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OOmmnniiSSwwiittcchh 66885555
HHaarrddeenneedd LLAANN SSwwiittcchh
BBooiilleerrppllaattee DDooccuummeenntt
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 1 Alcatel.Lucent-ESD
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TTaabbllee ooff CCoonntteennttss
DDiissccllaaiimmeerr_______________________________________________________________________ 3
TTrraaddeemmaarrkk TTeexxtt __________________________________________________________________ 3
RReevviissiioonn HHiissttoorryy __________________________________________________________________ 3
AAllccaatteell--LLuucceenntt CCoommppaannyy BBaacckkggrroouunndd ________________________________________________ 4
AAbboouutt BBooiilleerrppllaattee _________________________________________________________________ 5
OOmmnniiSSwwiittcchh 66885555 IInnttrroodduuccttiioonn ______________________________________________________ 6
TTaarrggeett MMaarrkkeett ________________________________________________________________________ 6
WWhhaatt’’ss NNeeww?? _________________________________________________________________________ 6
TThhee OOmmnniiSSwwiittcchh 66885555 PPrroodduucctt OOvveerrvviieeww______________________________________________ 7
HHaarrddwwaarree OOvveerrvviieeww ___________________________________________________________________ 8 OOmmnniiSSwwiittcchh OOSS66885555--1144 ________________________________________________________________________ 8 OOmmnniiSSwwiittcchh 66885555--1144 IInntteerrnnaall AArrcchhiitteeccttuurree ____________________________________________________ 10
OOmmnniiSSwwiittcchh OOSS66885555--UU1100______________________________________________________________________ 10 OOmmnniiSSwwiittcchh 66885555--UU1100 IInntteerrnnaall AArrcchhiitteeccttuurree___________________________________________________ 11
OOmmnniiSSwwiittcchh OOSS66885555--2244 _______________________________________________________________________ 12 OOmmnniiSSwwiittcchh 66885555--2244 IInntteerrnnaall AArrcchhiitteeccttuurree ____________________________________________________ 13
OOmmnniiSSwwiittcchh OOSS66885555--UU2244______________________________________________________________________ 14 OOmmnniiSSwwiittcchh 66885555--UU2244 IInntteerrnnaall AArrcchhiitteeccttuurree___________________________________________________ 15
TThhee OOmmnniiSSwwiittcchh OOSS66885555 PPoowweerr SSuuppppllyy SSyysstteemm ____________________________________________________ 17 OOvveerrtteemmpp ccoonnddiittiioonn___________________________________________________________________________ 20 HHaarrddwwaarree MMoonniittoorriinngg _________________________________________________________________________ 22 MMaannaaggiinngg PPoowweerr oovveerr EEtthheerrnneett ((PPooEE))_____________________________________________________________ 22 PPoowweerr oovveerr EEtthheerrnneett SSppeecciiffiiccaattiioonnss ___________________________________________________________ 22 PPoorrtt PPrriioorriittyy LLeevveellss________________________________________________________________________ 23 UUnnddeerrssttaannddiinngg PPrriioorriittyy DDiissccoonnnneecctt ___________________________________________________________ 23 MMoonniittoorriinngg PPoowweerr oovveerr EEtthheerrnneett vviiaa CCLLII______________________________________________________ 24 PPoowweerr CCoorrddss______________________________________________________________________________ 25
Specifications ___________________________________________________________________________ 25 RReedduunnddaanntt AACC CCiirrccuuiitt RReeccoommmmeennddaattiioonn ______________________________________________________ 25 GGrroouunnddiinngg tthhee CChhaassssiiss _____________________________________________________________________ 25
TTeemmppeerraattuurree MMaannaaggeemmeenntt______________________________________________________________________ 25
MMTTBBFF (( MMeeaann TTiimmee BBeettwweeeenn FFaaiilluurree))____________________________________________________ 26
RReegguullaattoorryy CCoommpplliiaannccee aanndd SSaaffeettyy IInnffoorrmmaattiioonn ___________________________________________ 38 DDeeccllaarraattiioonn ooff CCoonnffoorrmmiittyy:: CCEE MMaarrkk _____________________________________________________________ 39 WWaassttee EElleeccttrriiccaall aanndd EElleeccttrroonniicc EEqquuiippmmeenntt ((WWEEEEEE)) SSttaatteemmeenntt_________________________________________ 39 SSttaannddaarrddss CCoommpplliiaannccee_________________________________________________________________________ 39 SSaaffeettyy SSttaannddaarrddss __________________________________________________________________________ 39 EEMMCC SSttaannddaarrddss ___________________________________________________________________________ 39 SSaaffeettyy aanndd EEnnvviirroonnmmeennttaall SSttaannddaarrddss _________________________________________________________ 41
OOmmnniiSSwwiittcchh 66885555 SSeerriieess –– HHaarrddwwaarree && SSooffttwwaarree FFeeaattuurreess OOvveerrvviieeww TTaabbllee ____________________ 41
AAppppeeddiixx AA -- SSmmaallll FFoorrmm FFaaccttoorr PPlluuggggaabbllee ((SSFFPP MMSSAA))______________________________________ 89 HHaannddlliinngg FFiibbeerr aanndd FFiibbeerr OOppttiicc CCoonnnneeccttoorrss ___________________________________________________ 89
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 2 Alcatel.Lucent-ESD
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AAppppeennddiixx BB -- PPiinn--OOuuttss ________________________________________________________________ 91 RRJJ--4455 CCoonnssoollee PPoorrtt –– CCoonnnneeccttoorr PPiinnoouuttss ______________________________________________________ 91 RRJJ--4455 CCoonnssoollee PPoorrtt –– CCoonnnneeccttoorr PPiinnoouuttss ______________________________________________________ 91 1100//110000MMbbppss EEtthheerrnneett PPoorrtt RRJJ--4455 PPiinnoouuttss ((NNoonn--PPooEE)) ____________________________________________ 91 PPoowweerr oovveerr EEtthheerrnneett PPoorrtt ––RRJJ--4455 PPiinnoouuttss ((wwiitthh PPooEE))____________________________________________ 91 11 GGiiggaabbiitt EEtthheerrnneett PPoorrtt RRJJ--4455 PPiinnoouuttss ((NNoonn--PPooEE))_______________________________________________ 92 1100//110000//11000000MMbbppss PPoowweerr oovveerr EEtthheerrnneett PPoorrtt --RRJJ--4455 PPiinnoouuttss ______________________________________ 92 CCoonnssoollee PPoorrtt // SSeerriiaall CCoonnnneeccttiioonn DDeeffaauulltt SSeettttiinnggss _______________________________________________ 92 OOSS66885555 DDBB--2255 PPppoowweerr CCoonnnneeccttiioonn PPIINN--OOUUTT __________________________________________________ 93
AAppppeennddiixx CC -- MMTTBBFF CCaallccuullaattiioonn SSttaannddaarrddss aanndd RReeqquuiirreemmeennttss ______________________________ 93
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 3 Alcatel.Lucent-ESD
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DDiissccllaaiimmeerr
The information contained in this document represents the features of the listed Alcatel-Lucent Products.
Alcatel-Lucent makes no claims regarding the accuracy of this published information and specifically disclaims all liability for
loss or damages of any kind resulting from discussions made or actions taken by any party based on this information.
PPrroodduucctt iinnffoorrmmaattiioonn ccoonnttaaiinneedd iinn tthhiiss ddooccuummeenntt iiss ssuubbjjeecctt ttoo cchhaannggee aanndd ffrreeqquueenntt uuppddaatteess wwiitthhoouutt pprriioorr nnoottiiccee..
Contact your local Alcatel-Lucent representative for the most current information.
Copyright © 2008 Alcatel-Lucent Internetworking, Inc. All rights reserved. This document will not be reproduced in
whole or in part without the express written permission of Alcatel-Lucent Internetworking.
TTrraaddeemmaarrkk TTeexxtt To protect the Alcatel-Lucent trademark, the following legal text must be inserted in the body of all RFPs, RFIs, and
quotations. Alcatel-Lucent is a registered trademark of Alcatel-Lucent, a society anonym organized under the laws of
the Republic of France. The first use of Alcatel-Lucent in any documents must include a "" registered trademark symbol.
RReevviissiioonn HHiissttoorryy Rev. Date: Revision Description
Preliminary December ‘ 08 Preliminary draft.
Rev. 1.0 February. ‘ 09 Removed all references to ASIC, CPU, tranceivers’ vendors
Rev. 2.0 July ‘09 Added OS6855-U24X and AOS6.4.2
Rev. 2.1 Aug ‘09 Added OS6855-PSS-P-D
Rev. 2.1a Nov. ‘09 Updates to the diagrams and added MTBFs for OS6855-U24X , updates on the power
consumption numbers, as well as other minor modifications.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 4 Alcatel.Lucent-ESD
Calabasas/CA./USA
AAllccaatteell--LLuucceenntt CCoommppaannyy BBaacckkggrroouunndd About Alcatel-Lucent
Alcatel-Lucent (Paris:ALU.PA - News) (NYSE:ALU - News) provides solutions that enable service providers, enterprises
and governments worldwide, to deliver voice, data and video communication services to end-users. As a leader in fixed,
mobile and converged broadband networking, IP technologies, applications, and services, Alcatel-Lucent offers the end-
to-end solutions that enable compelling communications services for people at home, at work and on the move. With
operations in more than 130 countries, Alcatel-Lucent is a local partner with global reach. The company has the most
experienced global services team in the industry, and one of the largest research, technology and innovation organizations
in the telecommunications industry. Alcatel-Lucent achieved adjusted proforma revenues of Euro 18.3 billion in 2006 and
is incorporated in France, with executive offices located in Paris. [All figures exclude impact of activities transferred to
Thales]. For more information, visit Alcatel-Lucent on the Internet:
http://www.Alcatel-Lucent.com
Alcatel-Lucent’s vision is to enrich people’s lives by transforming the way the world communicates. Alcatel-Lucent
provides solutions that enable service providers, enterprises and governments worldwide, to deliver voice, data and video
communication services to end-users. As a leader in fixed, mobile and converged broadband access, carrier and enterprise
IP technologies, applications, and services, Alcatel-Lucent offers the end-to-end solutions that enable compelling
communications services for people at home, at work and on the move.
With 79,000 employees (after the completion of the Thales transaction) and operations in more than 130 countries,
Alcatel-Lucent is a local partner with global reach. The company has the most experienced global services team in the industry,
and one of the largest Innovation and Technology organizations focused on communications. Alcatel-Lucent achieved
combined sales of Euro 18.6 billion* in 2005, and is incorporated in France, with executive offices located in Paris.
Organization
With a strong focus on complete solutions maximizing value for customers, Alcatel-Lucent is organized around five
business groups and four geographic regions. The Wireless, Wire-line, Convergence groups, which make up the Carrier
Business Group, are dedicated to serving the needs of the world's service providers. The Enterprise Business Group
focuses on meeting the needs of business customers. The Services Business Group designs, deploys, manages and
maintains networks worldwide. The company's geographic regions are Europe and North, Europe and South, North
America, and Asia-Pacific.
Innovation & Technology
Alcatel-Lucent today is one of the largest innovation powerhouses in the communications industry, boasting 23,000
research and development experts worldwide, representing a combined R&D investment of Euro 2.7 billion* in 2005, and
a portfolio of over 25,000 active patents spanning virtually every technology area. At the core of this innovation is
Alcatel-Lucent’s research, which includes the world-renowned Bell Labs and Research & Innovation groups, providing
Alcatel-Lucent with an innovation engine of 1,500 researchers and scientists at the forefront of research into areas such as
multimedia and convergent services and applications, new service delivery architectures and platforms, wireless and
Wire-line, broadband access, packet and optical networking and transport, network security, enterprise networking and
communication services and fundamental research in areas such as nanotechnology, algorithmic, and computer sciences.
History
Formed from the merger of Alcatel and Lucent Technologies, Alcatel-Lucent combines two entities that share a common
lineage that can be traced back to 1986, when Alcatel’s parent company, CGE (la Compagnie Générale d’Electricité),
acquired ITT’s European telecom business. Nearly 60 years earlier, ITT had purchased most of AT&T’s manufacturing
operations outside the United States. AT&T was Lucent’s former parent company.
By creating Alcatel-Lucent we are bringing our common lineages back together and starting an exciting new chapter of
our history -- creating the world’s first truly global communications solutions provider, with the most complete end-to-end
portfolio of solutions and services in the industry.
AAbboouutt AAllccaatteell--LLuucceenntt EEnntteerrpprriissee NNeettwwoorrkkiinngg SSoolluuttiioonnss
Alcatel-Lucent delivers standards-based IP communications solutions to a global customer base of over 500,000 small,
medium and large enterprises, government agencies, healthcare facilities, and educational institutions. Alcatel-Lucent's
award-winning Omni family of IP Communications solutions consists of an extensive portfolio of network switching
infrastructure products and IP telephony products built to provide long-term value.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 5 Alcatel.Lucent-ESD
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AAbboouutt BBooiilleerrppllaattee Alcatel-Lucent Internetworking Boilerplate documents include the following series:
� AOS OmniSwitch 9000 Series
� AOS OmniSwitch 6850 Series
� AOS OmniSwitch 6855 Series
� AOS OmniSwitch 6400 Series
� OmniStack LS 6200 Product Families
� OmniAccess Wireless LAN (WLAN) Product Families
� OmniVista Network Management System
� Legacy Product Families:
• AOS OmniSwitch 8800
• AOS OmniSwitch 7000 Series
• AOS OmniSwitch 6800 Series
• AOS OmniSwitch 6600/6602 Series
• OmniStack 6024/6124/6148/8008 Product Families
• OmniStack 6300 Product Families
The scope of this document is to provide the reader with a basic understanding of all the main product features
implemented in the Alcatel-Lucent OmniSwitch 6855 Hardened LAN Switch. Furthermore, it can be used as a reference
for preparing replies to RFI/RFP/RFQ questions.
(RFI : Request for Information – RFP : Request for Proposal – RFQ : Request for Quotation)
NOTE: Throughout this document if a reference is made towards future releases of the OS6855 the content of these
releases and functionality should be confirmed against the prior to quotation to a customer.
This document is intended to be an evolving document that will be updated in view of:
• A new product release and new features,
• The need for additional information on existing features.
The document does not provide information related to the OmniVista network management platform. Please refer to the
NMS roadmap and boilerplate documents for details.
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DDooccuummeennttss ttoo ccoolllleeccttiivveellyy ggaatthheerr tthhee mmoosstt uupp--ttoo--ddaattee iinnffoorrmmaattiioonn rreeqquuiirreedd ffoorr rreessppoonnddiinngg ttoo
ccuussttoommeerr’’ss RRFFPPss && RRFFIIss pprrooppoossaallss..
TThhiiss ddooccuummeenntt wwiillll nnoott ccoonnttaaiinn ddeettaaiilleedd ddeessiiggnn//ffuunnccttiioonnaall//ccoonnffiigguurraattiioonn,, aanndd//oorr
ssooffttwwaarree//hhaarrddwwaarree aarrcchhiitteeccttuurraall ssppeecciiffiiccaattiioonnss.. IItt wwiillll oonnllyy pprroovviiddee aann oovveerrvviieeww ooff ssuucchh
aaffoorreemmeennttiioonneedd ssppeecciiffiiccaattiioonnss.. PPlleeaassee cchheecckk uusseerr mmaannuuaallss aanndd AAOOSS ssppeecciiffiicc bbooiilleerr ppllaattee ffoorr
ddeettaaiillss..
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 6 Alcatel.Lucent-ESD
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OOmmnniiSSwwiittcchh 66885555 IInnttrroodduuccttiioonn The Alcatel-Lucent OmniSwitch 6855 is an extension of the Alcatel-Lucent OmniSwitch 6850 Stackable LAN switch family
and is a platform specifically built for deployments where operating conditions are more demanding than normal.
The OmniSwitch 6855 inherits the benefits of the Alcatel-Lucent OmniSwitch 6850 product family and offers flexible,
configurations, high availability and wire speed performance at L2 and L3 that dramatically improves network response
time.
The key feature differentiator for the Alcatel-Lucent OmniSwitch 6855 is that it is a hardened, fully managed Gigabit
Ethernet LAN switch, designed to operate under wide operating temperatures and harsh industrial electromagnetic
environments. Its superior hardware design complemented by the advanced Alcatel-Lucent operating system (AOS)
makes the OmniSwitch 6855 an excellent choice for industrial and carrier class applications
TTaarrggeett MMaarrkkeett
The Alcatel-Lucent OmniSwitch 6855 is designed to operate in environments where conditions are harsh. Typical target
customers or applications include utilities, oil and gas installations, water treatment plants, manufacturing plants,
traffic signal control systems, and military installations. In particular:
1. Power utility: Electric utility companies are now automating their operations including their substations. The Ethernet
products used in these locations must operate at extreme temperatures as well as in high electro-magnetic fields. Fiber optic
media is recommended for connecting all devices used in a substation.
2. Transportation: Intelligent Transportation Systems (ITS), such as railroad applications and advanced traffic management
systems, require Ethernet based, hardened communication solutions for use in wayside cabinets to support control, signaling
and video monitoring applications.
3. Telecommunications and carrier Ethernet applications: Desirable for outdoor installations that require enhanced QoS to
support voice, video and data.
4. Military installations: Must meet stringent shock and vibration requirements as well as enhanced security and high network
availability.
5. All environmentally harsh deployments.
WWhhaatt’’ss NNeeww??
The Alcatel-Lucent OmniSwitch 6855 offers these new, unique features:
� Purpose built, rugged hardware comprised of industrial grade components designed to withstand operating temperatures from -40C to +70C
� Five different models: 14-port and 24-port copper, 10-port and 24-port fiber models and 24 port fiber mode with two 10 Gig ports,powered by a variety of AC and DC power supplies
� PoE is enabled on all copper models
� Enhanced network reliability: in addition to having hardened hardware the Alcatel-Lucent OmniSwitch 6855s have improved reliability by providing redundancy everywhere including power supplies that are hot swappable and image rollback to automatically re-load previous configurations and software versions
� Performance: Wire-rate switching and routing at gigabit speeds. The Alcatel-Lucent OmniSwitch 6855 family supports real-time voice, data, and video applications.
� Advanced services: QoS, ACLs for traffic control � Native IPv4 and IPv6 support at no additional cost.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 7 Alcatel.Lucent-ESD
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TThhee OOmmnniiSSwwiittcchh 66885555 PPrroodduucctt OOvveerrvviieeww There are five OmniSwitch 6855 models in the family. 10 and 24 port fiber models and 14 and 24 port copper models,
which can be powered by AC or DC power supplies to create the following bundles in the price list:
OmniSwitch 6855 Series
This section contains the information required to order the OmniSwitch 6855 Hardened Gigabit Ethernet switch bundles and backup power supplies, industrial grade transceivers and accessories.
The product family model names have the format : OS6855-xxxx.
Suffix letters in the bundle name indicate the type of power supply included. No letters present means bundle comes with standard AC power supply package.
- "D" means bundle comes with -48V DC power supply
- "DL" means bundle comes with a low voltage 24V DC power supply - "P" means the bundle comes with PoE power supply
Backup power supply naming
- "PSS" denotes power supply for the small models ( OS6855-14 and OS6855-U10 ) - "PSL" denotes power supply for the 24 port models.
Advanced routing software is included in the price. ( OSPFv2/v3, PIM-SM/DM and DVMRP) . Only industrial strenght tranceivers ( denoted by the letter "i" at the beginnning of the name) are supported on OmniSwitch 6855. For AC powered chassis and power supplies, the country-specific power cord must be specified by adding the variation extension (-xx) from
the list of power cords in the "Power Cords for European Market" and "Power Cords for Rest of World" sections in the "Accessories -Power
Cord Options" section of this price list. See the Alcatel Enterprise Solutions Division Worldwide Price List Addendum, "All Products - General; Cable Options" for additional information and Power Cord Cross Reference chart.
Limited lifetime warranty does not apply to transceivers or backup power supplies. See the Transceiver section of this Worldwide Price List to choose the appropriate optical or copper plug-in interface.
Model Number Description
OmniSwitch 6855 PoE Chassis Bundles
OS6855-14
OS6855-14 Hardened Gigabit Ethernet L3 fixed configuration fanless chassis in a 1U form factor designed to operate in harsh environments. It has 12 RJ-45 connectors individually configurable to 10/100/1000 BaseT, and 2 SFP ports which support various distances. The bundle comes with OS6855-PSS power supply, power shelf , country specific power cord, user manual
access card and rack mounts. Ethernet optical transceivers, PoE power supply ( OS6855-PSS-P) and backup power supplies can
be ordered separately.
OS6855-14D OS6855-14D Hardened Gigabit Ethernet L3 fixed configuration fanless chassis in a 1U form factor designed to operate in
harsh environments. It has 12 RJ-45 connectors individually configurable to 10/100/1000 BaseT, and 2 SFP ports which
support various distances. The bundle comes with OS6855-PSS-D power supply, power shelf, user manual access card and rack mounts. Ethernet optical transceivers, PoE power supply ( OS6855-PSS-P) and backup power supplies can be ordered
separately.
OS6855-24 OS6855-24 Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh
environments. It has 20 RJ-45 connectors individually configurable to 10/100/1000 BaseT four of which provide PoE and 4 combo ports. On the combo ports, either copper or fiber can be used on a one for one basis. The bundle comes with OS6855-
PSL-P power supply, power shelf, country specific power cord, user manual access card and rack mounts. Ethernet optical
transceivers and backup power supplies can be ordered separately.
OS6855-24D OS6855-24 Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh environments. It has 20 RJ-45 connectors individually configurable to 10/100/1000 BaseT four of which are PoE capable and
4 combo ports. On the combo ports, either copper or fiber can be used on a one for one basis. The bundle comes with OS6855-
PSL-D power supply, power shelf, user manual access card and rack mounts.
OS6855-24DL OS6855-24 Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh
environments. It has 20 RJ-45 connectors individually configurable to 10/100/1000 BaseT four of which are PoE capable and
4 combo ports. On the combo ports, either copper or fiber can be used on a one for one basis. The bundle comes with OS6855-PSL-DL power supply, power shelf, country specific power cord, user manual access card and rack mounts. Ethernet optical
transceivers and backup power supplies can be ordered separately.
OS6855-U10 OS6855-U10 Hardened Gigabit Ethernet L3 fixed configuration fanless chassis in a 1U form factor designed to operate in
harsh environments. It has 2 RJ-45 connectors individually configurable to 10/100/1000 BaseT, and 8 SFP ports which support various distances. The bundle comes with OS6855-PSS power supply, power shelf, country specific power cord, user manual
access card and rack mounts. Ethernet optical transceivers and backup power supplies can be ordered separately.
OS6855-U10D OS6855-U10 Hardened Gigabit Ethernet L3 fixed configuration fanless chassis in a 1U form factor designed to operate in
harsh environments. It has 2 RJ-45 connectors individually configurable to 10/100/1000 BaseT, and 8 SFP ports which support various distances. The bundle comes with OS6855-PSS-D power supply, power shelf, user manual access card and rack
mounts. Ethernet optical transceivers and backup power supplies can be ordered separately.
OS6855-U24 OS6855-24 Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh environments. It has 22 SFP ports which support various distances, and 2 combo ports. On the combo ports, either RJ-45
connectors individually configurable to 10/100/1000 BaseT or fiber SFP can be used on a one for one basis. The bundle comes
with OS6855-PSL power supply, power shelf, country specific power cord, user manual access card and rack mounts.
OS6855-U24D OS6855-24 Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 8 Alcatel.Lucent-ESD
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environments. It has 22 SFP ports which support various distances, and 2 combo ports. On the combo ports, either RJ-45
connectors individually configurable to 10/100/1000 BaseT or fiber SFP can be used on a one for one basis. The bundle comes with OS6855-PSL-D power supply, power shelf, user manual access card and rack mounts.Ethernet optical transceivers and
backup power supplies can be ordered separately.
OS6855-U24DL OS6855-U24 Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh environments. It has 22 SFP ports which support various distances, and 2 combo ports. On the combo ports, either RJ-45 connectors individually configurable to 10/100/1000 BaseT or fiber SFP can be used on a one for one basis. The bundle comes
with OS6855-PSL-DL power supply, power shelf, user manual access card and rack mounts.
OS6855-U24X OS6855-U24X Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh
environments. It has two 10G SFP+ ports that can be used for stacking or uplinks, 22 SFP ports which support various distances, and 2 combo ports. On the combo ports, either RJ-45 connectors individually configurable to 10/100/1000 BaseT or
fiber SFP can be used on a one for one basis. The bundle comes with OS6855-PSL power supply, power shelf, user manual
access card and rack mounts.
OS6855-U24XD OS6855-U24X Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh
environments. It has two 10G SFP+ ports that can be used for stacking or uplinks, 22 SFP ports which support various
distances, and 2 combo ports. On the combo ports, either RJ-45 connectors individually configurable to 10/100/1000 BaseT or fiber SFP can be used on a one for one basis. The bundle comes with OS6855-PSL-D power supply, power shelf, user manual
access card and rack mounts.
OS6855-U24XDL OS6855-U24X Hardened Gigabit Ethernet L3 fixed configuration chassis in a 1U form factor designed to operate in harsh
environments. It has two 10G SFP+ ports that can be used for stacking or uplinks, 22 SFP ports which support various distances, and 2 combo ports. On the combo ports, either RJ-45 connectors individually configurable to 10/100/1000 BaseT or
fiber SFP can be used on a one for one basis. The bundle comes with OS6855-PSL-DL power supply, power shelf, user manual
access card and rack mounts.
OS6855-U24
OS6855-PSS OS6855-PSS power brick AC power supply. Provides only system power. Does not provide PoE. Ships with country specific
power cord.
OS6855-PSS-P OS6855-PSS-P power brick AC power supply. Provides PoE only power to one OS6855-14. Ships with country specific power
cord.
OS6855-PSS-D OS6855-PSS-D power brick 24V-48V DC power supply. Provides only system power to one switch. Does not provide PoE.
OS6855-PSS-P-D OS6855-PSS-P-D power brick 48V DC power supply. Provides PoE only power to one OS6855-14.
OmniSwitch 6855 Backup Power Supplies for OS6855-24 , OS6855-U24, OS6855-U24X
OS6855-PSL OS6855-PSL modular AC backup power supply. Provides backup system power to one OS6855-U24 switch. Ships with
chassis connection cable and country specific power cord.
OS6855-PSL-P OS6855-PSL-P modular AC backup power supply. Provides backup system and PoE power to one OS6855-24 switch. Ships with chassis connection cable and country specific power cord.
OS6855-PSL-D OS6855-PSL-D modular -48V DC backup power supply. Provides backup system power to one 24 port 6855 switch. Ships
with chassis connection cable.
OS6855-PSL-DL OS6855-PSL-DL modular 24V DC backup power supply. Provides backup system power to one 24 port 6855 switch. Ships
with chassis connection cable.
OmniSwitch 6855 Accessories
OS6855-24-FLTR A pack of 4 air filters for 6855-24 model
OS6855-U24-FLTR A pack of 4 air filters for 6855-U24 model
OS6855-PSS-SHLF Power supply shelf for OS6855-U10 and 6855-14 models; mounting brackets included
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.
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The OmniSwitch 6855-C14 is a hardened LAN switch offering 12 10/100/1000 Base-T, and two SFP
connectors. Additionally, the first four ports are PoE capable. ( Note: in order to provide PoE power OS6855-PSS-P
have to be installed in addition to the system power AC or DC power supply)
The front panel of the OS6855-14 chassis contains the following major components:
• (12) Unshared 10/100/1000Base-T with PoE support on the first four ports
• (2) SFP connectors
• Console port (RJ-45) • LEDs
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 9 Alcatel.Lucent-ESD
Calabasas/CA./USA
The rear panel of OS6855-14 switch contains the following major components: • Two 3-pin connectors provided for primary and redundant system power supplies
• Two 4-pin connectors provided for primary and redundant PoE power supplies
• Grounding block for type LCD8-10A-L grounding lug
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 10 Alcatel.Lucent-ESD
Calabasas/CA./USA
For more information please see the hardware user guide.
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• 400MHz CPU
• 128 M flash for boot and OS storage
• 256M SDRAM
• 32 bit 66MHz PCI bus
• RJ45 console port
• USB (not used)
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The OmniSwitch 6855-U10 is a hardened LAN switch offering 8 SFP connectors and 2 10/100/1000 Base-T ports.
Front panel :
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 11 Alcatel.Lucent-ESD
Calabasas/CA./USA
Back Panel:
OOmmnniiSSwwiittcchh 66885555--UU1100 IInntteerrnnaall AArrcchhiitteeccttuurree
• CPU - 400MHz
• 128M flash for boot and OS storage
• 256M SDRAM
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 12 Alcatel.Lucent-ESD
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• 32 bit 66MHz PCI bus
• RJ45 console port
• USB (not used)
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The OmniSwitch 6855-24 is a hardened gigabit switch offering 20 unshared 10/100/1000Base-T, as well
as four combo ports individually configurable to 10/100/1000Base-T or 1000Base-X . Additionally, only the first four ports support PoE.
Front Panel :
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 13 Alcatel.Lucent-ESD
Calabasas/CA./USA
Back Panel :
OOmmnniiSSwwiittcchh 66885555--2244 IInntteerrnnaall AArrcchhiitteeccttuurree
• CPU – 400MHz
• 32 bit 66MHz PCI bus
• 256M SDRAM
• 128 M flash for boot and OS storage
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 14 Alcatel.Lucent-ESD
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• RJ45 console port
• USB (not used)
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The OmniSwitch 6855-U24 is a hardened gigabit switch offering 22 SFP connectors, and two combo
ports individually configurable to 10/100/1000Base-T or 1000Base-X .
Front Panel:
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 15 Alcatel.Lucent-ESD
Calabasas/CA./USA
Back Panel:
OOmmnniiSSwwiittcchh 66885555--UU2244 IInntteerrnnaall AArrcchhiitteeccttuurree
• CPU – 400MHz
• 32 bit 66MHz PCI bus
• 256M SDRAM
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 16 Alcatel.Lucent-ESD
Calabasas/CA./USA
• 128 M flash for boot and OS storage
• RJ45 console port
• USB (not used)
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The OmniSwitch 6855-U24 is a hardened gigabit switch offering 22 SFP connectors, two combo ports individually configurable to 10/100/1000Base-T or 1000Base-X and two 10 Gigabit ports which can be used
as stacking or uplinks.
Front Panel:
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 17 Alcatel.Lucent-ESD
Calabasas/CA./USA
OmniSwitch 6855-U24X Back Panel
OOmmnniiSSwwiittcchh 66885555--UU2244 IInntteerrnnaall AArrcchhiitteeccttuurree
• CPU – 400MHz
• 32 bit 66MHz PCI bus
• 256M SDRAM
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 18 Alcatel.Lucent-ESD
Calabasas/CA./USA
• 128 M flash for boot and OS storage
• RJ45 console port
• USB (not used)
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� All of the OmniSwitch 6855 models support redundant, hot-swappable AC, DC or PoE power supplies which are external to the box.
� Primary as well as backup power supplies for all models are external to the device and hot-swappable which allows for easier maintenance and replacement
� Power supplies can also be remotely mounted using a special cable, which allows OmniSwitch 6855 to be used in areas with reduced depth.
� There is no interruption of service in case of a new PS is installed or an old one replaced
Please note that the half chassis models (OS6855-14 and OS6855-U10) use different power supplies than the 24 port models.
For detailed information regarding Input voltage range, rated frequency, inrush current, output voltage , output current, etc. see chapter 2 of OmniSwitch 6855 Series Hardware User Guide.
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The power supplies for OS6855-U10 and OS6855-14 models come in the form of a power brick in either AC or DC variant. A separate power brick provides PoE power and is available for purchase when PoE is required.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 19 Alcatel.Lucent-ESD
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Power Supply Models Description
OS6855-PSS External PSU for OS6855-14 and OS6855-U10; 90-240VAC, 50-60Hz AC; 40W, 12V, AC-DC
PS6855-PSS-P External PSU for OS6855-14; 66W, 48V PoE, AC-DC
PS6855-PSS-D External PSU for 6855-14 and OS6855-U10; 40W, -48V and 24V input to 12V DC-DC
Specification Weight Depth Width Height
Power brick (AC, DC or PoE) 1.30lb/0.65kg 5.50” 3.20” 1.6”
Power brick and tray 2.65lb/1.2kg 7.50" 8.50” 1.73” (1RU)
The power supply shelf holds two power bricks and can be mounted either in a side-by-side configuration with the switch for 19” rack mounting or attached at the back of the switch for bulkhead mounting options.
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The primary as well as the backup power supplies for the OmniSwitch 6855-24 port models are external and connect to the rear of the unit. A power shelf provided with the unit, can slide into the rear of the switch and is used to hold two power supplies.
Power Supply
Models
Description
OS6855-PSL External PSU for OS6855-U24; 90-240VAC, 50-60Hz AC; 80W, 12V, AC-DC
PS6855-PSL-P External PSU for OS6855-24; 90-240VAC, 50-60Hz AC; 160W, 48V PoE, 12V, AC-DC
PS6855-PSL-D External PSU for OS6855-24 and OS6855-U24; 80W, -48V/12V DC-DC
PS6855-PSL-DL External PSU for OS6855-24 and OS6855-U24; 80W, 24V/12V DC-DC
Specification Weight Depth Width Height
Power supply (AC, DC or PoE) 2.00lb/1.00kg 6.50" 6.30” 1.73” (1RU)
Power supply and Tray 3.52lb/1.60kg 7.00" 13.88” 1.73” (1RU)
Any power supply can be remotely connected using a cable, which enables rack mounting using the mounting ears provided with the unit. This feature allows for space sensitive installations requiring reduced-depth (e.g., a wall-mounted cabinet).
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The OmniSwitch 6855 Series switches support an optional backup power supply. This power supply is connected to the rear of the unit. There is a power shelf provided with the unit that slides into the rear of the chassis and is used to hold the power supplies. This provides redundant chassis power on a 1:1 basis. Backup power supplies operate in standby mode. If the primary power supply fails unexpectedly, the backup power supply automatically takes up the full power load without disrupting the switch.
Please take a note of the backup power supply naming convention:
- "PSS" denotes power supply that can only be used with for the small models ( OS6855-14 and OS6855-U10 )
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 20 Alcatel.Lucent-ESD
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- "PSL" denotes power supply for the 24 port models only.
OS6855-14 OS6855-U10 OS6855-24 OS6855-U24 OS6855-U24X
OS6855-PSS Yes Yes Not supported Not supported Not supported
OS6855-PSS-P Yes Not supported Not supported Not supported Not supported
OS6855-PSS-D Yes Yes Not supported Not supported Not supported
OS6855-PSS-P-D Yes Not supported Not supported Not supported Not supported
OS6855-PSL Not supported Not supported Not supported Yes Yes
OS6855-PSL-P Not supported Not supported Yes Not supported Not supported
OS6855-PSL-D Not supported Not supported Yes Yes Yes
OS6855-PSL-DL Not supported Not supported Yes Yes Yes
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The OmniSwitch 6855 is designed to operate within a wider operating temperature range than normal
network equipment as noted under the specifications section. However, in the event that the normal operating temperature of the switch is exceeded, the following will occur:
• Upon crossing the configured overtemperature threshold, a trap will be sent. (See the OmniSwitch AOS Release 6 Network Configuration Guide) for information on configuring switch thresholds.
If the temperature continues to rise above the maximum operating temperature, the following will occur:
• OK LED will display solid Amber. • The switch will automatically shutdown
• Once the temperature drops to an acceptable operating level, the switch will automatically restart.
OS6855-U10
OS6855-14
OS6855-U24X
OS6855-U24
OS6855-24
Operating Temperature -40 to +70C -40 to +75C
Shutdown temperature 73C 78C
Warning temperature (interrupt) 71C 76C
Automatic Recovery temperature 60C 65C
Fan turn on temperature Not applicable 50C
Fan turn off temperature Not applicable 35C
Check the following if an overtemp condition exists:
• Verify that the switch is installed properly in an environment that adheres to the installation instructions
in the following chapters. • Verify proper airflow to the chassis.
TTrraanncceeiivveerrss
For more information on supported tranceivers please refer to “ OmniSwitch Tranceivers Guide” located at : http://enterprise.all.alcatel-
lucent.com/private/active_docs/os_xcvr_632r01.pdf?CFID=408480&CFTOKEN=21326601
You can also find a separate section in the WWPL listing the industrial grade tranceivers supporte on OS6855
familiy. Please note that, third party tranceivers not qualified by Alcatel-Lucent ESD, are not supported.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 21 Alcatel.Lucent-ESD
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All optical transceivers qualified for OmniSwitch 6855 operate at wider operating temperature range then the corresponding commercial types.
Gigabit Ethernet Transceivers
iSFP-GIG-LH70
1000Base-LH Industrial Gigabit Ethernet optical transceiver (SFP MSA). Supports single mode fiber over 1550nm
wavelength (nominal) with an LC connector. Typical reach of 70 Km on 9/125 µm SMF.
iSFP-GIG-LH40
1000Base-LH Industrial Gigabit Ethernet optical transceiver (SFP MSA). Supports single mode fiber over 1310 nm
wavelength (nominal) with an LC connector. Typical reach of 40 Km on 9/125 µm SMF.
iSFP-GIG-LX
1000Base-LX Industrial Gigabit Ethernet optical transceiver (SFP MSA). Supports single mode fiber over 1310nm
wavelength (nominal) with an LC connector. Typical reach of 10 Km on 9/125 µm SMF.
iSFP-GIG-SX
1000Base-SX Industrial Gigabit Ethernet optical transceiver (SFP MSA). Supports multimode fiber over 850nm wavelength (nominal) with an LC connector. Typical reach of 300m on 62.5/125 µm MMF or 550m on 50/125 µm
MMF.
100 FX Ethernet Transceivers
iSFP-100-MM
100Base-FX Industrial SFP transceiver with an LC type interface. This transceiver is designed for use over multimode
fiber optic cable.
iSFP-100-SM15
100Base-FX Industrial SFP transceiver with an LC type interface. This transceiver is designed for use over single
mode fiber optic cable up to 15KM.
iSFP-100-SM40
100Base-FX Industrial SFP transceiver with an LC type interface. This transceiver is designed for use over single mode fiber optic cable up to 40KM.
iSFP-100-BX-U
100Base-BX Industrial SFP transceiver with an SC type interface. This bi-directional transceiver is designed for use
over single mode fiber optic on a single strand link up to 20KM point-to-point. This transceiver is normally used in the client (ONU) transmits 1310nm and receives 1550nm optical signal
iSFP-100-BX-D
100Base-BX Industrial SFP transceiver with an SC type interface. This bi-directional transceiver is designed for use
over single mode fiber optic on a single strand link up to 20KM point-to-point. This transceiver is normally used in the central office (OLT) transmits 1550nm and receives 1310nm optical signal
Supported Configuration Matrix for industrial grade tranceivers
Transceivers OS6855-14 OS6855-U10 OS6855-24 OS6855-U24
Gigabit Ethernet Transceivers
iSFP-GIG-LH70 Yes Yes Yes Yes
iSFP-GIG-LH40 Yes Yes Yes Yes
iSFP-GIG-LX Yes Yes Yes Yes
iSFP-GIG-SX Yes Yes Yes Yes
100 FX Ethernet Transceivers
iSFP-100-MM Yes Yes No Yes
iSFP-100-SM15 Yes Yes No Yes
iSFP-100-SM40 Yes Yes No Yes
iSFP-100-BX-U Yes Yes No Yes
iSFP-100-BX-D Yes Yes No Yes
iSFP-100-BXLC-U Yes Yes No Yes
iSFP-100-BXLC-D Yes Yes No Yes
The technical specification for each transceiver are provided in the OS6855 hardware user guide.
For SFP MSA tranceivers specifications and definitions see appendix A.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 22 Alcatel.Lucent-ESD
Calabasas/CA./USA
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Automatic monitoring refers to the switch’s built-in sensors that automatically monitor operations. If an error is detected
(e.g., over-threshold temperature), the switch immediately sends a trap to the user. The trap is displayed on the console in
the form of a text error message. (In the case of an over-threshold temperature condition, the chassis displays an amber
TMP LED in addition to sending a trap.)
LEDs, which provide visual status information, are provided on the chassis front panel. LEDs are used to indicate
conditions such as hardware and software status, temperature errors, link integrity, data flow, etc.
User-driven hardware monitoring refers to CLI commands that are entered by the user in order to access the current
status of hardware components. The user enters “show” commands that output information to the console.
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Power over Ethernet (PoE) is supported on OmniSwitch 6855 Series switches and provides inline power directly from the
switch’s Ethernet ports. Powered Devices (PDs) such as IP phones, wireless LAN stations, Ethernet hubs, and other access
points can be plugged directly into the Ethernet ports. From these RJ-45 ports the devices receive both electrical power
and data flow. As the feature reduces devices’ dependence on conventional power sources, PoE eliminates many
restrictions that traditional electrical considerations have imposed on networks.
In a PoE configuration, Power Source Equipment (PSE) detects the presence of a PD and provides an electrical current
that is conducted along the data cable. The PD operates using the power received via the Ethernet data cable; no
connection to an additional power source (e.g., an AC wall socket) is required.
Note on Terminology. There are several general terms used to describe the feature, PoE. The terms Power over Ethernet
(PoE), Power over LAN (PoL), Power on LAN (PoL), and Inline Power are synonymous terms used to describe the
powering of attached devices via Ethernet ports.
Additional terms, such as Powered Device (PD) and Power Source Equipment (PSE) are not synonymous with PoE, but
are directly related to the feature:
• PD refers to any attached device that uses a PoE data cable as its only source of power. Examples include access points,
such as IP telephones, Ethernet hubs, wireless LAN stations, etc.
• PSE refers to power sourcing equipment, which provides power to a single link section. PSE main functions include
searching the PD, optionally classifying the PD, supplying power to the link section only if the PD is detected, monitoring
the power on the link section, and scaling power back to detect level when power is no longer requested or required.
As the OmniSwitch 6855 Series switches fully support 10/100/1000 Ethernet connectivity, you may also attach non-PD
equipment, such as computer workstations, printers, servers, etc. to the PoE ports.
Important. Alcatel-Lucent recommends that PoE-enabled switches with attached IP telephones should have operational
power supply redundancy at all times for 911 emergency requirements. In addition, both the switch and the power supply
should be plugged into an Uninterruptible Power Source (UPS).
Note. You can also monitor all chassis components and manage many chassis features, including Power over Ethernet,
with WebView; Alcatel-Lucent’s embedded web-based device management application. WebView is an interactive and
easy-to-use GUI that can be launched from the OmniVista or a web browser.
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IEEE Standards supported IEEE 802.3af DTE Power via MDI
Default PoE administrative status Enabled
Default PoE operational status Disabled
- PoE must be activated on a switch-by-switch basis via the lanpower start command - Separate PoE power supply need to be installed for 6855-14 model.
OmniSwitch 6855 Series platforms supporting PoE Only the copper models of the family support PoE : OS6855-14 and OS6855-24
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 23 Alcatel.Lucent-ESD
Calabasas/CA./USA
Cable distances supported 100 meters
Total number of PoE-capable ports per switch Up to 4
Default amount of inline power allocated for each port 15400 Milliwatts
Range of inline power allowed for each port 3000-20000 Milliwatts
PoE Current draw Approximately 4.3 amps
PoE Power supplied to port On 6855-14 the maximum available PoE power is 66 watts On 6855-24 the maximum available PoE power is 80 watts
Please refer to the Power Supply Specification Section for more details.
Power Priority level for a port Low
The capacitor detection method Disabled
Priority discount status Enabled
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As not all Powered Devices (PDs) connected to the switch have the same priority within a customer network setting, the
OmniSwitch 6855 Series switches allow the user to specify priority levels on a port-by-port basis.
Priority levels include low, high, and critical. The default priority level for a port is low.
• Low. This default value is used for port(s) that have low-priority devices attached. In the event of a power management
issue, inline power to low-priority ports is interrupted first (i.e., before critical and high-priority ports).
• High. This value is used for port(s) that have important, but not mission-critical, devices attached. If other ports in the
chassis have been configured as critical, inline power to high-priority ports is given second priority.
• Critical. This value is used for port(s) that have mission-critical devices attached, and therefore require top (i.e., critical)
priority. In the event of a power management issue, inline power to critical ports is maintained as long as possible.
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The priority disconnect function differs from the port priority function in that it applies only to the addition of powered
devices (PDs) in tight power budget conditions. Priority disconnect is used by the system software in determining whether
an incoming PD will be granted or denied power when there are too few watts remaining in the PoE power budget for an
additional device. For example, if there are only 2 watts available in the current PoE power budget and a user plugs a
3.5W powered device into a PoE port, the system software must determine whether the device will be powered on.
Based on priority disconnect rules, in some cases one or more existing devices may be powered down in order to
accommodate the incoming device. In other cases, the incoming device will be denied power.
Priority disconnect rules involve the port priority status of an incoming device (i.e., low, high, and critical), as well as the
port’s physical port number (i.e., 1–24). Understanding priority disconnect rules is especially helpful in avoiding power
budget deficits and the unintentional shutdown of mission-critical devices when PDs are being added in tight power
budget conditions.
Reminder. Priority disconnect applies only when there is inadequate power remaining in the power budget for an
incoming device. By default, priority disconnect is enabled in the switch’s system software.
When priority disconnect is disabled and there is inadequate power in the budget for an additional device, power will be denied
to any incoming PD, regardless of its port priority status (i.e., low, high, and critical) or physical port number (i.e., 1–24).
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 24 Alcatel.Lucent-ESD
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Priority Disconnect is enabled; same Priority Level on All PD Ports
Reminder. Priority disconnect examples are applicable only when there is inadequate power remaining to power an incoming device.
When a PD is being connected to a port with the same priority level as all other ports in the slot, the physical port number is
used to determine whether the incoming PD will be granted or denied power. Lower numbered ports receive higher priority
than higher-numbered ports. In other words, a PD connected to Port 1 will have a higher power priority than a PD connected to
Port 2; a PD connected to Port 23 will have a higher power priority than a PD connected to Port 24.
In order to avoid a power budget deficit, another port in the slot is disconnected.
In determining which port to power off, the system software disconnects the port with the highest physical port number.
Priority Disconnect is enabled; Incoming PD Port has Highest Priority Level
Reminder. Priority disconnect examples are applicable only when there is inadequate power remaining to power an incoming device.
When a PD is being connected to a port with a higher priority level than all other ports in the slot, the incoming PD will
automatically be granted power over the other devices, regardless of its physical port number.
In order to avoid a power budget deficit, another port in the slot is disconnected. In determining which port to power off, the
system software first selects the port with the lowest configured priority level. For example, if a critical priority device is being
added to a slot in which five existing devices are attached to high priority ports and one device is attached to a low priority port,
the low priority port is automatically disconnected, regardless of its physical port number.
If all existing devices are attached to ports with the same lower priority level, the system software disconnects the port with
both the lowest priority level and the highest physical port number. For example, if a critical priority device is being added to a
slot in which six existing devices are attached to high priority ports, the high priority port with the highest physical port number
is automatically disconnected.
Priority Disconnect is enabled; Incoming PD Port has Lowest Priority Level
Reminder. Priority disconnect examples are applicable only when there is inadequate power remaining to power an incoming device.
When a PD is being connected to a port with a lower priority level than all other ports in the slot, the incoming PD will be
denied power, regardless of its physical port number. Devices connected to other higher-priority ports will continue operating
without interruption.
Priority Disconnect is disabled
Reminder. Priority disconnect examples are applicable only when there is inadequate power remaining to power an incoming device.
When priority disconnect is disabled, power will be denied to any incoming PD, regardless of its port priority status (i.e.,
low, high, and critical) or physical port number (i.e., 1–24).
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To monitor current PoE statistics and settings, use the show lanpower command. The command output displays a list of all
current PoE-capable ports, along with the following information for each port:
• Maximum power allocated to the port, in Milliwatts
• Actual power used by the port
• Current port status
• Power priority status
• Power on/off status
Aggregate slot and chassis management information is also displayed. This information includes:
• Maximum watts allocated to the corresponding slot
• Amount of power budget remaining that can be allocated for PoE modules
• Total amount of power remaining that can be allocated for additional switch functions
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 25 Alcatel.Lucent-ESD
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PPoowweerr CCoorrddss
Because the power cord is the power supply’s main disconnect device, it should be plugged into an easily accessible
outlet. In the event that your power cord is lost or damaged, refer to the specifications below.
Specifications
The power cord to be used with 115-Volt configuration is a minimum type SJT (SVT) 18/3, rated at 250Volts AC, 10 Amps with
a maximum length of 15 feet. One end terminates in an IEC 320 attachment plug and the other end terminates in a NEMA 5-15P
plugs. The power cord to be used with 230-Volt configuration is minimum type SJT (SVT) 18/3, rated 250 Volts AC, 10 Amps
with a maximum length of 15 feet. One end terminates in an IEC 320 attachment plug and the other end terminates as required by
the country where it will be installed. European cords must be Harmonized (HAR) type. DC-to-DC Power Cords
For DC-to-DC connections please refer to the Hardware Users Manuals for additional guidelines and information.
Refer to the information below for power plug types by region:
Power Cord Types
North America NEMA 5-15-P (US), C22.2, No. 42 (Canada)
United Kingdom / Ireland BS 1,363
Europe CEE 7/7
Japan JIS 8,303
Australia AS 3,112
India BS 546
Italy CIE 2,316
Switzerland / Liechtenstein SEV 1011
Denmark / Greenland SRAF 1,962 / D816 / 87
Argentina AR1-10P
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If possible, it is recommended that each AC outlet reside on a separate circuit. With redundant AC, if a single circuit fails,
the switch’s remaining power supplies (on separate circuits) will likely be unaffected and can therefore continue operating.
Note. The switch must have power supply redundancy for the redundant AC circuit to be effective.
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The switch has two threaded holes for grounding screws located on the back of the chassis. These holes use 10-32 screws
and are approximately one inch apart. These holes are surrounded by a small paint-free rectangular area, which provides
metal-to-metal contact for a ground connection.
Use this connector to supplement the ground provided by the AC power cord. To do so, install a Panduit Grounding Lug
(type LCD8-10A-L) using 8AWG copper conductors to the paint-free rectangular area. Be sure to use a crimping tool.
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The operating temperature of your switch is an important factor in its overall operability. In order to avoid a temperature-
related system failure, your switch must always run at an operating temperature between 0 and 45 ºC (32 to 113 ºF).
To avoid chassis over-temperature conditions, follow these important guidelines:
Be sure that your switch is installed in a well-ventilated environment. To ensure adequate airflow, allow at least six inches of
clearance at the front and back of the chassis. In addition, leave at least two inches of clearance at the left and right sides.
Be sure that blank cover panels are installed at empty slot positions at all times. Blank cover panels help regulate airflow
and thus regulate the overall operating temperature in the switch. To check the switch’s current temperature status, use the
show temperature command.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 26 Alcatel.Lucent-ESD
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For MTBF definitions, calculation standards and methods, please see Appendix C.
Family Module Name MTBF-Hr MTBF-Yr
OS6855-14 PS-I40AC (40W AC Pwr Supply) 300687 34.325
PS-I40DC2448 (40W DC Pwr Supply) 273120 31.17808219
PS-I66AC-P (66W AC PoE Pwr Supp.) 339545 38.76084475
OS6855-14-PCBA (No PS. No SFP) 430389 49.13116438
OS6855-14+PS-I40AC (No SFP) 177016 20.20730594
OS6855-14+2(PS-I40AC) (No SFP) 242606 27.69474886
OS6855-14+PS-I40DC2448 (No SFP) 167088 19.0739726
OS6855-14+2(PS-I40DC2448) (No SFP) 230504 26.31324201
OS6855-14+PS-I40AC +PS-I40DC2448 (No SFP) 236695 27.01997717
OS6855-14+PS-I40AC +PS-I66AC-P (No SFP) 116356 13.2826484
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P) (No SFP) 191593 21.87134703
OS6855-14+PS-I40DC2448 +PS-I66AC-P (No SFP) 111982 12.78333333
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P) (No SFP) 185036 21.12283105
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P) (No SFP) 188405 21.50742009
ISFP-100-MM 5220297 595.9243151
ISFP-100-SM15 4491556 512.7347032
ISFP-100-SM40 4491556 512.7347032
ISFP-100-BX-U 8861320 1011.56621
ISFP-100-BX-D 8861320 1011.56621
ISFP-GIG-SX 7363770 840.6130137
ISFP-GIG-LX 4794094 547.2710046
ISFP-GIG-LH40 7053678 805.2143836
ISFP-GIG-LH70 7041758 803.853653
OS6855-14+PS-I40AC +2(ISFP-100-MM) 165774 18.9239726
OS6855-14+PS-I40AC +2(ISFP-100-SM15) 164083 18.73093607
OS6855-14+PS-I40AC +2(ISFP-100-SM40) 164083 18.73093607
OS6855-14+PS-I40AC +2(ISFP-100-BX-U) 170216 19.43105023
OS6855-14+PS-I40AC +2(ISFP-100-BX-D) 170216 19.43105023
OS6855-14+PS-I40AC+2(ISFP-GIG-SX) 168896 19.2803653
OS6855-14+PS-I40AC +2(ISFP-GIG-LX) 164843 18.81769406
OS6855-14+PS-I40AC +2(ISFP-GIG-LH40) 168556 19.24155251
OS6855-14+PS-I40AC +2(ISFP-GIG-LH70) 168543 19.24006849
OS6855-14+2(PS-I40AC) +2(ISFP-100-MM) 224683 25.64874429
OS6855-14+2(PS-I40AC) +2(ISFP-100-SM15) 222007 25.34326484
OS6855-14+2(PS-I40AC) +2(ISFP-100-SM40) 222007 25.34326484
OS6855-14+2(PS-I40AC) +2(ISFP-100-BX-U) 231738 26.45410959
OS6855-14+2(PS-I40AC) +2(ISFP-100-BX-D) 231738 26.45410959
OS6855-14+2(PS-I40AC) +2(ISFP-GIG-SX) 229639 26.21449772
OS6855-14+2(PS-I40AC) +2(ISFP-GIG-LX) 223209 25.48047945
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 27 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-14+2(PS-I40AC) +2(ISFP-GIG-LH40) 229098 26.15273973
OS6855-14+2(PS-I40AC) +2(ISFP-GIG-LH70) 229077 26.15034247
OS6855-14+PS-I40DC2448 +2(ISFP-100-MM) 157035 17.92636986
OS6855-14+PS-I40DC2448 +2(ISFP-100-SM15) 155517 17.75308219
OS6855-14+PS-I40DC2448 +2(ISFP-100-SM40) 155517 17.75308219
OS6855-14+PS-I40DC2448 +2(ISFP-100-BX-U) 161016 18.38082192
OS6855-14+PS-I40DC2448 +2(ISFP-100-BX-D) 161016 18.38082192
OS6855-14+PS-I40DC2448 +2(ISFP-GIG-SX) 159835 18.24600457
OS6855-14+PS-I40DC2448 +2(ISFP-GIG-LX) 156200 17.83105023
OS6855-14+PS-I40DC2448 +2(ISFP-GIG-LH40) 159530 18.21118721
OS6855-14+PS-I40DC2448 +2(ISFP-GIG-LH70) 159518 18.20981735
OS6855-14+2(PS-I40DC2448) +2(ISFP-100-MM) 214359 24.47020548
OS6855-14+2(PS-I40DC2448) +2(ISFP-100-SM15) 211938 24.19383562
OS6855-14+2(PS-I40DC2448) +2(ISFP-100-SM40) 211938 24.19383562
OS6855-14+2(PS-I40DC2448) +2(ISFP-100-BX-U) 220730 25.19748858
OS6855-14+2(PS-I40DC2448) +2(ISFP-100-BX-D) 220730 25.19748858
OS6855-14+2(PS-I40DC2448) +2(ISFP-GIG-SX) 218836 24.98127854
OS6855-14+2(PS-I40DC2448) +2(ISFP-GIG-LX) 213026 24.31803653
OS6855-14+2(PS-I40DC2448) +2(ISFP-GIG-LH40) 218349 24.92568493
OS6855-14+2(PS-I40DC2448) +2(ISFP-GIG-LH70) 218329 24.92340183
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-100-MM) 219645 25.07363014
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-100-SM15) 217094 24.78242009
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-100-SM40) 217094 24.78242009
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-100-BX-U) 226364 25.84063927
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-100-BX-D) 226364 25.84063927
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-GIG-SX) 224366 25.61255708
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-GIG-LX) 218240 24.91324201
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-GIG-LH40) 223851 25.55376712
OS6855-14+PS-I40AC+PS-I40DC2448 +2(ISFP-GIG-LH70) 223831 25.55148402
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-100-MM) 111390 12.71575342
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-100-SM15) 110624 12.6283105
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-100-SM40) 110624 12.6283105
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-100-BX-U) 113378 12.94269406
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-100-BX-D) 113378 12.94269406
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-GIG-SX) 112791 12.87568493
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-GIG-LX) 110969 12.66769406
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-GIG-LH40) 112640 12.85844749
OS6855-14+PS-I40AC+PS-I66AC-P +2(ISFP-GIG-LH70) 112634 12.85776256
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-100-MM) 180834 20.64315068
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-100-SM15) 179191 20.45559361
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-100-SM40) 179191 20.45559361
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-100-BX-U) 185119 21.13230594
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-100-BX-D) 185119 21.13230594
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-GIG-SX) 183851 20.98755708
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-GIG-LX) 179930 20.53995434
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 28 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-14+2(PS-I40AC)+2(PS-I66AC-P)+2(ISFP-GIG-LH40) 183523 20.95011416
OS6855-14+2(PS-I40AC) +2(PS-I66AC-P)+2(ISFP-GIG-LH70) 183510 20.94863014
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-100-MM) 107376 12.25753425
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-100-SM15) 106664 12.17625571
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-100-SM40) 106664 12.17625571
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-100-BX-U) 109222 12.46826484
OS6855-14+PS-I40DC2448+PS-I66AC-P+2(ISFP-100-BX-D) 109222 12.46826484
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-GIG-SX) 108677 12.40605023
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-GIG-LX) 106984 12.21278539
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-GIG-LH40) 108536 12.38995434
OS6855-14+PS-I40DC2448 +PS-I66AC-P+2(ISFP-GIG-LH70) 108530 12.38926941
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-100-MM) 175014 19.97876712
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-100-SM15) 173480 19.80365297
OS6855-14+2(PS-I40DC2448)+2(PS-I66AC-P)+2(ISFP-100-SM40) 173480 19.80365297
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-100-BX-U) 179010 20.43493151
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-100-BX-D) 179010 20.43493151
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-GIG-SX) 177828 20.3
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-GIG-LX) 174170 19.88242009
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-GIG-LH40) 177523 20.26518265
OS6855-14+2(PS-I40DC2448) +2(PS-I66AC-P)+2(ISFP-GIG-LH70) 177511 20.26381279
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-100-MM) 178006 20.32031963
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-100-SM15)
176416 20.13881279
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-100-SM40)
176416 20.13881279
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-100-BX-U)
182150 20.793379
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-100-BX-D)
182150 20.793379
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-GIG-SX) 180924 20.65342466
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-GIG-LX) 177132 20.22054795
OS6855-14+PS-I40AC+PS-I40DC2448+2(PS-I66AC-P)+2(ISFP-GIG-LH40)
180607 20.61723744
OS6855-14+PS-I40AC+PS-I40DC2448 +2(PS-I66AC-P)+2(ISFP-GIG-LH70)
180595 20.61586758
OS6855-U10 PS-I40AC (40W AC Pwr Supply) 300687 34.325
PS-I40DC2448 (40W DC Pwr Supply) 273120 31.17808219
OS6855-U10-PCBA (No PS. No SFP) 508942 58.09840183
OS6855-U10+PS-I40AC (No SFP) 189015 21.57705479
OS6855-U10+2(PS-I40AC) (No SFP) 261965 29.90468037
OS6855-U10+PS-I40DC2448 (No SFP) 177738 20.28972603
OS6855-U10+2(PS-I40DC2448)(No SFP) 247801 28.28778539
OS6855-U10+PS-I40AC +PS-I40DC2448 (No SFP) 255040 29.11415525
ISFP-100-MM 5220297 595.9243151
ISFP-100-SM15 4491556 512.7347032
ISFP-100-SM40 4491556 512.7347032
ISFP-100-BX-U 8861320 1011.56621
ISFP-100-BX-D 8861320 1011.56621
ISFP-GIG-SX 7363770 840.6130137
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 29 Alcatel.Lucent-ESD
Calabasas/CA./USA
ISFP-GIG-LX 4794094 547.2710046
ISFP-GIG-LH40 7053678 805.2143836
ISFP-GIG-LH70 7041758 803.853653
OS6855-U10+PS-I40AC +8(ISFP-100-MM) 146562 16.73082192
OS6855-U10+PS-I40AC +8(ISFP-100-SM15) 141409 16.14257991
OS6855-U10+PS-I40AC +8(ISFP-100-SM40) 141409 16.14257991
OS6855-U10+PS-I40AC +8(ISFP-100-BX-U) 161463 18.43184932
OS6855-U10+PS-I40AC +8(ISFP-100-BX-D) 161463 18.43184932
OS6855-U10+PS-I40AC +8(ISFP-GIG-SX) 156814 17.90114155
OS6855-U10+PS-I40AC +8(ISFP-GIG-LX) 143693 16.4033105
OS6855-U10+PS-I40AC +8(ISFP-GIG-LH40) 155648 17.76803653
OS6855-U10+PS-I40AC +8(ISFP-GIG-LH70) 155602 17.76278539
OS6855-U10+2(PS-I40AC) +8(ISFP-100-MM) 194586 22.2130137
OS6855-U10+2(PS-I40AC) +8(ISFP-100-SM15) 186511 21.29121005
OS6855-U10+2(PS-I40AC) +8(ISFP-100-SM40) 186511 21.29121005
OS6855-U10+2(PS-I40AC) +8(ISFP-100-BX-U) 217869 24.87089041
OS6855-U10+2(PS-I40AC) +8(ISFP-100-BX-D) 217869 24.87089041
OS6855-U10+2(PS-I40AC) +8(ISFP-GIG-SX) 210560 24.03652968
OS6855-U10+2(PS-I40AC) +8(ISFP-GIG-LX) 190020 21.69178082
OS6855-U10+2(PS-I40AC) +8(ISFP-GIG-LH40) 208733 23.82796804
OS6855-U10+2(PS-I40AC)+8(ISFP-GIG-LH70) 208660 23.8196347
OS6855-U10+PS-I40DC2448 +8(ISFP-100-MM) 139690 15.94634703
OS6855-U10+PS-I40DC2448 +8(ISFP-100-SM15) 135001 15.41107306
OS6855-U10+PS-I40DC2448 +8(ISFP-100-SM40) 135001 15.41107306
OS6855-U10+PS-I40DC2448 +8(ISFP-100-BX-U) 153162 17.48424658
OS6855-U10+PS-I40DC2448 +8(ISFP-100-BX-D) 153162 17.48424658
OS6855-U10+PS-I40DC2448 +8(ISFP-GIG-SX) 148972 17.00593607
OS6855-U10+PS-I40DC2448 +8(ISFP-GIG-LX) 137081 15.64851598
OS6855-U10+PS-I40DC2448 +8(ISFP-GIG-LH40) 147920 16.88584475
OS6855-U10+PS-I40DC2448 +8(ISFP-GIG-LH70) 147878 16.88105023
OS6855-U10+2(PS-I40DC2448) +8(ISFP-100-MM) 186955 21.34189498
OS6855-U10+2(PS-I40DC2448) +8(ISFP-100-SM15) 179654 20.50844749
OS6855-U10+2(PS-I40DC2448) +8(ISFP-100-SM40) 179654 20.50844749
OS6855-U10+2(PS-I40DC2448) +8(ISFP-100-BX-U) 208188 23.76575342
OS6855-U10+2(PS-I40DC2448) +8(ISFP-100-BX-D) 208188 23.76575342
OS6855-U10+2(PS-I40DC2448) +8(ISFP-GIG-SX) 201546 23.00753425
OS6855-U10+2(PS-I40DC2448) +8(ISFP-GIG-LX) 182887 20.87751142
OS6855-U10+2(PS-I40DC2448) +8(ISFP-GIG-LH40) 199883 22.81769406
OS6855-U10+2(PS-I40DC2448) +8(ISFP-GIG-LH70) 199817 22.81015982
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-100-MM) 190869 21.78869863
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-100-SM15) 183236 20.9173516
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-100-SM40) 183236 20.9173516
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-100-BX-U) 213146 24.33173516
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-100-BX-D) 213146 24.33173516
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-GIG-SX) 206165 23.53481735
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 30 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-GIG-LX) 186614 21.30296804
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-GIG-LH40) 204418 23.33538813
OS6855-U10+PS-I40AC+PS-I40DC2448 +8(ISFP-GIG-LH70) 204349 23.32751142
OS6855-24 OS6855-24-Fans 562238 64.18242009
PS-126I80AC (80W AC Pwr Supply) 561803 64.13276256
PS-120I80DC48 (80W-48VDC PS) 314515 35.90353881
PS-100I80DC24 (80W-24VDC PS) 316907 36.17659817
PS-360I160AC-P (160W AC PoE PS) 391673 44.71152968
OS6855-24-PCBA(No Fan.No PS.No SFP) 529644 60.46164384
OS6855-24 (No PS. No SFP) 272727 31.13321918
OS6855-24+PS-126I80AC (No SFP) 183599 20.95878995
OS6855-24+2(PS-126I80AC) (No SFP) 228757 26.11381279
OS6855-24+PS-120I80DC48 (No SFP) 146067 16.67431507
OS6855-24+2(PS-120I80DC48)(No SFP) 192263 21.94783105
OS6855-24+PS-100I80DC24 (No SFP) 146581 16.73299087
OS6855-24+2(PS-100I80DC24)(No SFP) 192812 22.01050228
OS6855-24+PS-126I80AC+PS-120I80DC48 (No SFP) 213638 24.38789954
OS6855-24+PS-126I80AC +PS-100I80DC24 (No SFP) 213829 24.4097032
OS6855-24+PS-126I80AC +PS-360I160AC-P (No SFP) 125003 14.26974886
OS6855-24+PS-120I80DC48 +PS-100I80DC24 (No SFP) 192538 21.97922374
OS6855-24+PS-120I80DC48 +PS-360I160AC-P (No SFP) 106391 12.14509132
OS6855-24+PS-100I80DC24 +PS-360I160AC-P (No SFP) 106663 12.17614155
ISFP-100-MM 5220297 595.9243151
ISFP-100-SM15 4491556 512.7347032
ISFP-100-SM40 4491556 512.7347032
ISFP-100-BX-U 8861320 1011.56621
ISFP-100-BX-D 8861320 1011.56621
ISFP-GIG-SX 7363770 840.6130137
ISFP-GIG-LX 4794094 547.2710046
ISFP-GIG-LH40 7053678 805.2143836
ISFP-GIG-LH70 7041758 803.853653
OS6855-24+PS-126I80AC +4(ISFP-100-MM) 160956 18.3739726
OS6855-24+PS-126I80AC +4(ISFP-100-SM15) 157798 18.01347032
OS6855-24+PS-126I80AC+4(ISFP-100-SM40) 157798 18.01347032
OS6855-24+PS-126I80AC +4(ISFP-100-BX-U) 169548 19.35479452
OS6855-24+PS-126I80AC +4(ISFP-100-BX-D) 169548 19.35479452
OS6855-24+PS-126I80AC +4(ISFP-GIG-SX) 166949 19.05810502
OS6855-24+PS-126I80AC +4(ISFP-GIG-LX) 159210 18.17465753
OS6855-24+PS-126I80AC+4(ISFP-GIG-LH40) 166286 18.98242009
OS6855-24+PS-126I80AC +4(ISFP-GIG-LH70) 166260 18.97945205
OS6855-24+2(PS-126I80AC)+4(ISFP-100-MM) 196761 22.46130137
OS6855-24+2(PS-126I80AC) +4(ISFP-100-SM15) 192365 21.95947489
OS6855-24+2(PS-126I80AC) +4(ISFP-100-SM40) 192365 21.95947489
OS6855-24+2(PS-126I80AC) +4(ISFP-100-BX-U) 208806 23.83630137
OS6855-24+2(PS-126I80AC) +4(ISFP-100-BX-D) 208806 23.83630137
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 31 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-24+2(PS-126I80AC) +4(ISFP-GIG-SX) 205151 23.41906393
OS6855-24+2(PS-126I80AC) +4(ISFP-GIG-LX) 194329 22.1836758
OS6855-24+2(PS-126I80AC) +4(ISFP-GIG-LH40) 204220 23.31278539
OS6855-24+2(PS-126I80AC) +4(ISFP-GIG-LH70) 204183 23.30856164
OS6855-24+PS-120I80DC48 +4(ISFP-100-MM) 131365 14.99600457
OS6855-24+PS-120I80DC48 +4(ISFP-100-SM15) 129254 14.75502283
OS6855-24+PS-120I80DC48 +4(ISFP-100-SM40) 129254 14.75502283
OS6855-24+PS-120I80DC48 +4(ISFP-100-BX-U) 137032 15.64292237
OS6855-24+PS-120I80DC48 +4(ISFP-100-BX-D) 137032 15.64292237
OS6855-24+PS-120I80DC48 +4(ISFP-GIG-SX) 135330 15.44863014
OS6855-24+PS-120I80DC48 +4(ISFP-GIG-LX) 130199 14.86289954
OS6855-24+PS-120I80DC48 +4(ISFP-GIG-LH40) 134894 15.39885845
OS6855-24+PS-120I80DC48 +4(ISFP-GIG-LH70) 134876 15.39680365
OS6855-24+2(PS-120I80DC48) +4(ISFP-100-MM) 169982 19.4043379
OS6855-24+2(PS-120I80DC48) +4(ISFP-100-SM15) 166821 19.04349315
OS6855-24+2(PS-120I80DC48) +4(ISFP-100-SM40) 166821 19.04349315
OS6855-24+2(PS-120I80DC48) +4(ISFP-100-BX-U) 178518 20.37876712
OS6855-24+2(PS-120I80DC48) +4(ISFP-100-BX-D) 178518 20.37876712
OS6855-24+2(PS-120I80DC48) +4(ISFP-GIG-SX) 175947 20.08527397
OS6855-24+2(PS-120I80DC48) +4(ISFP-GIG-LX) 168236 19.20502283
OS6855-24+2(PS-120I80DC48) +4(ISFP-GIG-LH40) 175289 20.01015982
OS6855-24+2(PS-120I80DC48) +4(ISFP-GIG-LH70) 175263 20.00719178
OS6855-24+PS-100I80DC24+4(ISFP-100-MM) 131780 15.043379
OS6855-24+PS-100I80DC24 +4(ISFP-100-SM15) 129656 14.80091324
OS6855-24+PS-100I80DC24 +4(ISFP-100-SM40) 129656 14.80091324
OS6855-24+PS-100I80DC24 +4(ISFP-100-BX-U) 137484 15.69452055
OS6855-24+PS-100I80DC24 +4(ISFP-100-BX-D) 137484 15.69452055
OS6855-24+PS-100I80DC24 +4(ISFP-GIG-SX) 135771 15.4989726
OS6855-24+PS-100I80DC24 +4(ISFP-GIG-LX) 130608 14.90958904
OS6855-24+PS-100I80DC24 +4(ISFP-GIG-LH40) 135332 15.44885845
OS6855-24+PS-100I80DC24 +4(ISFP-GIG-LH70) 135314 15.44680365
OS6855-24+2(PS-100I80DC24) +4(ISFP-100-MM) 170400 19.45205479
OS6855-24+2(PS-100I80DC24) +4(ISFP-100-SM15) 167222 19.08926941
OS6855-24+2(PS-100I80DC24) +4(ISFP-100-SM40) 167222 19.08926941
OS6855-24+2(PS-100I80DC24)+4(ISFP-100-BX-U) 178984 20.43196347
OS6855-24+2(PS-100I80DC24) +4(ISFP-100-BX-D) 178984 20.43196347
OS6855-24+2(PS-100I80DC24) +4(ISFP-GIG-SX) 176398 20.13675799
OS6855-24+2(PS-100I80DC24) +4(ISFP-GIG-LX) 168644 19.25159817
OS6855-24+2(PS-100I80DC24) +4(ISFP-GIG-LH40) 175737 20.06130137
OS6855-24+2(PS-100I80DC24) +4(ISFP-GIG-LH70) 175710 20.05821918
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-100-MM) 185787 21.20856164
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-100-SM15) 181914 20.76643836
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-100-SM40) 181914 20.76643836
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-100-BX-U) 196341 22.41335616
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-100-BX-D) 196341 22.41335616
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 32 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-GIG-SX) 193147 22.04874429
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-GIG-LX) 183645 20.9640411
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-GIG-LH40) 192333 21.95582192
OS6855-24+PS-126I80AC +PS-120I80DC48+4(ISFP-GIG-LH70) 192300 21.95205479
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-100-MM) 185930 21.22488584
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-100-SM15) 182051 20.78207763
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-100-SM40) 182051 20.78207763
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-100-BX-U) 196502 22.43173516
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-100-BX-D) 196502 22.43173516
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-GIG-SX) 193303 22.06655251
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-GIG-LX) 183785 20.98002283
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-GIG-LH40) 192487 21.97340183
OS6855-24+PS-126I80AC +PS-100I80DC24+4(ISFP-GIG-LH70) 192454 21.9696347
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-100-MM) 114077 13.02248858
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-100-SM15) 112481 12.8402968
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-100-SM40) 112481 12.8402968
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-100-BX-U) 118326 13.50753425
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-100-BX-D) 118326 13.50753425
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-GIG-SX) 117055 13.36244292
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-GIG-LX) 113197 12.92203196
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-GIG-LH40) 116729 13.32522831
OS6855-24+PS-126I80AC +PS-360I160AC-P+4(ISFP-GIG-LH70) 116715 13.32363014
OS6855-24+PS-120I80DC48+PS-100I80DC24+4(ISFP-100-MM) 170192 19.4283105
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-100-SM15) 167022 19.06643836
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-100-SM40) 167022 19.06643836
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-100-BX-U) 178751 20.4053653
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-100-BX-D) 178751 20.4053653
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-GIG-SX) 176173 20.11107306
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-GIG-LX) 168441 19.22842466
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-GIG-LH40) 175514 20.03584475
OS6855-24+PS-120I80DC48 +PS-100I80DC24+4(ISFP-GIG-LH70) 175487 20.03276256
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-100-MM) 98371 11.22956621
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-100-SM15) 97183 11.09394977
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-100-SM40) 97183 11.09394977
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-100-BX-U) 101515 11.58847032
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-100-BX-D) 101515 11.58847032
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-GIG-SX) 100578 11.48150685
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-GIG-LX) 97717 11.15490868
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-GIG-LH40) 100337 11.45399543
OS6855-24+PS-120I80DC48 +PS-360I160AC-P+4(ISFP-GIG-LH70) 100327 11.45285388
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-100-MM) 98604 11.25616438
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-100-SM15) 97410 11.11986301
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-100-SM40) 97410 11.11986301
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-100-BX-U) 101763 11.61678082
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-100-BX-D) 101763 11.61678082
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 33 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-GIG-SX) 100822 11.50936073
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-GIG-LX) 97946 11.18105023
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-GIG-LH40) 100579 11.481621
OS6855-24+PS-100I80DC24 +PS-360I160AC-P+4(ISFP-GIG-LH70) 100570 11.48059361
OS6855-U24 OS6855-U24-Fans 562238 64.18242009
PS-126I80AC (80W AC Pwr Supply OS6855-PSL) 561803 64.13276256
PS-120I80DC48 (80W-48VDC PS OS6855-PSL-D ) 314515 35.90353881
PS-100I80DC24 (80W-24VDC PS OS6855-PSL-DL ) 316907 36.17659817
OS6855-U24-PCBA(No Fan.No PS.No SFP) 488705 55.78824201
OS6855-U24 (No PS. No SFP) 261449 29.84577626
OS6855-U24+PS-126I80AC (No SFP) 178418 20.3673516
OS6855-U24+2(PS-126I80AC) (No SFP) 221365 25.26997717
OS6855-U24+PS-120I80DC48 (No SFP) 142769 16.29783105
OS6855-U24+2(PS-120I80DC48)(No SFP) 187226 21.37283105
OS6855-U24+PS-100I80DC24 (No SFP) 143260 16.35388128
OS6855-U24+2(PS-100I80DC24)(No SFP) 187744 21.43196347
OS6855-U24+PS-126I80AC +PS-120I80DC48 (No SFP) 207256 23.65936073
OS6855-U24+PS-126I80AC +PS-100I80DC24 (No SFP) 207436 23.67990868
OS6855-U24+PS-120I80DC48 +PS-100I80DC24 (No SFP) 187485 21.40239726
ISFP-100-MM 5220297 595.9243151
ISFP-100-SM15 4491556 512.7347032
ISFP-100-SM40 4491556 512.7347032
ISFP-100-BX-U 8861320 1011.56621
ISFP-100-BX-D 8861320 1011.56621
ISFP-GIG-SX 7363770 840.6130137
ISFP-GIG-LX 4794094 547.2710046
ISFP-GIG-LH40 7053678 805.2143836
ISFP-GIG-LH70 7041758 803.853653
OS6855-U24+PS-126I80AC +24(ISFP-100-MM) 98018 11.18926941
OS6855-U24+PS-126I80AC +24(ISFP-100-SM15) 91339 10.42682648
OS6855-U24+PS-126I80AC +24(ISFP-100-SM40) 91339 10.42682648
OS6855-U24+PS-126I80AC +24(ISFP-100-BX-U) 120290 13.73173516
OS6855-U24+PS-126I80AC +24(ISFP-100-BX-D) 120290 13.73173516
OS6855-U24+PS-126I80AC +24(ISFP-GIG-SX) 112816 12.87853881
OS6855-U24+PS-126I80AC +24(ISFP-GIG-LX) 94242 10.75821918
OS6855-U24+PS-126I80AC +24(ISFP-GIG-LH40) 111021 12.67363014
OS6855-U24+PS-126I80AC +24(ISFP-GIG-LH70) 110950 12.66552511
OS6855-U24+2(PS-126I80AC) +24(ISFP-100-MM) 112572 12.85068493
OS6855-U24+2(PS-126I80AC) +24(ISFP-100-SM15) 104108 11.88447489
OS6855-U24+2(PS-126I80AC) +24(ISFP-100-SM40) 104108 11.88447489
OS6855-U24+2(PS-126I80AC) +24(ISFP-100-BX-U) 141491 16.15194064
OS6855-U24+2(PS-126I80AC)+24(ISFP-100-BX-D) 141491 16.15194064
OS6855-U24+2(PS-126I80AC) +24(ISFP-GIG-SX) 131671 15.03093607
OS6855-U24+2(PS-126I80AC) +24(ISFP-GIG-LX) 107775 12.30308219
OS6855-U24+2(PS-126I80AC) +24(ISFP-GIG-LH40) 129331 14.76381279
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 34 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-U24+2(PS-126I80AC) +24(ISFP-GIG-LH70) 129238 14.75319635
OS6855-U24+PS-120I80DC48 +24(ISFP-100-MM) 86194 9.839497717
OS6855-U24+PS-120I80DC48 +24(ISFP-100-SM15) 80987 9.245091324
OS6855-U24+PS-120I80DC48 +24(ISFP-100-SM40) 80987 9.245091324
OS6855-U24+PS-120I80DC48 +24(ISFP-100-BX-U) 102958 11.75319635
OS6855-U24+PS-120I80DC48 +24(ISFP-100-BX-D) 102958 11.75319635
OS6855-U24+PS-120I80DC48 +24(ISFP-GIG-SX) 97432 11.12237443
OS6855-U24+PS-120I80DC48 +24(ISFP-GIG-LX) 83261 9.504680365
OS6855-U24+PS-120I80DC48 +24(ISFP-GIG-LH40) 96091 10.96929224
OS6855-U24+PS-120I80DC48 +24(ISFP-GIG-LH70) 96038 10.96324201
OS6855-U24+2(PS-120I80DC48) +24(ISFP-100-MM) 104716 11.95388128
OS6855-U24+2(PS-120I80DC48) +24(ISFP-100-SM15) 97556 11.13652968
OS6855-U24+2(PS-120I80DC48) +24(ISFP-100-SM40) 97556 11.13652968
OS6855-U24+2(PS-120I80DC48)+24(ISFP-100-BX-U) 128313 14.64760274
OS6855-U24+2(PS-120I80DC48)+24(ISFP-100-BX-D) 128313 14.64760274
OS6855-U24+2(PS-120I80DC48) +24(ISFP-GIG-SX) 120448 13.74977169
OS6855-U24+2(PS-120I80DC48) +24(ISFP-GIG-LX) 100672 11.49223744
OS6855-U24+2(PS-120I80DC48) +24(ISFP-GIG-LH40) 118551 13.53321918
OS6855-U24+2(PS-120I80DC48) +24(ISFP-GIG-LH70) 118476 13.52465753
OS6855-U24+PS-100I80DC24 +24(ISFP-100-MM) 86372 9.859817352
OS6855-U24+PS-100I80DC24 +24(ISFP-100-SM15) 81145 9.263127854
OS6855-U24+PS-100I80DC24 +24(ISFP-100-SM40) 81145 9.263127854
OS6855-U24+PS-100I80DC24 +24(ISFP-100-BX-U) 103213 11.78230594
OS6855-U24+PS-100I80DC24 +24(ISFP-100-BX-D) 103213 11.78230594
OS6855-U24+PS-100I80DC24+24(ISFP-GIG-SX) 97661 11.14851598
OS6855-U24+PS-100I80DC24 +24(ISFP-GIG-LX) 83427 9.523630137
OS6855-U24+PS-100I80DC24+24(ISFP-GIG-LH40) 96313 10.9946347
OS6855-U24+PS-100I80DC24+24(ISFP-GIG-LH70) 96260 10.98858447
OS6855-U24+2(PS-100I80DC24)+24(ISFP-100-MM) 104853 11.96952055
OS6855-U24+2(PS-100I80DC24) +24(ISFP-100-SM15) 97672 11.14977169
OS6855-U24+2(PS-100I80DC24) +24(ISFP-100-SM40) 97672 11.14977169
OS6855-U24+2(PS-100I80DC24) +24(ISFP-100-BX-U) 128534 14.67283105
OS6855-U24+2(PS-100I80DC24) +24(ISFP-100-BX-D) 128534 14.67283105
OS6855-U24+2(PS-100I80DC24) +24(ISFP-GIG-SX) 120638 13.77146119
OS6855-U24+2(PS-100I80DC24) +24(ISFP-GIG-LX) 100797 11.50650685
OS6855-U24+2(PS-100I80DC24) +24(ISFP-GIG-LH40) 118734 13.55410959
OS6855-U24+2(PS-100I80DC24) +24(ISFP-GIG-LH70) 118659 13.54554795
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-100-MM) 109471 12.4966895
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-100-SM15) 101534 11.59063927
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-100-SM40) 101534 11.59063927
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-100-BX-U) 136212 15.54931507
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-100-BX-D) 136212 15.54931507
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-SX) 127197 14.52020548
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-LX) 104979 11.98390411
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-LH40) 125038 14.27374429
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 35 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-U24+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-LH70) 124953 14.2640411
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-100-MM) 109515 12.50171233
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-100-SM15) 101571 11.59486301
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-100-SM40) 101571 11.59486301
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-100-BX-U) 136286 15.55776256
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-100-BX-D) 136286 15.55776256
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-SX) 127259 14.52728311
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-LX) 105019 11.98847032
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-LH40) 125098 14.28059361
OS6855-U24+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-LH70) 125013 14.27089041
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-MM) 104785 11.96175799
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-SM15) 97614 11.14315068
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-SM40) 97614 11.14315068
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-BX-U) 128424 14.66027397
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-BX-D) 128424 14.66027397
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-SX) 120543 13.76061644
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-LX) 100735 11.49942922
OS6855-U24+PS-120I80DC48+PS-100I80DC24+24(ISFP-GIG-LH40) 118643 13.54372146
OS6855-U24+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-LH70) 118568 13.53515982
OS6855-U24X OS6855-U24X (No PS. No SFP) 373980 42.69178082
OS6855-U24X+PS-126I80AC (No SFP) 224521 25.63025114
OS6855-U24X+2(PS-126I80AC)(No SFP) 288502 32.93401826
OS6855-U24X+PS-120I80DC48(No SFP) 170840 19.50228311
OS6855-U24X+2(PS-120I80DC48)(No SFP) 230969 26.3663242
OS6855-U24X+PS-100I80DC24(No SFP) 171543 19.58253425
OS6855-U24X+2(PS-100I80DC24)(No SFP) 231784 26.45936073
OS6855-U24X+PS-126I80AC +PS-120I80DC48 (No SFP) 264149 30.15399543
OS6855-U24X+PS-126I80AC +PS-100I80DC24 (No SFP) 264441 30.18732877
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24 (No SFP) 231378 26.4130137
OS6855-U24X+PS-126I80AC +24(ISFP-100-MM) 110481 12.6119863
OS6855-U24X+PS-126I80AC +24(ISFP-100-SM15) 102069 11.65171233
OS6855-U24X+PS-126I80AC +24(ISFP-100-SM40) 102069 11.65171233
OS6855-U24X+PS-126I80AC +24(ISFP-100-BX-U) 139620 15.93835616
OS6855-U24X+PS-126I80AC +24(ISFP-100-BX-D) 139620 15.93835616
OS6855-U24X+PS-126I80AC +24(ISFP-100-BXLC-U) 144596 16.50639269
OS6855-U24X+PS-126I80AC +24(ISFP-100-BXLC-D) 144596 16.50639269
OS6855-U24X+PS-126I80AC +24(ISFP-GIG-SX) 129649 14.80011416
OS6855-U24X+PS-126I80AC +24(ISFP-GIG-LX) 105707 12.06700913
OS6855-U24X+PS-126I80AC +24(ISFP-GIG-LH40) 127285 14.53025114
OS6855-U24X+PS-126I80AC +24(ISFP-GIG-LH70) 127191 14.51952055
OS6855-U24X+PS-126I80AC +24(ISFP-GIG-BX-U) 109241 12.47043379
OS6855-U24X+PS-126I80AC +24(ISFP-GIG-BX-D) 109427 12.49166667
OS6855-U24X+PS-126I80AC +24(ISFP-GIG-T) 138157 15.77134703
OS6855-U24X+PS-126I80AC +2(ISFP-10G-SR) 212748 24.28630137
OS6855-U24X+PS-126I80AC +2(ISFP-10G-LR) 195212 22.28447489
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 36 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-U24X+2(PS-126I80AC) +24(ISFP-100-MM) 128627 14.68344749
OS6855-U24X+2(PS-126I80AC) +24(ISFP-100-SM15) 117755 13.4423516
OS6855-U24X+2(PS-126I80AC) +24(ISFP-100-SM40) 117755 13.4423516
OS6855-U24X+2(PS-126I80AC) +24(ISFP-100-BX-U) 167388 19.10821918
OS6855-U24X+2(PS-126I80AC) +24(ISFP-100-BX-D) 167388 19.10821918
OS6855-U24X+2(PS-126I80AC) +24(ISFP-100-BXLC-U) 174168 19.88219178
OS6855-U24X+2(PS-126I80AC) +24(ISFP-100-BXLC-D) 174168 19.88219178
OS6855-U24X+2(PS-126I80AC) +24(ISFP-GIG-SX) 153941 17.57317352
OS6855-U24X+2(PS-126I80AC) +24(ISFP-GIG-LX) 122440 13.97716895
OS6855-U24X+2(PS-126I80AC) +24(ISFP-GIG-LH40) 150780 17.21232877
OS6855-U24X+2(PS-126I80AC) +24(ISFP-GIG-LH70) 150655 17.19805936
OS6855-U24X+2(PS-126I80AC) +24(ISFP-GIG-BX-U) 127015 14.49942922
OS6855-U24X+2(PS-126I80AC) +24(ISFP-GIG-BX-D) 127257 14.52705479
OS6855-U24X+2(PS-126I80AC) +24(ISFP-GIG-T) 165404 18.88173516
OS6855-U24X+2(PS-126I80AC) +2(ISFP-10G-SR) 271080 30.94520548
OS6855-U24X+2(PS-126I80AC) +2(ISFP-10G-LR) 245469 28.02157534
OS6855-U24X+PS-120I80DC48 +24(ISFP-100-MM) 95686 10.92305936
OS6855-U24X+PS-120I80DC48 +24(ISFP-100-SM15) 89311 10.19531963
OS6855-U24X+PS-120I80DC48 +24(ISFP-100-SM40) 89311 10.19531963
OS6855-U24X+PS-120I80DC48 +24(ISFP-100-BX-U) 116797 13.33299087
OS6855-U24X+PS-120I80DC48 +24(ISFP-100-BX-D) 116797 13.33299087
OS6855-U24X+PS-120I80DC48 +24(ISFP-100-BXLC-U) 120259 13.72819635
OS6855-U24X+PS-120I80DC48 +24(ISFP-100-BXLC-D) 120259 13.72819635
OS6855-U24X+PS-120I80DC48 +24(ISFP-GIG-SX) 109738 12.52716895
OS6855-U24X+PS-120I80DC48 +24(ISFP-GIG-LX) 92084 10.51187215
OS6855-U24X+PS-120I80DC48 +24(ISFP-GIG-LH40) 108039 12.33321918
OS6855-U24X+PS-120I80DC48 +24(ISFP-GIG-LH70) 107972 12.32557078
OS6855-U24X+PS-120I80DC48 +24(ISFP-GIG-BX-U) 94754 10.81666667
OS6855-U24X+PS-120I80DC48 +24(ISFP-GIG-BX-D) 94895 10.83276256
OS6855-U24X+PS-120I80DC48 +24(ISFP-GIG-T) 115772 13.21598174
OS6855-U24X+PS-120I80DC48 +2(ISFP-10G-SR) 163937 18.71426941
OS6855-U24X+PS-120I80DC48 +2(ISFP-10G-LR) 153324 17.50273973
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-100-MM) 117979 13.46792237
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-100-SM15) 109043 12.44783105
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-100-SM40) 109043 12.44783105
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-100-BX-U) 148371 16.93732877
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-100-BX-D) 148371 16.93732877
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-100-BXLC-U) 153463 17.51860731
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-100-BXLC-D) 153463 17.51860731
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-GIG-SX) 138076 15.76210046
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-GIG-LX) 112916 12.88995434
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-GIG-LH40) 135619 15.481621
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-GIG-LH70) 135522 15.47054795
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-GIG-BX-U) 116666 13.31803653
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-GIG-BX-D) 116864 13.34063927
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 37 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-U24X+2(PS-120I80DC48) +24(ISFP-GIG-T) 146869 16.76586758
OS6855-U24X+2(PS-120I80DC48) +2(ISFP-10G-SR) 220104 25.1260274
OS6855-U24X+2(PS-120I80DC48) +2(ISFP-10G-LR) 203568 23.23835616
OS6855-U24X+PS-100I80DC24 +24(ISFP-100-MM) 95906 10.94817352
OS6855-U24X+PS-100I80DC24 +24(ISFP-100-SM15) 89503 10.21723744
OS6855-U24X+PS-100I80DC24 +24(ISFP-100-SM40) 89503 10.21723744
OS6855-U24X+PS-100I80DC24+24(ISFP-100-BX-U) 117126 13.37054795
OS6855-U24X+PS-100I80DC24 +24(ISFP-100-BX-D) 117126 13.37054795
OS6855-U24X+PS-100I80DC24 +24(ISFP-100-BXLC-U) 120608 13.76803653
OS6855-U24X+PS-100I80DC24 +24(ISFP-100-BXLC-D) 120608 13.76803653
OS6855-U24X+PS-100I80DC24 +24(ISFP-GIG-SX) 110027 12.56015982
OS6855-U24X+PS-100I80DC24 +24(ISFP-GIG-LX) 92288 10.53515982
OS6855-U24X+PS-100I80DC24 +24(ISFP-GIG-LH40) 108320 12.3652968
OS6855-U24X+PS-100I80DC24 +24(ISFP-GIG-LH70) 108252 12.35753425
OS6855-U24X+PS-100I80DC24 +24(ISFP-GIG-BX-U) 94970 10.8413242
OS6855-U24X+PS-100I80DC24 +24(ISFP-GIG-BX-D) 95111 10.85742009
OS6855-U24X+PS-100I80DC24 +24(ISFP-GIG-T) 116095 13.25285388
OS6855-U24X+PS-100I80DC24 +2(ISFP-10G-SR) 164584 18.78812785
OS6855-U24X+PS-100I80DC24 +2(ISFP-10G-LR) 153890 17.5673516
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-100-MM) 118160 13.48858447
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-100-SM15) 109194 12.46506849
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-100-SM40) 109194 12.46506849
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-100-BX-U) 148679 16.97248858
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-100-BX-D) 148679 16.97248858
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-100-BXLC-U) 153795 17.55650685
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-100-BXLC-D) 153795 17.55650685
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-GIG-SX) 138337 15.79189498
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-GIG-LX) 113080 12.9086758
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-GIG-LH40) 135869 15.51015982
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-GIG-LH70) 135772 15.49908676
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-GIG-BX-U) 116843 13.33824201
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-GIG-BX-D) 117041 13.36084475
OS6855-U24X+2(PS-100I80DC24) +24(ISFP-GIG-T) 147170 16.80022831
OS6855-U24X+2(PS-100I80DC24) +2(ISFP-10G-SR) 220839 25.20993151
OS6855-U24X+2(PS-100I80DC24) +2(ISFP-10G-LR) 204188 23.30913242
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-100-MM) 124388 14.19954338
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-100-SM15) 114306 13.04863014
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-100-SM40) 114306 13.04863014
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-100-BX-U) 159681 18.22842466
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-100-BX-D) 159681 18.22842466
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-100-BXLC-U) 165753 18.92157534
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-100-BXLC-D) 165753 18.92157534
OS6855-U24X+PS-126I80AC+PS-120I80DC48+24(ISFP-GIG-SX) 147550 16.84360731
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-LX) 118660 13.5456621
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-LH40) 144681 16.51609589
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 38 Alcatel.Lucent-ESD
Calabasas/CA./USA
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-LH70) 144568 16.50319635
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-BX-U) 122899 14.02956621
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-BX-D) 123123 14.05513699
OS6855-U24X+PS-126I80AC +PS-120I80DC48+24(ISFP-GIG-T) 157899 18.025
OS6855-U24X+PS-126I80AC +PS-120I80DC48+2(ISFP-10G-SR) 249607 28.49394977
OS6855-U24X+PS-126I80AC +PS-120I80DC48+2(ISFP-10G-LR) 227958 26.02260274
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-100-MM) 124448 14.20639269
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-100-SM15) 114355 13.05422374
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-100-SM40) 114355 13.05422374
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-100-BX-U) 159785 18.2402968
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-100-BX-D) 159785 18.2402968
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-100-BXLC-U) 165865 18.93436073
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-100-BXLC-D) 165865 18.93436073
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-SX) 147638 16.85365297
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-LX) 118713 13.55171233
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-LH40) 144765 16.52568493
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-LH70) 144651 16.51267123
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-BX-U) 122957 14.03618721
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-BX-D) 123181 14.06175799
OS6855-U24X+PS-126I80AC +PS-100I80DC24+24(ISFP-GIG-T) 158000 18.03652968
OS6855-U24X+PS-126I80AC +PS-100I80DC24+2(ISFP-10G-SR) 249869 28.52385845
OS6855-U24X+PS-126I80AC +PS-100I80DC24+2(ISFP-10G-LR) 228176 26.04748858
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-MM) 118070 13.4783105
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-SM15) 109118 12.45639269
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-SM40) 109118 12.45639269
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-BX-U) 148525 16.95490868
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-BX-D) 148525 16.95490868
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-BXLC-U) 153629 17.53755708
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-100-BXLC-D) 153629 17.53755708
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-SX) 138207 15.77705479
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-LX) 112998 12.89931507
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-LH40) 135744 15.49589041
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-LH70) 135647 15.48481735
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-BX-U) 116755 13.32819635
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+24(ISFP-GIG-BX-D) 116953 13.35079909
OS6855-U24X+PS-120I80DC48+PS-100I80DC24+24(ISFP-GIG-T) 147020 16.78310502
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+2(ISFP-10G-SR) 220472 25.16803653
OS6855-U24X+PS-120I80DC48 +PS-100I80DC24+2(ISFP-10G-LR) 203879 23.27385845
RReegguullaattoorryy CCoommpplliiaannccee aanndd SSaaffeettyy IInnffoorrmmaattiioonn
This section provides information on regulatory agency compliance and safety for the OmniSwitch 6855 Series.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 39 Alcatel.Lucent-ESD
Calabasas/CA./USA
DDeeccllaarraattiioonn ooff CCoonnffoorrmmiittyy:: CCEE MMaarrkk
This equipment is in compliance with the essential requirements and other provisions of Directive 73/23/EEC and 89/336/EEC as amended by Directive 93/68/EEC.
WWaassttee EElleeccttrriiccaall aanndd EElleeccttrroonniicc EEqquuiippmmeenntt ((WWEEEEEE)) SSttaatteemmeenntt
The product at end of life is subject to separate collection and treatment in the EU Member States, Norway and Switzerland. Treatment applied at end of life of the product in these countries shall comply with the applicable national laws implementing directive 2002/96EC on waste electrical and electronic equipment (WEEE).
SSttaannddaarrddss CCoommpplliiaannccee
The product bears the CE mark. In addition it is in compliance with the following other safety and EMC standards. Note: EN = European Norm, IEC = International Electro-technical Commission All hardware-switching platforms comply with Class A standards for digital devices per AS/NZS 3548, CISPR 22, EN55022, the FCC Part 15, ICES-003, and VCCI standards. Modules with copper connectors meet Class A requirements using unshielded (UTP) cables, but meet Class B requirements using shielded (STP) cables.
SSaaffeettyy SSttaannddaarrddss
• US UL 60950 • IEC 60950-1:2001; all national deviations • EN 60950-1: 2001; all deviations • CAN/CSA-C22.2 No. 60950-1-03 • NOM-019 SCFI, Mexico • AS/NZ TS-001 and 60950:2000, Australia • UL-AR, Argentina • UL-GS Mark, Germany • EN 60825-1 Laser, EN60825-2 Laser • CDRH for UL (Safety Laser Evaluation)
EEMMCC SSttaannddaarrddss
Commercial EMI/EMC • FCC CRF Title 47 Subpart B (Class A and Class B* limits) • VCCI (Class A and Class B* limits • AS/NZS 3548 (Class A and Class B*) • CE marking for European countries (Class A and Class B*) • EN 55022: 2006 (Emission Standard) • EN 61000-3-3: 1995 • EN 61000-3-2: 2006 • EN 55024: 1998 (Immunity Standards)
- EN 61000-4-2: 1995+A1: 1998 - EN 61000-4-3: 1996+A1: 1998 - EN 61000-4-4: 1995 - EN 61000-4-5: 1995 - EN 61000-4-6: 1996 - EN 61000-4-8: 1994 - EN 61000-4-11: 1994
• IEEE802.3: Hi-Pot Test (2250 VDC on all Ethernet ports)
* Class A with UTP cables and Class B with STP cables
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 40 Alcatel.Lucent-ESD
Calabasas/CA./USA
Industrial IEC 60870-2-2 (operational temperature) IEC 60068-2-1 (temperature type test – cold) IEC 60068-2-2 (temperature type test – hot) IEC 60721-3-1: Class 1K5 (storage temperature) IEC 68-2-30 95% non-condensing humidity IEC 60255-21-2 (mechanical shock) IEC 60255-21-1 (vibration) EN 61131-2 EN 61000-6-4 :2007 (emission standard for industrial environments) EN 61000-6-2 :2005 ( immunity standard for industrial environments) EN 55024: 1998 (Immunity Standards)
-IEC 61000-4-3 -IEC 61000-4-12 -IEC 61000-4-16 -IEC 61000-4-17 -IEC 61000-4-29
IEC 60255-5 IEC 61850-3 (Electric power Substations) – see details in table below IEEE 1613 (C37.90.x)
C37.90.3 (ESD) C37.90.2 (Radiated RFI) IEEE1613 C37.90.1 (Fast Transient ) IEEE1613 C37.90.1 ( Oscillatory ) IEEE1613 C37.90 (H.V. Impulse) IEEE1613 C37.90 (Dielectric Strength)
IEC 62236-4:2008- Railway applications: Electromagnetic compatibility – Part 4 EN 50121-4:2006 for Class A device
IEC 61850-3:2002 Details
Standards/Specification Test Description Limits/Test Specification
EN 55022:2006 Conducted Emissions - Voltage Class A & Class B
EN 55022:2006 Conducted Distrubance at Telecom Ports Class A & Class B
EN 55022:2006 Radiated Emissions Class A & Class B
EN 61000-3-2:2000 Harmonic Current Emissions Quasi-Stationary Current Harmonics Test
230V@50Hz, 39th Odd Harmonics and 40th Even harmonics
EN 61000-3-3:1995+A1:2001 Voltage Fluctuations/Flicker Voltage Fluctuation and Flicker Test
230V@50Hz.
EN61000-4-2:1995+A1:1998+A2:2002 Electrostatic Discharge Immunity Air Discharge: + 15kV Contact Discharge: + 8kV
EN61000-4-3:2002+A1:2002 Radiated Electromagnetics Field Immunity Amplitude modulated 80% over the frequency range
80MHz to 2.5GHz at a level of 3 V/m
EN61000-4-4:1995+A1:2001+A2:2001 Electrical Fast Transient/Burst Immunity Test
+ 4kV
EN61000-4-5:1994+A1:2001 Surge Immunity Test Line to Neutral: + 2kV
Line to Ground: + 4kV
EN61000-4-6:1994+A1:2001 Conducted Radio-Frequency Immunity .150 MHz to 80 MHz, 10Vrms with an
amplitude modulated 1 kHz sine wave at 80%.
EN61000-4-8:1994+A1:2001 Power Frequency Magnetic Fields Immunity 40 A/m cont. 1000 A/m for 1 Sec Field @ 50Hz, X, Y, & Z-axis.
EN61000-4-29:2000 Voltage Dips and Interrupts DC Input Power
Ports
Voltage Dips: 30% drop for 20ms, 3 time
Voltage Dips: 60% drop for 1000ms, 3 time Short Interrupt: 100% drop for 100ms, 3 time
Short Interrupt: 100% drop for 1000ms, 3 time
EN61000-4-11:1994+A1:2001 Voltage Dips, Interruptions and Variations Voltage Dips: 30% drop for 20ms or 1 cycle, 3 time
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 41 Alcatel.Lucent-ESD
Calabasas/CA./USA
Voltage Dips: 60% drop for 1000ms or 50 cycle, 3 time
Short Interrupt: 100% drop for 100ms or 5 cycle, 3 time Short Interrupt: 100% drop for 1000ms or 50 cycle, 3 time
EN61000-4-12:2006 Ring Wave immunity Test (Damped
Oscillatory)
AC, Differntial Mode
Line to Neutral: + 2.0kV (0, 90, 270°) Line to Ground: + 4.0kV (0, 90, 270°)
EN61000-4-16:1998+A1:2004 Test for Immunity to conducted, common mode distrubances in the frequency range 0
Hz to 150 kHz
10 Vrms, 0.15 MHz to 80 MHz
EN61000-4-17:2002 Ripple on DC Power Supply Voltage Dips: 30% drop for 20ms, 3 time Voltage Dips: 60% drop for 1000ms, 3 time
Short Interrupt: 100% drop for 100ms, 3 time
Short Interrupt: 100% drop for 1000ms, 3 time
IEC 60255-5 Dielectric & HV Impluse
IEEE 1613, C37.90.3 Electrostatic Discharge Immunity Enclosure Contact: + 8 kV Enclosure Ports: + 15 kV
IEEE 1613, C37.90.2 Radiated RFI 35 V/m
IEEE 1613, C37.90.1 Fast Transcient Signal Ports: + 4kV @2.5KHz
D.C Power Ports: + 4kV A.C Power Ports: + 4kV
Earth Ground Ports: + 4kV
IEEE 1613, C37.90.1 Oscillatory Signal Ports: 2.5kV common mode @1 MHz
DC Power Ports: 2.5kV common, 1kV differential mode @ 1MHz AC Power Ports: 2.5kV common, 1kV differential mode @
1MHz
IEEE 1613, C37.90 H.V. Impulse Signal Ports: 5kV (Fail-Safe Relay output)
DC Power Ports: 5kV
AC Power Ports: 5kV
IEEE 1613, C37.90 Dielectric Strength Signal Ports: 2kVac DC Power Ports: 2kVac
AC Power Ports: 2kVac
Note: All test reports and certificate can be downloaed from the central repository accessible at:
https://agile.esd.alcatel-lucent.com/Agile/PLMServlet?module=CMBaseHandler&opcode=forwardToMainMenu
To search for documents, please:
1. Go to 'Global Searches'
2. Click on 'Compliance Searches'
3. Choose which Search/Product Line, then you can search for all or specific Compliance Documents
SSaaffeettyy aanndd EEnnvviirroonnmmeennttaall SSttaannddaarrddss
• ETS 300 019 Storage Class 1.1
• ETS 300 019 Transportation Class 2.3
• ETS 300 019 Stationary Use Class 3.1
OmniSwitch 6855 switches comply with Class-A standards for digital devices per the FCC Part 15, ICES-003, EN 55022,
CISPR 22, AS/NZS 3548, and VCCI standards. Modules with copper connectors meet Class-A requirements using
unshielded (UTP) cables.
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OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 42 Alcatel.Lucent-ESD
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Note: 1 inch = 2.54 centimeters & One Rack Unit = 1.75" & 1 kg = 2.2046 lbs & 1 watt ≈ 3.41214 BTU/hr.
Indicators /LEDs LED per port:
• 10/100/1000: PoE, link/activity • SFP: link/activity
• PoE ports; speed, link/activity/PoE applied
System LEDs: • Switch ID (indicates the stack ID of the unit in the stack: 1 to 7)
• System (OK) (chassis HW/SW status)
• PS1 (primary power supply status) • PS2 (backup power status)
OS6855-U24X Specific:
• 7 segment LED display on the front ( indicates the mode ( stacking or uplink) and stack number
Mounting OmniSwitch-6855 is rack mountable in 19″ (W) racks
Base/wall mounging is also offered
Physical Dimensions (W x D x H)
The OS6855 Series chassis are 1U
(One Rack Unit)
Chassis size without P/S or P/S shelf OS6855-24 , OS6855-U24 : 17.32 x 10.63 x 1.73in (44.0 x 27.0 x 4.4 cm)
OS6855-14 , OS6855-U10 : 8.5 x 10.25 x 1.73in ( 21.5 x 26 x 4.4)
OS6855-U24X: 17.25 x 10.87 x 1.73in ( 43.8 x 27.4 x 4.4 cm ) Total size including P/S shelf and mounting ears
OS6855-24 , OS6855-U24 : 19.00 x 17.56 x 1.73 in (48.2 x 44.6 x 4.4 cm)
OS6855-U24X: 19 x 17.60 x 1.73in ( 48.2 x 44.8 x 4.4 cm ) OS6855-14 , OS6855-U10 ( PS tray attached to the side): 19.00 x 10.25 x 1.73in
OS6855-14 , OS6855-U10 ( PS tray attached to the back): 8.5 x 17.5 x 1.73in
Weights Switch weight (no PS): OS6855-14: 5.28lb/2.42kg
OS6855-U10: 5.28lb/2.42kg
OS6855-24: 8.34lb/3.78kg OS6855-U24: 8.34lb/3.78kg
OS6855-U24X: 11.68 lb/5.3 kg
Switch weight (with one PS): OS6855-14: 7.78lb/3.55kg
OS6855-U10: 7.78lb/3.55kg
OS6855-24: 11.8lb/5.35kg OS6855-U24: 11.8lb/5.35kg
OS6855-U24X: 15.14 lb/6.87 kg
Power Consumption
The OmniSwitch 6855 Series
Power consumption without PoE :
The power consumption measurements were obtained from the AC input power using nominal input voltage of 120VAC and running full traffic on all ports. PoE is disabled.
Operational conditions for the test setup: Active State: Maximum ports per system, and with full LAN traffic operation.
Idle State: System is up and ready to work, but with no LAN traffic.
Product: Total Amount
of ports and speed
Power Consumption
Active State (Watt)
Power Consumption Idle State (Watt)
OS6855-U10 8+2 @ 1,000Mbs 25 24
OS6855-14 12+2 @ 1,000Mbs 30 29
OS6855-24 24 @ 1,000Mbs 46 44
OS6855-U24 24 @ 1,000Mbs 49 48
OS6855-U24X 24@1Gig - 2@10Gig 51 50
These are acutal measured numbers.
When power budget needs to be calculate it is advisable to add 10% buffer over the power consumtion
numbers above.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 43 Alcatel.Lucent-ESD
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Power consumption with PoE:
Operational Conditions for the test setup:
Active State: Typical Maximum Power (15.4W) per PoE Port, and maximum amount of ports utilized at 15.4W.
Idle State: PoE System has been turned on, but Power Device (PD) is set to 0.0 W.
OS6855-14 OS6855-24
Power Supply Model OS6855-PSS-P OS6855-PSL-P
Delivered Power at PoE Port (W) 15.4 15.4
AC Input Power Per Port (W) 17.5 19.5
Power Loss Per Port at System (W) 2.1 4.1
AC Input Power Idle State (W) 7 8
Amount of PoE Ports Tested at 15.4W
4 4
Total AC Power (W) 77 86
Total PoE Power Loss at System (W) 15.4 24.4
Total PoE Power Loss at System(%) 20 28.37
Product: Number of PoE
ports
System Power Consumption
with PoE Idle State (Watt)
System Power Consumption
with PoE Active State (Watt)
OS6855-14 4 @ 15.4W/ port 30W + 7W = 37 (30 + 7+ 4 x 2.1) = 45.4
OS6855-24 4 @ 15.4W/ port 46W + 8W = 54 (46 + 8 + 4 x 4.1) = 70.4
Heat Dissipation
The OmniSwitch 6855 Series
1-watt ≈ 3.41214 BTU/hr. Note: To calculate the heat dissipation for the PoE Models the following formula has been used: Heat Dissipation = Chassis Power Consumption as measured x 3.41214 BTU/hr.
Heat Dissipation WITHOUT POE :
OS6855-14: 30 watts x 3.41214 ≈ 102.4 BTU/hr
OS6855-U10: 25 watts x 3.41214 ≈ 85.3 BTU/hr
OS6855-24: 46 watts x 3.41214 ≈ 157 BTU/hr
OS6855-U24: 49 watts x 3.41214 ≈ 167.2 BTU/hr
OS6855-U24X: 51 watts x 3.41214 ≈ 174 BTU/hr
Heat Dissipation WITH POE :
The reason that the PoE power budget has not been fully taken into account here, is that the heat is dissipated on the PoE devices and not on the OmniSwitch 6855 chassis. Therefore, we only account for
the heat dissipated on the OmniSwitch 6855 chassis plus the heat dissipated on the PoE daughter card
inside the chassis including the power loss per port at the system.
OS6855-14: 45.4 watts x 3.41214 ≈ 154.9 BTU/hr.
OS6855-24: 70.4 watts x 3.41214 ≈ 240.2 BTU/hr.
Power plug type North America: NEMA 5-15-P (US), C22.2, No. 42 (Canada) United Kingdom / Ireland: BS 1,363, Europe: CEE 7/7
Japan: JIS 8,303, Australia: AS 3,112, India: BS 546, Italy: CIE 2,316
Switzerland / Liechtenstein: SEV 1011 Denmark / Greenland: SRAF 1,962 / D816 / 87, Argentina: AR1-10P
Electrical Requirements OmniSwitch 6855 switches have the following general electrical requirements:
• Each switch requires one grounded electrical outlet for each power supply installed in the.
OmniSwitch 6855 switches offer both AC and DC power supply support.
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 44 Alcatel.Lucent-ESD
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Refer to the Hardware Users Guide for more information.
• For switches using AC power connections, each supplied AC power cord is 2 meters (approximately 6. 5 feet) long. Do not use extension cords.
Redundant AC Power: If possible, it is recommended that each AC outlet reside on a separate circuit.
With redundant AC, if a single circuit fails, the switch’s remaining power supplies (on separate circuits) will likely be unaffected and can therefore continue operating.
• For switches using DC power, the user must assemble the DC power cord. Refer to the Hardware
Users Guide for more information.
Name Plates A nameplate in the front of the chassis will identify the product model name & number and the vendor (in this case Alcatel-Lucent).
A nameplate in the back will clearly identify the following:
• Model #, Assembly # with BAR CODE, and FCC statements
• Electric Ratings and U.S. Patent information along with their respective symbols.
Metro Ethernet Forum (MEF) 9 and 14 certification OS6855 models are MEF certified
1. MEF 9 for equipment vendors – Ethernet services at the user network interface (UNI)
2. MEF 14 for equipment vendors – focused on traffic management, service performance, and quality of service (QoS)
Reliability Tests The OmniSwitch 6855 Series has been rigorously tested for:
• Temperature
• Humidity
• Vibrations
• Acoustic Noise
• Altitude
• Drop
• Shock
• Bench Handling
Please contact Alcatel-Lucent Internetworking Product Marketing and/or other Alcatel-Lucent authorized representatives to obtain further data and/or a full test report.
Compliancy 1) Restriction on Hazardous Substances in Electrical and Electronic Equipment (RoHS)
OS6855 family is RoHS 6/6 compliant 2) WEEE (Waste Electrical and Electronic Equipment)
3) NEBS Level 3 Certified *-Contact for availability
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 45 Alcatel.Lucent-ESD
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RoHS Requirements It is Alcatel-Lucent's position to be in compliance with the European R.O.H.S Directive 2002/95/EC by the end of 2005. In doing so, all component selection decisions shall be influenced by offerings that
are a) ROHS compliant today or b) have planned date of cutover to ROHS compliance without
impacting the design (i.e. causing a redesign). It is Alcatel-Lucent's intention to choose environmentally friendly component finishes that are today solder-able with SN63/Pb37 solders (through late 2005), but can move to SnAgCu chemistries in Jan2006.
Compliance with Environmental procedure 020499-00, primarily focused on Restriction of Hazardous Substances (ROHS Directive 2002/95/EC) and Waste Electrical and Electronic Equipment (WEEE
Directive 2002/96/EC).
Thus, all assemblies built after Dec. 31, 2005 shall be compliant with hazardous materials requirements as defined in 020499-00. Upon request, documentation shall be provided certifying
compliance.
RoHS
Restriction on Hazardous Substances
First Green switch in the Market – RoHS compliancy
With the OmniSwitch 6855 family, Alcatel-Lucent will be the first switch manufacturer to be in compliance with the new European Community’s directive – Restriction on Hazardous Substances in
Electrical and Electronics Equipment (RoHS) – which requires electric equipment to be free of six
hazardous substances by July 2006. Although, only required for European Union countries, the rest of the World will benefit from these “green” switches by lessening the amount of hazardous substances
that find its way into the environment.
EU Council Decision 87/95/EEC Compliance with regulation given in: http://europa.eu.int/ISPO/infosoc/legreg/docs/8795eec.html
WEEE The product at end of life is subject to separate collection and treatment in the EU Member States,
Norway and Switzerland. Treatment applied at end of life of the product in these countries shall
comply with the applicable national laws implementing directive 2002/96EC on waste electrical and electronic equipment (WEEE).
Electrical Compliance The Electrical Compliance requirements are met through the EMC Compliance Standards and the
Safety Compliance Standards as indicated above.
Electrostatic Discharge (ESD) The chassis has been thoroughly tested to withstand ESD test voltage conditions at any point on the
enclosure using the test setups and conditions in accordance with IEC 61000-4-2 (EN61000-4-2).
ISO-9001:2000 DNV Certification The OmniSwitch 6855 is compliant with the ISO-9001: 2000 DNV
Capability Maturity Model (CMM) Alcatel-Lucent's Software Engineering Institute (SEI) Capability Maturity Model (CMM) rating for
software processes meets the Level-2 (CMM-level-2) requirements.
Mean Time Between Failure (MTBF) Standard All AOS OmniSwitches support a commercial equivalent of MIL-HDBK-217F-2:
MTBF Predictions are based on Telcordia (Bellcore Handbook Technical Reference) SR-332, Issue 1.
Quality Assurance and Customer Satisfaction It is the policy of Alcatel-Lucent USA to satisfy the Quality expectations of our customers – both internal and external. Total Quality performance means understanding who the customer is, what the
customer expectations are, and meeting those expectations without error, on time, every time. Total
Quality is doing the right things right today and better tomorrow. As part of Alcatel’s overall Quality Assurance process Alcatel’s Cross-functional team continuously evaluates Cost, Time to Market, Communication, Customer satisfaction and Process improvements. Necessary and appropriate actions are subsequently taken as required.
Alcatel-Lucent's Enterprise Solutions Division adheres to the ISO 9001 certification program. It
measures Customer Satisfaction and Key Process Indicators that are reviewed on regular intervals with the Executive Management Team.
Service & Support Default Warranty One year on Hardware, and 90-days on Software. Additional, optional support is available. Contact
your local Alcatel-Lucent representative for more information.
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Limited Lifetime Warranty All versions of the Omni Stackable family come with a Limited Lifetime Hardware Warranty, limited
to the original owner, and will be provided for up to five (5) years. Faulty parts will be replaced via a five (5) business days AVR (Advance Replacement) RMA.
Limited Lifetime Warranty does not apply to transceivers.
Warranty
Service & Support Programs & End Of Life
Lifetime Support
Standard Warranty Support
All Alcatel-Lucent's products come with a standard one-year warranty on hardware and a three-month warranty on software.
Hardware DOA Warranty
If hardware fails within the first 30 days after delivery, call Alcatel-Lucent's Internetworking Division Customer Service by 2:00 p.m. (Pacific Standard Time) and they will send a replacement part
overnight.
One-year Hardware Warranty After the first 30 days, call Alcatel-Lucent's Internetworking Division Customer Service for a Return
material Authorization (RMA) and ship the part back to them for factory repair. The repaired unit will be shipped back to you from our facility within 10 business days. Next day, advanced replacement is
available for a small expedited fee.
All-in-One Maintenance: All maintenance fix releases will be provided free of charge during the first 90 days.
Service & Support Programs & End Of Life (EOL)
In accordance with Alcatel-Lucent’s established Product Life Cycle policy, as well as its customer satisfaction policy, Alcatel-Lucent will honor its obligations to customers currently under warranty or
with valid purchased service agreements relating to a product line for five (5) years (Software: three
(3) years and Hardware: five (5) years) beyond the EOL (End Of Life) of a product line.
Lifetime Support
All versions of the stackaable product families come with a Limited Lifetime Hardware Warranty,
limited to the original owner, and will be provided for up to five (5) years. Faulty parts will be replaced via a five (5) business days AVR (Advance Replacement) RMA.
Limited Lifetime Warranty does not apply to SFPs.
Hardware Warranty Hardware – Alcatel.Lucent warrants that, for the applicable warranty period of one (1) year for
hardware (a) Equipment shall, under normal use and service, be free from defects in material and workmanship, and (b) Equipment shall materially conform to Alcatel.Lucent’s specification therefore
in effect on the date of shipment. The warranty period applicable to any product shall be one (1) year
from the date of shipment except if Alcatel.Lucent performs installation Services for any Product, then the warranty period applicable to the product shall be one (1) year from the date Purchaser is deemed
to have accepted the Product in accordance with the Agreement. Hardware warranty only includes
Standard Repair or Replacement of Defective Parts (Standard R&R) support.
Lifetime Support
All versions of the stackable product families come with a Limited Lifetime Hardware Warranty,
limited to the original owner, and will be provided for up to five (5) years. Faulty parts will be replaced via a five (5) business days AVR (Advance Replacement) RMA.
Limited Lifetime Warranty does not apply to SFPs.
Software Warranty Software & Firmware – Alcatel.Lucent warrants that, for the applicable warranty period of ninety (90) days for software, (a) Software media shall, under normal use and service, be free from defects in
material and workmanship, and (b) Software shall materially conform to Alcatel.Lucent’s specification therefore in effect on the date of shipment. However, Alcatel.Lucent makes no warranty that any software will operate uninterrupted or error free. Software warranty includes software bug fixes and
patches. Software upgrades and/or enhancements are not included as a part of Alcatel.Lucent’s
warranty, but can be purchased separately.
Life Span The Alcatel.Lucent Product Life Span depends on many conditions in the market place and varies from platform to platform. Historically speaking, some platforms have been out in the market more than
seven (7) years and still continue to exist on our product portfolio, while others may have experienced
shorter life spans.
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Contracted S&S Programs: Standard extended warranty offerings including
technical and maintenance support
Alcatel.Lucent provides a full suite of maintenance offerings including Technical Assistance Center 24 x 7 x 365, Standard Repair or Replacement of Defective Units, Advanced Repair or Replacement, and
Emergency Call Out to dispatch a qualified Field Engineer to provide on-site support. An overview is
provided below that provides information regarding support options available.
Contracted Program: SupportBasic SupportBasic: One year 7x24 phone. Includes e-service Web access, software releases, repair and return of hardware to be completed in 10 business days from receipt.
Contracted Program: SupportPlus SupportPlus: One year - 7x24 phone. Includes e-service Web access, software releases and advanced
shipment for next business day arrival of replacement hardware.
Contracted Program: SupportTotal
(available only in N. America)
SupportTotal: One year - 7x24 phone. Includes eService Web access, software releases, and same day
4-hour on site hardware replacement (labor and parts) 7 days a week, 24 hours a day. Excludes NMS and Authentication Services software.
Hardware Architecture
MAC Address Table (L2 Unicast MAC addresses) Up to 16 K (16,384) MAC Addresses is supported per system.
Learned Port Security – What is the maximum number of MAC addresses a
port can learn?
For the OmniSwitch 6855 family, the learned port security feature of the Alcatel-Lucent Operating System allows up to 100 MAC addresses per port to be learned and acted upon, with up to 8,192 per
switch. The maximum number of MAC addresses the switch can learn for Layer 2 forwarding is
16,384 simultaneous MAC addresses.
IP Address Table Routes (RIB) 48K routing table
L3 IPv4 Host Entries (FIB) 8K
L3 IPv4 LPM Routes (FIB) 12K
L3 IPv6 Host Entries (FIB) 4K
L3 IPv6 LPM Routes (FIB) 6K
Hardware Tunnels/Trunks 128
Flows/ACLs 2K
Meters 2K
Counters 2K
Packet Buffer Size per system 2MB of buffering available per system Each port type regardless of port speed is assigned a minimum and a maximum threshold buffer space.
Buffering is supported per port and there is a shared pool of up to 2MB available per system that is
based on an optimization algorithm that monitors buffer allocation per port. The buffering algorithm could be optimized to allocate the unused buffering space for the inactive ports to the active ports. In
other words, inactive ports buffer space can be used by those ports that are active and require more buffering space if need be. * 2,097,152 bytes of buffering available per system.
* Two buffer allocation thresholds: LwmCosSetLimit and DynCellLimit. There is one of each type of threshold per queue. Each queue is defined by a {port, COS} combination. There are 8 COS in our
system, the highest COS is reserved for internal traffic while the user can assign the other 7.
* LwmCosSetLimit is the Low Water Mark for buffer allocation per queue. Beyond this mark a queue
will tap into a dynamically shared buffer pool.
* DynCellLimit is the stop threshold for a queue to acquire more buffer from the pool.
Both of the above thresholds have been pre-determined and calculated for optimal performance under our benchmark. The default will automatically tap into shared buffer resources whenever the situation
demands it. If the users wish to customize the buffer sizes, we are usually able to accommodate the
request by analyzing their traffic pattern.
10-Gigabit Ethernet Interface N/A
Connectors SFP, and RJ45 connectors
Stacking • Not supported
Console Port RS-232 Console Port (RJ-45 connector).
The console-protecting chip SEMTEC LCDA15C-6 is used along with the RJ45 connector.
Combo Ports OS6855-24: four Gigabit Ethernet SFP combo ports
OS6855-U24: two Gigabit Ethernet SFP combo ports OS6855-14 and –U10: No combo ports
10GigE Uplinks N/A
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POE /(Power over Ethernet) In-line Power Support POE with full compliance of IEEE 802.3af
Temperature Sensor Temperature Sensor National Semi-Conductor LM77 is supported
Thermal detection & Shutdown Thermal detection and shutdown is supported.
Clock Real Time Clock
Power Supply • Main and backup power supplies are external either directly connected to the rear of the unit or remotely mounted.
• Supports redundant dual hot swappable power supplies
Fans 6855-14 and 6855-U10 are fanless
OS6855-24 and U24 fans are off by default and turn on only at increased temperature
LEDS Per port Link/Activity/PoE monitoring LED support System Power, BPS, and Diagnostic LED support
Hardware Device Level features supported
The OmniSwitch 6855 Series platforms are 1U
(Rack Unit) high
Supported.
19" Rack-Mountable Supported.
Dynamic and automatic module ID selection Supported
All models conform to Alcatel-Lucent coloring and
labeling scheme
Supported
Switch Façade for Alcatel-Lucent label Supported
Grounding lugs Supported
Mounting holes on the side, near the front and back of the chassis
Supported
RS-232 connector for console connection on the front
pane
Supported
USB port on the front panel
(Version 2.0 full speed min.)
Supported (Future Release)
7 segment LED stack# display on the front panel N/A
Port LED Supported
Standard OK1 & OK2 LEDs Supported
Port Numbering scheme with first port in the upper
left hand corner
Supported
Power Supply Failure LED Supported
Temperature Threshold Exceeded LED Supported
FAN failure LED Supported
Primary unit LED (designate the master unit in a stack
configuration)
N/A
Secondary unit LED (designate the master unit in a
stack configuration)
N/A
LED for BPS status Supported
AC and DC power supplies Supported
AC Power Supply: power source 115-200 V AC, 50-60 Hz
Supported
DC power supply: 36 – 72 V DC (input) Supported
Single main power supply to provide power for
chassis and POE
Supported
POE back up power Supported
POE interface compatible with PowerDsine Ron chip Supported
Power supplies are able to attach to the rear of the unit Supported
Insertion or removal of redundant power supply Insertion or removal of redundant power supply does not cause any power or service disruption to the
switch
Remote mounting of both primary and backup power supplies
Supported
Single BPS for chassis and POE Supported on 6855-24
Circuit breaker protected OS6855 units Supported
Redundant Fans support 1:N redundancy for 24 port models 6855-14 and 6855-U10 are fanless
Noise level All OmniSwitch 6855 platforms are noiseless at 25C
Operating Temperature -40C to +70 C for OS6855-14 and OS6855-U10
-40C to +75 C for OS6855-24 and OS6855-U24
Storage Temperature -40C to +85C
Operating Humidity 5% to 95% (non-condensing)
Storage Humidity 5% to 95% (non-condensing)
Loop protection against loop back Supported
UDLD Supported
Support Cat 5, 5e, 6, and 6e Supported
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Capability to disable transmit function (or reset) of
each PHY individually
Supported
Data Plane IEEE 802.3z & 802.3ab & 802.3u & 802.3 Supported
Auto-Detect on both Copper and Fiber Supported
Simultaneous detection configuration priority Supported
Media failure failover capability Supported
802.3af on POE Models Supported: Power over Ethernet – is supported on 10/100/1000BASE-T ports only
Hot Swappable Optical transceivers are hot swappable
Auto-negotiation/Auto sensing 10/100/1000 Supported
Auto-Detect the insertion and removal of the SFP Supported
UNH (or equivalent) operation standards Supported
Ethernet Specifications Connectors/ Cabling • Management: 1 RJ-45 console interface configured as DCE/DTE for operation, diagnostics, status,
and configuration information. Ship kit includes RJ-45 to DB-9 connector adaptor • AC power connector
Connector type 10/1000/1000BASE-T copper ports: RJ-45
10/100/1000BASE-T copper ports with PoE: RJ-45
SFP ports: LC or SC with Removable/Pluggable transceiver – SFP-MSA
Connections supported 10BASE-T hub or device; 100BASE-TX hub or device; 1000BASE-T hub or device
1000BASE-X hub or device
Cable supported 10BASE-T: unshielded twisted-pair (UTP)
100BASE-TX: unshielded twisted-pair (UTP), Category 5, EIA/TIA 568 or shielded twisted-pair (STP), Category 5, 100 ohm
1000BASE-T: unshielded twisted-pair (UTP), Category 5, EIA/TIA 568 or shielded twisted-pair
(STP), Category 5, 100 ohm Note: Category 6 cabling is also supported on the 10/100/1000BASE-T connections.
IEEE Standards Supported 802.3 Carrier Sense Multiple Access with Collision Detection (CSMA/CD)
Data rates • 10/100/1000Mbps triple speed
o 10Mbps o 100Mbps
o 1000Mbps (Gigabit Ethernet)
• Gigabit Ethernet
Ports Supported • Triple Speed ports is supported and includes:
o Ethernet (10 Mbps) o Fast Ethernet (100 Mbps)
o 1000Mbps Ethernet (Gigabit Ethernet)
• Gigabit Ethernet
Switching/Routing Support Layer 2 Switching/Layer 3 Routing
Backbone Support 10/100/1000Mbps, Gigabit Ethernet ports
Port Mirroring Support 10/100/1000Mbps, Gigabit Ethernet ports
802.1Q Hardware Tagging 10/100/1000Mbps, Gigabit Ethernet ports
Maximum Transfer Unit -- MTU MTU parameter for Routers is not configurable.
The ASIC does not include the notion of an MTU that applies to an IP interface. Instead, it uses the physical long-frame-size of the egress port as the MTU. When the ASIC attempts to forward a packet,
it tests the size of the packet against the physical long-frame-size of the egress port, if the packet is too
large, it forwards the packet to the CPU for fragmentation (or ICMP processing in the case of a packet with Don't Fragment set).
• 10/100 ports are set with a long-frame-size of 1553 bytes.
• GigE/10GigE ports are set with a long-frame-size of 9216 bytes (jumbo frames). Packets larger than the long-frame-size are dropped at ingress. The above (& default) values are the
maximum configurable values.
Packets that are forwarded from a 10/100 to a 10/100 port cannot ever be reported as too big via ICMP because anything larger than 1553 would not be accepted.
The same holds true for packets forwarded between two GigE/10GigE ports and from a 10/100 port to
a GigE/10GigE. Layer-2 Ethernet Frame Size:
Untagged: 1,518 Bytes without IEEE 802.1Q tags
Tagged: 1,522 Bytes with IEEE 802.1Q tags Long Frame Size (enabled by default): 1553 Bytes (IEEE 8021.Q tagged or untagged)
Frame Type: Type2, LLC, SNAP, RAW 802.3 The maximum frame size on the Gigabit Ethernet interfaces range from 1,518 to 9,216 Bytes Jumbo frames up to 9K Bytes (9,216 Bytes) are supported on GigE/10GigE interfaces.
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Untagged (without IEEE 802.1Q tags) Ethernet Packets: 1,518 Bytes
Tagged (with IEEE 802.1Q tags) Ethernet Packets: 1,522 Bytes
Inter-Frame Gap 12 Bytes (by default) Inter-frame gap is a measure of the minimum idle time between the end of one frame transmission and
the beginning of another. By default, the inter-frame gap is 12 bytes. Through the use of this feature,
the inter-frame gap value (in bytes) on a specific port, a range of ports, or all ports on a switch (slot) can be configured. Values for this command range from 9 to 12 bytes. Note. This command is only valid on Gigabit ports.
Interface Alias (Port Alias) Supported (none configured by default): Through the use of this feature an alias (i.e., description) for a single port can be configured. (You cannot configure an entire switch or a range of ports.) The text
description can be up to 40 characters long.
Peak Flood Rate Configuration By default:
42Mbps (Fast Ethernet) 496Mbps (Gigabit Ethernet)
997Mbps (10-Gigabit Ethernet)
By default, the flood rate is 42 Mbps on 10/100/1000 ports and 496 Mbps on Gigabit ports. Through the use of this feature, the peak ingress flood rate value on a specific port, a range of ports, or all ports
on a switch (slot) in megabits per second can be configured.
Note. The user can configure a flood rate equal to the line rate, but it is not recommended. Alcatel-Lucent recommends that you always configure the flood rate to be less than the line speed.
Flow Control IEEE 802.3x flow control.
Trap Port Link Messages Supported (disabled by default)
This feature can be enabled or disabled (the default) on a specific port, a range of ports, or all ports on a switch (slot). When enabled, a trap message will be displayed on a Network Management Station
(NMS) whenever the port state has changed.
Per port rate limiting
Per-port L2/L3 multicast & broadcast flood limit is supported.
Per-port multicast / broadcast / flood limit is supported. The ASIC provides a per port configuration on
the incoming and/or outgoing port basis that allows broadcast and/or multicast storm control. The CPU can program a threshold value per port that indicates the number of broadcast and/or multicast
packets/bytes that are allowed in a given time interval.
Re-settable Statistics Counters Supported
Duplex Mode support The duplex mode feature is supported on a specific port, a range of ports, or all ports on a switch (slot). It can be set to full (full duplex mode, which is the default on fiber ports), half (half duplex mode), and
auto (auto-negotiation, which is the default on copper ports). The Auto option causes the switch to
advertise all available duplex modes (half/full/both) for the port during auto-negotiation. In full duplex mode, the interface transmits and receives data simultaneously. In half duplex mode, the interface can
only transmit or receive data at a given time.
Auto-negotiation Auto-negotiation is supported (enabled by default). It can be enabled or disabled on a single port, a
range of ports, or an entire slot.
Crossover Crossover can be configured on a single port, a range of ports, or an entire slot. If auto negotiation is disabled, auto MDIX, flow control, auto speed, and auto duplex are not accepted. Setting the crossover configuration to auto will configure the interface or interfaces to automatically
detect crossover settings. Setting crossover configuration to mdix will configure the interface or inter-faces for MDIX (Media Dependent Interface with Crossover), which is the standard for hubs and
switches. Setting crossover to mdi will configure the interface or interfaces for MDI (Media
Dependent Interface), which is the standard for end stations. And setting the crossover configuration to disable will disable crossover configuration on an interface or interfaces.
Verifying Ethernet Port Configurations To display information about Ethernet port configuration settings, use the show commands. These
commands can be quite useful in troubleshooting and resolving potential configuration issues or problems on your switch. For more information about the resulting displays from these commands, see
the OmniSwitch CLI Reference Guide.
Diagnostics • Off-line Diagnostics for manufacturing
• Not to require external PCs or test equipment for running diagnostics
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 51 Alcatel.Lucent-ESD
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PPPeeerrrfffooorrrmmmaaannnccceee
Raw Fabric Capacity
All of the models in 6855 family use 24 port packet processor .
The raw fabric capacity for all is : 2244GGbbppss FFuullll DDuupplleexx oorr 4488GGbbppss aaggggrreeggaattee
Switching Capacity
• OS6855-U10/-U10D: 1100 GGbbppss FFuullll DDuupplleexx oorr 2200 GGbbppss aaggggrreeggaattee
• OS6855-14/-14D: 1144 GGbbppss FFuullll DDuupplleexx oorr 2288 GGbbppss aaggggrreeggaattee
• OS6855-24/-24D/-24DL: 2244GGbbppss FFuullll DDuupplleexx oorr 4488GGbbppss aaggggrreeggaattee
• OS6855-U24/-U24D/-U24DL: 2244GGbbppss FFuullll DDuupplleexx oorr 4488GGbbppss aaggggrreeggaattee
• OS6855-U24X/-U24XD/-U24XDL: 4488GGbbppss FFuullll DDuupplleexx oorr 9966GGbbppss aaggggrreeggaattee
Throughput Performance
Or Forwarding Rate Per Stand-Alone Switch
@64Byte Packets
TThheeoorreettiiccaall packet per second (pps) rates for Ethernet packets is normally calculated by adding 20
bytes to each packet size to account for the 0.096 microseconds inter frame gap (equivalent to 12 bytes) and the preamble (eight bytes). Thus, the theoretical 10 Mbps, 100 Mbps, Gigabit and 10-
Gigabit Ethernet packet rate in packets per second (pps) for a packet of “X” bytes is defined by the
following formulas. Throughput calculations assume 64 byte packets and the throughput rate is calculated “per-port”.
(10 Gbps) / ((8 bits/ byte) * (X+20)) = 14,880,952.3 pps
(1 Gbps) / ((8 bits/ byte) * (X+20)) = 1,488,095.23 pps (100 Mbps) / ((8 bits/ byte) * (X+20)) = 148,809.52 pps
(10 Mbps) / ((8 bits/ byte) * (X+20)) = 14,880.95 pps
Since the primary benefit of any switch is speed, the most appropriate performance metric is
throughput, which is typically expressed in millions of packets per second (Mpps). Throughput
measures the number of packets per second (measured in millions) that a switch can process for outbound (egress direction only) transmission to another device.
Throughput (at Layer-2 or Layer-3) = wire-speed Eth. ports * throughput rate per port
NNoottee:: TThhee ffoolllloowwiinngg aassssuummeess tthhaatt aallll ttrraaffffiicc iiss ffoorrwwaarrddeedd tthhrroouugghh tthhee MMaaiinn SSwwiittcchh FFaabbrriicc AASSIICC..
TThhee 22--ppoorrtt 1100--GGiiggaabbiitt EEtthh uupplliinnkk//ssttaacckkiinngg ssuuppppoorrttss 22 xx 1100--GGiiggaabbiitt EEtthh ppoorrttss aatt wwiirree--ssppeeeedd::
22 ** 1144,,888800,,995522..33 ppppss == 2299,,776611,,990044..66ppppss ((aapppprrooxx:: 2299..88MMppppss))
TThhee 1100 GGiiggaabbiitt EEtthh ppoorrttss tthhrroouugghhppuutt aatt wwiirree--ssppeeeeddss::
1100 ** 11,,448888,,009955..2233 ppppss == 1144,,888800,,995522..33ppppss ((aapppprrooxx:: 1144..99MMppppss))
TThhee 1144 GGiiggaabbiitt EEtthh ppoorrttss tthhrroouugghhppuutt aatt wwiirree--ssppeeeeddss::
1144 ** 11,,448888,,009955..2233 ppppss == 2200,,883333,,333333..2222ppppss ((aapppprrooxx:: 2200..88MMppppss))
TThhee 2244 GGiiggaabbiitt EEtthh ppoorrttss tthhrroouugghhppuutt aatt wwiirree--ssppeeeeddss::
2244 ** 11,,448888,,009955..2233 ppppss == 3355,,771144,,228855..5522ppppss ((aapppprrooxx:: 3355..77MMppppss))
TThhee OOSS66885555--UU1100//--UU1100DD ssuuppppoorrttss uupp ttoo 1100 GGEE ppoorrttss aatt wwiirree--ssppeeeeddss:: 1144..99MMppppss
TThhee OOSS66885555--1144//--1144DD ssuuppppoorrttss uupp ttoo 1144 GGEE ppoorrttss aatt wwiirree--ssppeeeedd:: 2200..88MMppppss
TThhee OOSS66885555--2244//--2244DD//--2244DDLL ssuuppppoorrttss uupp ttoo 2244 GGEE ppoorrttss aatt wwiirree--ssppeeeeddss:: 3355..77MMppppss
TThhee OOSS66885555--UU2244//--UU2244DD//--UU2244DDLL ssuuppppoorrttss uupp ttoo 2244 GGEE ppoorrttss aatt wwiirree--ssppeeeeddss:: 3355..77MMppppss
TThhee OOSS66885555--UU2244XX//--UU2244XXDD//--UU2244XXDDLL ssuuppppoorrttss uupp ttoo 2244 GGEE ppoorrttss ++ 22 1100GG:: 6655..55MMppppss
Throughput Performance Or Forwarding Rate
Per Stand-Alone Switch
@1518Byte Packets
TThheeoorreettiiccaall packet per second (pps) rates for Ethernet packets is normally calculated by adding 20 bytes to each packet size to account for the 0.096 microseconds inter frame gap (equivalent to 12
bytes) and the preamble (eight bytes). Thus, the theoretical 10 Mbps, 100 Mbps, Gigabit and 10-
Gigabit Ethernet packet rate in packets per second (pps) for a packet of “X” bytes is defined by the following formulas.
Throughput calculations assume 1518 byte packets and the throughput rate is calculated “per-port”.
(10Gbps) / ((8 bits/ byte) * (X+20)) = 812,743.82 pps (1Gbps) / ((8 bits/ byte) * (X+20)) = 81,274.38 pps
(100 Mbps) / ((8 bits/ byte) * (X+20)) = 8,127.43 pps (10 Mbps) / ((8 bits/ byte) * (X+20)) = 812.74 pps Since the primary benefit of any switch is speed, the most appropriate performance metric is
throughput, which is typically expressed in millions of packets per second (Mpps). Throughput
measures the number of packets per second (measured in millions) that a switch can process for outbound (egress direction only) transmission to another device.
Throughput (at Layer-2 or Layer-3) = wire-speed Eth. ports * throughput rate per port
NNoottee:: TThhee ffoolllloowwiinngg aassssuummeess tthhaatt aallll ttrraaffffiicc iiss ffoorrwwaarrddeedd tthhrroouugghh tthhee MMaaiinn SSwwiittcchh FFaabbrriicc AASSIICC..
1100 ** 8811,,227744..3388 ppppss ss == 881122,,774433..88 ppppss ((aapppprrooxx:: 881122..77KKppppss))
TThhee 1144 GGiiggaabbiitt EEtthh ppoorrttss tthhrroouugghhppuutt aatt wwiirree--ssppeeeeddss::
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 52 Alcatel.Lucent-ESD
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1144 ** 8811,,227744..3388 ppppss ==11,,113377,,884411..3322 ppppss ((aapppprrooxx:: 11..1144MMppppss))
TThhee 2244 GGiiggaabbiitt EEtthh ppoorrttss tthhrroouugghhppuutt aatt wwiirree--ssppeeeeddss::
2244 ** 8811,,227744..3388 ppppss == 11,,995500,,558855..1122ppppss ((aapppprrooxx:: 11..9955MMppppss))
TThhee OOSS66885555--UU1100//--UU1100DD ssuuppppoorrttss uupp ttoo 1100 GGiiggEE.. EEtthh ppoorrttss aatt wwiirree--ssppeeeeddss:: :: 881122..77KKppppss
TThhee OOSS66885555--1144//--1144DD ssuuppppoorrttss uupp ttoo 1144 GGiiggEE EEtthh ppoorrttss aatt wwiirree--ssppeeeedd:: 11..1144MMppppss
TThhee OOSS66885555--2244//--2244DD//--2244DDLL ssuuppppoorrttss uupp ttoo 2244 GGiiggEE EEtthh ppoorrttss aatt wwiirree--ssppeeeeddss:: 11..9955MMppppss
TThhee OOSS66885555--UU2244//--UU2244DD//--UU2244DDLL ssuuppppoorrttss uupp ttoo 2244 GGiiggEE EEtthh ppoorrttss aatt wwiirree--ssppeeeeddss:: 11..9955MMppppss
Layer-2 & Layer-3 Forwarding Rate
Per port
Wire-speed on 10Mbps port→ 14,880 pps with 64 Byte packets
Wire-speed on 100Mbps port→ 148,809 pps with 64 Byte packets
Wire-speed on Gigabit Ethernet port→ 1,488,095 pps with 64 Byte packets
Latency Notes for latency:
• Latency test results generated by IXIA Device Version 3.65.284
• RFC 2544 Latency Test
• Latency Measurement Type: First bit In to First bit Out ----- FIFO
• Protocol: the Layer-2 & Layer-3
• Frame Rate: 100%
The OmniSwitch 6855 Layer-2 & Layer-3 Latencies / Throughput Port Speed:
Gigabit
64 Byte Packets 1518 Byte Packets
Latency Estimated around 4.5µs Estimated around 16µs
Throughput Wire-speed:
1000Mbps Full Duplex Port: 1,488,096pps
Wire-speed:
1000Mbps Full Duplex Port: 81,275pps
Port Speed:
100Mbps
64 Byte Packets 1518 Byte Packets
Latency Estimated around 68.4µs Estimated around 184.6µs
Throughput Wire-speed:
100Mbps Full Duplex Port: 148,810pps
Wire-speed:
100Mbps Full Duplex Port: 8,128pps
Port Speed:
10Mbps
64 Byte Packets 1518 Byte Packets
Latency Estimated around TBD µs Estimated around TBD µs
Throughput Wire-speed:
10Mbps Full Duplex Port: 14,881pps
Wire-speed:
10Mbps Full Duplex Port: 813pps
SSyysstteemm Boot time Cold boot time in a stand-alone configuration when the switch can join the network and start passing
traffic: approximately 115 sec. Warm re-boot time in a stand-alone configuration when the switch can join the network and start
passing traffic: approximately 115 sec.
Image download time Approximately 65 sec
System Resiliency Verification Alcatel-Lucent OmniSwitch 6855 switches are designed in such a way that is highly reliable under
extreme stress conditions. The OmniSwitch 6855 switches are rigorously tested to ensure that the system is able to sustain heavy loads and allow for continued availability of all system resources.
The typical test setups involve:
• Running in normal operational mode where system is running under the specified CPU
threshold values.
• Running above the CPU threshold values all the time.
Interfaces Power over Ethernet • IEEE 802.3af (supported on all POE type chassis)
Stacking ports •N/A
Combo ports OS6855-24: 4 x Combo ports which can be individually configured to be be 10/100/1000BaseT or
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1000BaseX and that can support SFP transceivers.
OS6855-U24: 2 x Combo ports which can be individually configured to be 10/100/1000BaseT or 1000BaseX and that can support SFP transceivers.
OS6855-14 and OS6855-U10 do not have combo ports
10GigE uplinks • N/A
Ethernet minimum size packet 64 Bytes
Ethernet IP packet maximum transmission _ MTU 1000Mbps (GigE) and 10,000Mbps (10GigE); 9,216 Bytes (Jumbo frames) 10/100Mbps Eth IP packet max transmission unit; 1553 Bytes
Flood Control You can rate limit the flooding traffic. Flood control is done on ingress and the rate is shared for all
interfaces on that switch.
By default flood control only applies for flooding with broadcast (ff:ff:ff:ff:ff:ff) and unknown destination Mac address. You can enable flood control for multicast Mac as well.
Default settings:
• Flood multicast disable
• Flood rate set to 997 Mbps on 10Gig port
• Flood rate set to 496 Mbps on 1G port
• Flood rate set to 49Mbps on 100M ports
• Flood rate set to 4Mbps on 10M ports
Note: The above rates are met with packet size of 512 bytes. Different packet size will give different flood
rate.
The theoretical flood rate (the maximum TX rate at a given packet size you can send before you reach the flood control rate limiting) is obtained with:
Theoretical Flood Rate = Interface Flood Rate * (Packet Size + 20) / 512
Flood rate limiting does not give a steady rate at the theoretical flood rate. It gives a sporadic/bursty profile where the average rate is the theoretical flood rate.
Layer-2/Layer-3 Switching Root bridge priority / path cost: • Default spanning tree mode is RSTP (IEEE 802.1w)
• The bridge priority can be any value between 0 and 65535 for STP and RSTP protocol in the 16-bit mode. By default spanning tree follows the 16-bit path cost.
• The bridge priority can only be in multiples of 4096 in the 32-bit mode or in MSTP mode.
• MSTP can only operate in 32-bit mode.
Group mobility Rules supported: • Port
• MAC
• MAC range
• Mobile-Tag
• Protocol
• IP
• IPX
• DHCP port
• DHCP MAC
• DHCP MAC Range
• DHCP Generic
Binding rules supported
• Port-Protocol Binding rule
• MAC-Port Binding rule
• MAC-IP-Port Binding rule
Rule Precedence: • Mobile Tag
• DHCP Mac
• DHCP Mac Range
• DHCP Port
• DHCP Generic
• Mac-Port-IP Binding
• Mac-Port Binding
• Port-Protocol Binding
• Mac
• Mac Range
• Network Rule
• Protocol
Max. number of 1x1 STP instances 253 supported per system
Maximum VLANs VLAN Range Support Up to 4094 VLANs for Flat Spanning Tree mode/MSTP and 253 VLANs for 1x1 Spanning Tree mode
are supported. In addition, it is now possible on the OmniSwitch 6800/6855/9000 to specify a range of VLAN IDs when creating or deleting VLANs and/or configuring VLAN parameters, such as Spanning
Tree bridge values.
Note: Although, up to 4094 VLANs has been configured and tested, we still recommend configuring
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up to 1K (1,024) in a flat STP mode.
Is the native (untagged) VLAN required to be a specific VLAN? Alcatel-Lucent Response: No.
Note: Alcatel-Lucent AOS OmniSwitch product family software refers to a “native” VLAN (a Cisco
term) as a “default” VLAN. Therefore, our “default VLAN” functionality is similar to that of “native VLAN” as discussed here.
Is the management VLAN required to be a specific VLAN?
Alcatel-Lucent Response: No. Can the management VLAN be tagged or untagged?
Alcatel-Lucent Response: YES. Can the Native VLAN be excluded from an 802.1Q link (i.e., the ability to send only tagged traffic over an 802.1Q link)?
Alcatel-Lucent Response: YES.
How many VLAN IDs does this device support? Alcatel-Lucent Response: Comply with up to 4093.
Maximum Number of Tagged VLANs per Port: 4093
VLAN Stacking & Translation
Maximum frame size With the insertion of a 4-byte svlan tag by VLAN Stacking, the maximum frame size that can be
accommodated is jumbo frame size less 4 bytes = 9216 – 4 = 9212 bytes.
Maximum number of SVLANs: •For port level VLAN Stacking: 4093 (VLAN 2 through 4094).
•For port / vlan level VLAN Stacking: 768 (can use any number from 2 through 4094 inclusive).
Maximum number of BPDUs the switch can handle Approximately 800 BPDUs per second
MAC Address Table Up to 16 K (16,384) MAC Addresses is supported per system.
1K (authenticated / mobile users) per module
IP Address Table Routes 48K routing table 12K forwarding LPM entries, 8K hosts entries per module
Layer-2 Table Hashing
The L2 Table size is 16K entries. This is organized as 2K buckets with each bucket having 8 entries.
The search key for the L2 Table is the 60 bit (i.e. 48-bit DA MAC address + 12 bit VLAN-ID) in the Ethernet MAC header in the incoming flow. The key is hashed into a 11-bit value used to select the
bucket in the table using a CRC32 lower 11-bits algorithm. Each entry in the selected bucket is
compared with the key. The match must be an exact match since if it does, it must be a host MAC address entry. If the key matches an entry in the bucket, then the information in the entry is used in the
ingress logic for the destination port
RSTP Performance
Sub-second performance
Link Fail-over: 459ms
Link Fail-over Reverse: 240ms Port Fail-over: 220ms
Port Fail-over Reverse: 140ms
AGG Links Fail-over: 958ms AGG Links Fail-over Reverse: 260ms
AGG Fail-over: 219ms
AGG Fail-over Reverse: 280ms
Max number of configured VLANs per port 1 K (1,024) with support of full 4K IEEE 802.1Q VLAN Spectrum. Port based (w / IEEE 802.1Q)
VLANs.
A-VLAN Maximum number of Avlan authenticated user per system: 1024.
The system supports up to 1024 authenticated/mobile Mac-addresses AVLAN supports RADIUS or LDAP as authentication servers. By configuring multiple servers, user
can gain server failover in case of server outage.
Supported rules for AVLAN. MAC-Port Binding rule
MAC-IP-Port Binding rule
MAC range (used for IP phone OUI Mac-addresses for instance)
Max number of configured VLANs per system 4K (4,094) The switch has indeed been tested with up to 4,094 active VLANs, but this is really based on switch
configuration and available resources.
Note: since configuring 4K VLANs consumes a lot of resources, the more practical, or more
realistic and/or recommended figure is the 1,024 active VLANs.
In the STP flat Mode: 4K VLANs are supported over 802.1Q or over a trunk.
In the STP 1x1 Mode: 253 VLANs are supported over 802.1Q or over a trunk. In the STP Multiple Mode (IEEE 802.1s): 4K VLANs amongst 16 Multiple STP Instances (MSTPI).
Max number of system wide Rules 8 K (8,192)
Maximum number of rules per chassis: The following limitations are imposed by the NI hardware table sizes.
Since the tables are always synchronized between NI, the following numbers are the chassis limitations:
1024 VLAN-MAC rules:
A vlan Mac rule consists in MAC, MAC range, MAC-Port-IP binding, MAC-Port binding, MAC-Port-Protocol binding, MAC-IP binding and IPX Network rules.
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Since hardware does not support IPX network rules, the system internally uses a vlan Mac rule to map
the Mac address matching the given IPX network to that vlan. The VLAN-MAC table is also shared with authenticated Mac-addresses (AVLAN, 802.1x)
256 VLAN-SUBNET rules
A vlan subnet rule consists in IP network and Port-IP binding rules
16 VLAN-PROTOCOL rules
A vlan protocol rule consists in Protocol and Port-Protocol binding rules.
For IP protocol (ip-e2 or ip-snap), 2 rules are needed: 1 for ip packets and 1 for arp packets.
Notes:
• Dual protocols Mac-address is supported. The same Mac with both IP protocol (ip-e2) and IPX protocol (ipx-e2) can be classified into 2 different VLANs.
• Duplicate Mac on different mobile vlan is only supported for IP network rules or protocol rules. For rules falling into the VLAN MAC table, only one Mac/vlan is supported. For
instance, the same Mac with 2 IPX networks 0x111 and 0x222 cannot be classified into 2
VLANs.
• Tagged packets on mobile ports are first classified by their VLAN-ID. If you do not have
mobile-tag enabled for that vlan or a mobile rule to classify that packet to that vlan, the
packet is dropped.
Max number of MAC Rules 1 K (1,024)
Note: Maximum number of MAC rules, Authenticated VLAN Users, Binding Rules, and 802.1x Users all share the 1,024 MAC Rules
Max number of Subnet Rules 256 (Maximum of 256 IP Subnet rules are supported.)
Max number of Protocol Rules – System
16 + 1 per port Maximum of 16 rules of combining Protocol & Port-Protocol rules are supported (If IP-E2 is used,
total of 14 rules are supported)
Max Types of Protocols Rules supported 6 (Note: Support for IP, IPX, DECNet, AppleTalk, SNAP, and Ethertype)
Max number of DHCP rules per system 64
Max number of Binding Rules 1 K (1,024) Note: Maximum number of MAC rules, Authenticated VLAN Users, Binding Rules, and 802.1x Users
all share the 1,024 MAC Rules
Maximum of 1024 rules of combining MAC-Port-IP binding, MAC-Port binging, MAC, MAC Range, and IPX Network rules (The available MAC rule pool is also shared by AVLAN and 802.1x)
Max number of 802.1Q tags per port 4 K
Max number of Authenticated Users 1 K (1,024)
Note: Maximum number of MAC rules, Authenticated VLAN Users, Binding Rules, and 802.1x Users all share the 1,024 MAC Rules
Max number of 802.1x Users Maximum number of 802.1x authenticated user per system: 1 K (1,024)
Maximum number of 802.1x authenticated user per port: 253
The system supports up to 1024 authenticated/mobile mac-addresses. Note: Maximum number of MAC rules, Authenticated VLAN Users, Binding Rules, and 802.1x Users
all share the 1,024 Mac Rules
Max number of STP instances per system 253
Max number of 802.1s STP instances per system 253
Max number of Link Aggregate 32 aggregates of up to 8 ports each Support for static aggregate (aka OmniChannel)
Support for dynamic aggregate (IEEE 802.3ad)
LOAD BALANCE ALGORITHM The load balance is the same for static and LACP link aggregation.
The load balance takes the 3 last bits of the source address and the 3 last bits of the destination address
and does an XOR. That gives a number between 0 and 7 Note that Link1 is the lowest port number, then Link2 is next port number …
Static ARP with multicast Mac When you want to flood a routed unicast packet to ALL ports of the egress vlan, which can be
achieved by creating a static ARP with a multicast Mac address.
The flooding is done in hardware (wire speed). Using a policy rule, you can rate limit the flooding to a specific rate.
That feature is not supported on 10Gig (Ingress). However, flooding on egress 10Gig is supported.
The UDP Relay Services The UDP Relay will verify that the forward delay (elapsed boot time specified by the user) has been met before Relaying the UDP packet.
If the relay is configured with multiple Next Hop addresses, then the packet will be sent to all next-hop
destinations. The UDP Relay shall also verify that the maximum hop count (also set by the user) has not been exceeded. If either of these conditions is not meet, the UDP Relay will discard the
BOOTP/DHCP packet. NBNS/NBDD and generic service has been added to the UDP port relay. As indicated in the table for NBNS and NBDD user can specify which vlan the packets are forwarded
to. User can not specify the next hop IP address or the next hop address type.
For all other generic services, user is able to configure which vlan (up to 10 VLANs) the UDP packet is to be forwarded to. User cannot specify the next hop IP address or the next hop IP address type.
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Service UDP Port Number Configurable Options
BOOTP/DHCP (Bootstrap Protocol/
Dynamic Host
Configuration Protocol)
67/68 (Request / Response)
1. Next Hop Address 2. Forward delay
3. Maximum hops
NBNS/NBDD 137/138 1. VLANs to forward
to Generic services Any number 1. VLANs to forward
to Auto-negotiation Speed (10, 100, 1000Mbps) and duplex mode (half or full)
Traffic Control IEEE 802.3x Note: the switch does not support honoring the incoming (RX) IEEE 802.3x pause frames, but it does
support generating outgoing (TX) IEEE 802.3x pause frames
Spanning Tree • IEEE 802.1D Standard Spanning Tree Algorithm and Protocol (STP)
• IEEE 802.1w Rapid Spanning Tree Algorithm and Protocol (RSTP)
• IEEE 802.1s / IEEE 802.1Q 2005 Multiple Spanning Tree Protocol (MSTP)
• Ring Rapid Spanning Tree Protocol (RRSTP)
• PVST+ Support of single and multiple instances for STP & RSTP BPDU Watch Guard
How many Multiple Spanning Tree Groups are supported? 253
Is one Spanning Tree per Group supported? Yes only in a STP 1x1 mode Is one Spanning Tree per port supported? Yes
Is Single Instance Spanning Tree supported? Yes only in a STP flat mode
Does this device support any spanning tree enhancements (e.g., Root Guard, BPDU Guard, BPDU Filtering, PortFast, etc.)?
Alcatel-Lucent Response: YES. Note: Alcatel-Lucent AOS OmniSwitch product family software refers to “Root Guard” as “Restricted
Role” which is supported.
Note: Alcatel-Lucent AOS OmniSwitch product family software refers to “BPDU Guard” as “BPDU Shutdown Ports” which is supported.
BPDU Filtering is supported.
Note: Alcatel-Lucent AOS OmniSwitch product family software refers to “PortFast” as “EdgePort” which is supported.
Does this device support an instance of spanning tree per 802.1Q VLAN (commonly referred to as
PVST+)? Alcatel-Lucent Response: Comply.
Maximum Number of STP Instances:
Per Stack and/or Per Chassis
a) Flat Mode:
STP – 1 Instance
RSTP – 1 Instance MSTP – 1 CIST and 16 MST Instances
b) 1x1 Mode:
STP – 253 Instances RSTP – 253 Instances
Spanning Tree Root bridge priority / path cost
a) Default spanning tree mode is RSTP (IEEE 802.1w) b) The bridge priority can be any value between 0 and 65535 for STP and RSTP protocol in
the 16 bit mode. By default, spanning tree follows the 16 bit path cost. c) The bridge priority can only be in multiples of 4096 in the 32 bit mode or in MSTP mode.
d) MSTP can support 32 bit mode per standard.
e) Changing STP protocol to MSTP will reset all priority and path cost of a bridge to default
The default port path costs are: (IEEE Std 802.1D-1998- 16 Bit)
Port Speed Path cost
10M 100
100M 19
1000 M 4
10000 M 3
The default port path costs are: ( IEEE Std. 802.1Q-2005 32 Bit)
Port Speed Path cost
10M 2000000
100M 200000
1000 M 20000
10000 M *- Not available
2000
The default link aggregation path costs are (16 Bit):
Linkagg speed Linkagg size Path cost
2 60
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8 30
2 12
4 9
100M
8 7
1000M N/A 3
10000M N/A 2
The default link aggregation path costs are (32 Bit):
LinkAgg speed LinkAgg size Path cost
2 1200000
4 800000
10M 8 600000
2 120000
4 80000
100M
8 60000
2 12000
4 8000
1000M
8 6000
10000M
*- Not available
2
4
8
1200
800
600
Port Monitoring The same unit cannot support both mirroring and monitoring configuration i.e. a user cannot have a
port monitoring and a port mirroring session on the same unit. Only one monitoring session at a time across the entire system
Only the first 64 bytes of the packet can be monitored. Due to the port monitoring file size, the system can only store the first 2K packets (i.e. 140K/64 = 2187)
The port monitoring is not supported on the linkagg ports.
Enabling the monitoring function affects the performance. Consequently, Port Monitoring performance is not at wire-rate.
Port Mirroring Usage Guidelines • The maximum number of mirroring sessions is limited to one on OmniSwitch 6800, whereas two (2) mirroring sessions are allowed on OmniSwitch 9000 and OmniSwitch 6855.
• You cannot configure a port mirroring and a port monitoring session on the same NI module in an OmniSwitch 9000.
• You cannot configure port mirroring and monitoring on the same switching ASIC on OmniSwitch
6855 Series switches. Each switching ASIC controls 24 ports (e.g., ports 1–24, 25–48, etc.). For example, if a port mirroring session is configured for ports 1/12 and 1/22, then configuring a port
monitoring session for any of the ports between 1 and 24 is not allowed.
• If a port mirroring session is configured across two switching ASICs, then configuring a monitoring session is not allowed on any of the ports controlled by each of the ASICs involved. For example, if a
port mirroring session is configured for ports 1/8 and 1/30 on a 48-port switch, then configuring a port
monitoring session involving any of the ports between 1 and 48 is not allowed. • Port mirroring is not supported on logical link aggregate ports however, it is supported on individual
ports that are members of a link aggregate.
• An “N-to-1” port mirroring session is configurable, where “N” can be a number from 1 to 24 In other words, you can configure up to 23 ports for a single destination port in a session.
• Once you execute the port mirroring source destination command to define the mirrored port and
enable port mirroring status, the port mirroring command must be used to enable the port mirroring session.
• By default, the mirroring port is subject to Spanning Tree changes that could cause it to go into a
blocked state. To prevent this, specify the vlan_id number of the mirroring port that is to remain unblocked when executing the command.
Usage Guidelines - Remote Port Mirroring
• Remote Port mirroring is supported on OS6855 • Use the rpmir-vlan parameter with this command to configure remote port mirroring.
• There must not be any physical loop present in the remote port mirroring VLAN.
• Spanning Tree must be disabled for the remote port mirroring VLAN. • Source learning must be disabled or overridden on the ports belonging to the remote port mirroring
VLAN on intermediate and destination switches.
• The QoS redirect feature can be used to override source learning.
Port Mapping Port mapping feature is supported on 6850/6855/9000. Following are the limitations for the feature.
• 8 sessions supported per standalone switch and stack
• An aggregable port of a link aggregation group cannot be a mapped port and vice versa • A mirrored port cannot be a mapped port and vice versa
• A mobile port cannot be configured as a network port of a mapping session
STP convergence time (flat, 1x1, 802.1s) 30 sec
802.1w rapid reconfiguration Less than 1 sec
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Learned MAC addresses per port Up to 16 K (16,384) MAC Addresses is supported
Learned MAC addresses per system Up to 16 K (16,384) MAC Addresses is supported
Layer-2 forwarding on Ethernet ports Wire-speed (64 Bytes packets)
Layer-2 forwarding GigE, known MAC Wire-speed (64 Bytes packets)
Broadcast per Ingress port Programmable
Loopback Interface The loop-back interface allows you to uniquely identify a router in the network with one IP address. The advantage of the loop-back interface is to be independent of the physical ip interfaces. In a
redundant routing network, the loop-back interface is always accessible when routing topology
changes or ip interfaces go down. The main advantage of Loop-back interface is a more reliable Network Management path through
OmniVista or an NMS station.
Also, you can use the loop-back interface to uniquely identify the router within OSPF and BGP if you set the router-id to the same as the loop-back address.
The loop-back can also be used for the RP (Rendezvous Point) in PIM-SM. The loop-back address is also used for the sFlow Agent IP address.
The Loopback address is used for source IP of RADIUS authentication.
User Definable Loopback Interface
Loopback0 is the name assigned to an IP interface to identify a consistent address for network
management purposes. The Loopback0 interface is not bound to any VLAN; therefore it always remains operationally active. This differs from other IP interfaces, such that if there are no active ports
in the VLAN, all IP interfaces associated with that VLAN are not active. In addition, the Loopback0
interface provides a unique IP address for the switch that is easily identifiable to network management applications.
Sever Load Balancing (SLB) No supported
Layer-3 Routing Unicast (IPv4) Layer-3 Routing Protocols
(IPv4) IP Routing
• Static routing
• RIP v1 & v2 • OSPF v2
• BGP v4 *- with AOS 6.4.2 release
Multicast • IGMP v1, v2 & v3 snooping
• PIM-SM • PIM-DM • DVMRP
Network Protocol
• TCP/IP stack • ARP
• DHCP relay
• Generic UDP relay per VLAN
Resilience
• VRRPv2
Layer-3 Routing (IPX) IP Routing • Static routing
• RIP/SAP
Residential Metro
Triple-play Ethernet Access
• DHCP Option 82 – relay agent information
• Q-in-Q (Vlan stacking) • Ethernet OAM compliant with 802.1ag version 7.0
Large L3 table support Hardware:
• Maximum number of active flows in the hardware: 12K
One active flow is usually one “remote-subnet” flow (not a per destination ip flow based) Now with the ARP table enhancement, one active flow can also be a “host routed” flow
The table is shared for - IPV4 active flow (remote ipv4 network): 1 entry
- IPV6 active flow (remote ipv6 network): 2 entries
- Host active flow (ARP entry): 1 entry • Maximum number of active “ARP entries” flows: 12K
• Maximum number of ECMP Next-hops that can be stored: 512
Software: • Maximum number of IPv4 routes that can be held in the software routing table: 96K
• Maximum number of IPv6 routes that can be held in the software routing table: 5K
• Maximum number of ARP entries that can be held in software ARP table: 16K
Routing Information Base (RIB) & Forwarding Information Base (FIB)
Tested figures: The IPv4 RIB and the IPv6 RIB are separate tables with different capacities. RIB:
The RIB is 96K (IPv4). FIB:
There are actually two IPv4 FIBs and IPv6 FIBs.
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One is the software FIB which is separate for IPv4 & IPv6 and the second one is the hardware FIB
which is common for both IPv4 and IPv6. In the hardware FIB there is room for 12K IPv4 entries or 6K IPv6 entries.
Since the table is shared and IPv6 entries take up twice the room of an IPv4 entry you can have
combination like 10K IPv4 and 1K IPv6.
Maximum number of IP route entries (Layer-3 Routing Table Size)
(Maximum Routing Information Base – RIB)
Up to 48K routing table is supported. 12K forwarding LPM entries, 8K hosts entries per module.
Max number of IP Router interfaces per system – Single mode
1 K (1,024)
Max number of IP routes Up to 48K
Max number of IP static routes 1 K (1,024) routes
RIPv1&v2
• Maximum number of IP Routes: 48K
• Maximum number of RIPv2 interfaces per router: 10
• Maximum number of RIPv2 peers per router, one per interface: 10
• Maximum number of RIPv2 routes with no redistribution from OSPFv2 RIB on a OS6855 router: 6.5K (6.575K truncated to 6.5K)
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OSPFv2 Specifications The following values are the maximum limits enforced by the code. Maximum number of Areas (per router): 32
Maximum number of Interfaces (per area): 100
Maximum number of Interfaces (per router): 32 x 100 (Limited only by max. num of IPv4 interfaces = 4096) Maximum number of Link State Database entries (per router): 96K
Maximum number of neighbors/adjacencies (per router): 254 Maximum number of neighbors/adjacencies (per area): 128
Maximum number of routes (per router): 96K
Maximum number of OSPFv2- ECMP gateways (per destination): 4 Max number of OSPFv2 Sessions: 1
The following values are the tested limits with functionally verified (stress test).
On OS6855 ABR routers: Max number of IP Routes on OS6855 router: 12K
Max number of OSPFv2 Routes on OS6855 router: 12K
Max number of OSPFv2 Interfaces on OS6855 ABR: 48 Max number of OSPFv2 Areas on OS6855 ABR: 6
Max number of OSPFv2 Adjacencies on OS6855 ABR: 48
Max number of LSAs on OS6855 ABR: 12K Tested number of OSPFv2- ECMP gateways (per destination): 4
Max number of OSPFv2 Sessions: 1
On OS6855 non-ABR routers: Max number of IP Routes on OS6855 router: 96K
Max number of OSPFv2 Routes on OS6855 router: 96K
Max number of OSPFv2 Interfaces on OS6855 non-ABR: 27 Max number of OSPFv2 Areas on OS6855 non-ABR: 6
Max number of OSPFv2 Adjacencies on OS6855 non-ABR: 27
Max number of LSAs on OS6855 non-ABR: 24K Tested number of OSPFv2- ECMP gateways (per destination): 4
Max number of OSPFv2 Sessions: 1
Notes: Please note that, the above OSPFv2 specifications may vary depending on the available system
resources, and/or customer specific networking requirements & configurations.
Please also note that, depending on the number of Areas, Interfaces, Adjacencies, and Neighbors configured, the maximum number of routes may vary.
Please contact our customer Service & Support team, should your required specifications fall between
"the limits as enforced by the code" and "the limits as functionally tested".
ECMP Only 512 networks can be programmed in the ECMP table, so that the flows can be load balanced among the different paths.
When having more than 512 ECMP routes on the “show ip route”, only the last (highest) 512 routes are programmed in the ECMP table.
• Only 512 networks can be load balanced over ECMP links
• The other “ECMP networks” will always be routed on the same link.
BGP Routing Limitations
* in AOS release 6.4.2
Maximum BGP Peers per Router: 8
Maximum number of routes supported: 30,000
Range for AS Numbers 1 to 65535 Range of Local Preference Values 0 to 4294967295
Range for Confederation IDs 0 to 65535
Range for MED Attribute 0 to 4294967295
ARP Table: Max number of ARP entries per system Up to 8K (8,192) L3 ARP entries are supported.
Layer-3 forwarding, known IP@64 bytes pkt Wire-speed
Layer-3 forwarding, known IP@1518 bytes pkt Wire-speed
Layer-3 forwarding, known IP@ Jumbo pkt Wire-speed
Trunking 2 VLANs, 64 Bytes pkt Wire-speed
Trunking 2 VLANs, 1518 Bytes pkt Wire-speed
RIP Learning Rate 500 / sec
OSPF Learning Rate 500 / sec
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Route Convergence for OSPF 1.2 sec
IP redistribution
Supported platform: OS6800, OS6855, and OS9000 IPv4 Redistribution instances use route-maps to redistribute routes from a source protocol RIB to a
destination protocol RIB. The source protocol can be BGP, RIP, OSPF, Local or Static. The
destination protocol can be BGP, RIP or OSPF. • Maximum number of route-maps that can be created on router: 200
• Maximum number of route-map sequences that can be created on router: 400
• Maximum number of IPv4 access-lists that can be configured on router: 200 • Maximum number of OSPFv2 routes that can be redistributed into RIPv2: 6.5K
• Maximum number of RIPv2 routes that can be redistributed into OSPFv2: 6.5K
Unicast Routing Protocol Performance Below table is high light of routing limitation in 6.1.3.R01 release for OS6850 and OS9000.
OS6855 has the same performance as OS6850.
OS6850 OS9000
OSPFv2 ABR
LSA#/Routes# 12K/12K 32K/32K
OSPFV2 non-ABR LSA#/Routes# 24K/96K
24K/96K (4 ECMP)
RIPv2 6.5K 8.5K
IPv4 Redistribution RIPv2 into
OSPFv2 6.5K 8K
IPv4 Redistribution
OSPFv2
into RIPv2 6.5K 8.5K
OSPFv3 ABR LSA#/Routes# 1.25K/1.25K 1.25K/1.25K
OSPFv3 non-ABR
LSA#/Routes# 1.25K/1.25K 1.25K/5K
(4 ECMP)
RIPng 6.5K 8.5K
IPv6 Redistribution
RIPng into OSPFv3 1K 1K
IPv6 Redistribution
OSPFv3
into RIPng 1K 1K
Multicast & Network Protocols & Resilience Multicast Performance Q: Does this device support IPv4 hardware-based Multicast Routing?
A: Hardware-based native IPv4 & IPv6 Unicast & Multicast Routing is supported. The Alcatel OmniSwitch 9000s are designed to anticipate future network needs with wire-rate
processing for IPv4/IPv6 and support for unicast and multicast applications such as voice-over-IP and
video collaboration. The switches support edge requirements as Gigabit Ethernet to the desktop becomes commonplace and demand for power-over-Ethernet (PoE) capability increases.
Q: How many IPv4 Multicast Routes are supported?
A: We support as many IPv4 Multicast Routes as memory will allow. The more limiting factors are that we support 1,021IP Multicast flows (where a flow is classified as source-group pair).
Q: How many IPv4 multicast packets does this device route per second at 64-bytes?
A: Wire rate. Q: How many IPv4 multicast packets does this device route per second at 1518-bytes?
A: Wire rate.
Q: Does this device support IPv6 hardware-based Multicast Routing? A: Hardware-based native IPv4 & IPv6 Unicast & Multicast Routing is supported.
The Alcatel OmniSwitch 6850/9000s is designed to anticipate future network needs with wire-rate
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processing for IPv4/IPv6 and support for unicast and multicast applications such as voice-over-IP and
video collaboration. The switches support edge requirements as Gigabit Ethernet to the desktop becomes commonplace and demand for power-over-Ethernet (PoE) capability increases.
Note: The OmniSwitch 6850/9000 supports IPv6 hardware-based Multicast Switching (forwarding
between ports on the same VLAN) and IPv6 hardware-based Multicast Routing. Q: How many IPv6 Multicast Routes are supported?
A: We support as many IPv6 Multicast Routes as memory will allow. The more limiting factors are
that we support 1,021 IP Multicast flows (where a flow is classified by a source-group pair). Q: How many IPv6 multicast packets does this device route per second at 64-bytes?
A: Wire rate. Q: How many IPv6 multicast packets does this device route per second at 1518-bytes? A: Wire rate.
Multicast Flows
A flow is defined as a source-group pair.
Maximum Multicast Flows per switch: 1,021 (with hardware routing)
Up to 1,021 simultaneous multicast flows are supported. There is no hard limit on the number of static multicast groups that can be configured, but if you try to send traffic to the entire group at the same
time the limit is still 1,021 hardware flows. A flow is defined as a source-group pair.
In the case all hardware entries are exhausted, the IPMS will not perform software forwarding. IP multicast tunneling is performed in software.
Multicast support IGMPv1&v2&v3 Snooping
MLD Snooping
DVMRP PIM-SM
PIM-DM
Flow Table 1021 entries per system
VLAN Replication 2048 entries per system
Max number of DVMRP Interfaces 128
Max number of DVMRP Neighbors 256
Max number of DVMRP Tunnels 1 per interface
Max number of PIM-SM Interfaces 128
PIM-DM (IPv4) PIM-DM is a multicast routing protocol that defines a multicast routing algorithm for multicast groups
that are densely distributed across a network. It uses the underlying unicast routing information base to
flood multicast datagrams to all multicast routers. Prune messages are used to prevent future messages from propagating to routers with no group membership information. It employs the same packet
formats as sparse mode PIM (PIM-SM).
PIM-DM assumes that when a multicast source starts sending, all downstream systems want to receive multicast datagrams. Initially, multicast datagrams are flooded to all areas of the network. PIM-DM
uses RPF (Reverse Path Forwarding) to prevent looping of multicast datagrams while flooding. If
some areas of the network do not have group members, PIM-DM will prune off the forwarding branch by instantiating prune state.
PIM-DM differs from PIM-SM in two essential ways:
1. There are no periodic joins transmitted, only explicitly triggered prunes and grafts. 2. There is no Rendezvous Point (RP). This is particularly important in networks that cannot tolerate a
single point of failure.
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IGMP learning performance The system can process 1000 IGMP per second. However, the performance can drop to 128 when IGMP are received too fast.
• Burst of 1000 IGMP reports at 1000 packet/sec: all 1000 groups are learnt
• Burst of 1000 IGMP reports at 1Gbps: only 128 groups are learnt
Zapping You can configure “ip multicast zapping” to optimize channel surfing. That will instantly stop
forwarding multicast to a client when that client sent an IGMP Leave. The zapping time can be
measured by the leave message received by the switch and the last packet received by the client. This is usually in milliseconds. The feature is well suited for Multicast Switching and zapping only works
well when “ip multicast querying” is disabled.
L2 static multicast •1022 static multicast MACs are supported on OS6855 and OS9000. The L2 Multicast table can have 1024 entries but 2 are reserved for other applications.
Multicast without 8021.Q on 10/100Mbps interfaces Wire-speed
Multicast without 8021.Q on 1000Mbps interfaces Wire-speed
Multicast with 8021.Q, 0 copies, 1518Bytes pkt on
10/100/1000Mbps ports and/or GigE ports
Wire-speed
Multicast with 8021.Q, 1 copies, 1518Bytes pkt on 10/100/1000Mbps ports and/or GigE ports
Wire-speed
Multicast with 8021.Q, 2 copies, 1518Bytes pkt on 10/100/1000Mbps ports and/or GigE ports
Wire-speed
Network Protocols DHCP Relay (including generic UDP Relay)
TCP/IP Stack NDP
ARP
Resilience VRRPv3 Virtual Router Redundancy Protocol, VRRPv3, is designed to eliminate the single point of failure
existing in a static default routed IPv6 environment. The loss of the default router isolates all systems not able to detect an alternate path.
VRRPv3 provides the capability for assigning the responsibility of a virtual router to one of the IPv6
VRRPv3 routers on a LAN. A total of 255 VRRP3 instances can be configured if only IPv6 instances are configured. The total of
255 instances on a box is the maximum number of VRRP instances (VRRP2 + VRRP3) that can be
configured on a box.. As an example if a user configures 200 VRRP2 instances, then only 55 VRRP3 instances can be configured. If a user configures 255 VRRP2 instances then no VRRP3 instances can
be configured and vice versa.
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Layer-3 Routing Unicast (IPv6) Layer-3 Routing Protocols (IPv6) IP Routing
• Static routing • RIPng
• OSPF v3
Multicast • MLD snooping
• PIM-SM
• PIM-DM
Network protocol
• TCP/IP stack
• DHCP relay (including generic UDP relay) • ARP
Resilience • VRRPv3
Large L3 table support Hardware:
• Maximum number of active flows in the hardware: 12K
One active flow is usually one “remote-subnet” flow (not a per destination ip flow based) Now with the ARP table enhancement, one active flow can also be a “host routed” flow
The table is shared for
- IPV4 active flow (remote ipv4 network): 1 entry - IPV6 active flow (remote ipv6 network): 2 entries
- Host active flow (ARP entry): 1 entry
• Maximum number of active “ARP entries” flows: 12K • Maximum number of ECMP Next-hops that can be stored: 512
Software:
• Maximum number of IPv4 routes that can be held in the software routing table: 96K • Maximum number of IPv6 routes that can be held in the software routing table: 5K
• Maximum number of ARP entries that can be held in software ARP table: 16K
Routing Information Base (RIB) &
Forwarding Information Base (FIB)
Tested figures:
The IPv4 RIB and the IPv6 RIB are separate tables with different capacities. RIB:
The RIB is 96K (IPv4).
FIB: There are actually two IPv4 FIBs and IPv6 FIBs.
One is the software FIB which is separate for IPv4 & IPv6 and the second one is the hardware FIB
which is common for both IPv4 and IPv6. In the hardware FIB there is room for 12K IPv4 entries or 6K IPv6 entries.
Since the table is shared and IPv6 entries take up twice the room of an IPv4 entry you can have combination like 10K IPv4 and 1K IPv6.
Maximum number of IP route entries
(Layer-3 Routing Table Size)
(Maximum Routing Information Base – RIB)
Up to 16K routing table is supported.
6K forwarding LPM entries, 4K hosts entries per module.
Latency: <10µsec
Max number of IP Router interfaces per system – Single mode
1,000
IPv6 routes The total number of IPv6 routes supported in hardware (with no IPv4 routes) is 6000
Max number of IPv6 static routes 1,000 routes
IPv6 interfaces The recommended number of IPv6 interfaces is 100
IPv6 prefixes per interface The recommended number of IPv6 prefixes per interface is 50
IPv6 global unicast addresses per interface The recommended number of IPv6 global unicast addresses per interface is 50
A 6to4 tunnel A 6to4 tunnel explicitly uses an “ingress tunnel” for each IPv4 interface configured on the system. The limit is 100 ingress tunnels
The 10GIG routing performance over an IPv6 tunnel (6to4 and configured tunnel) has been determined
to be 10,775,862 – 96 byte packets per second. The 10GIG routing performance NI-NI or Single NI has been determined to be 14,880,812 - 64 byte
packets per second.
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RIPng
The following values are the maximum limits enforced by the code. The total number of RIPng interfaces is 100.
The maximum number of RIPng neighbors is 20
Maximum number of RIPng routes: 5K routes (Depending on the number of RIPng interfaces, and neighbors configured the maximum number of routes may vary.)
The following values are the tested limits functionally verified.
The following configuration is used as a stress test: (a) Maximum number of RIPng interfaces per router: 10
(b) Maximum number of RIPng peers per OS6855 router: 10 (c) Maximum number of RIPng routes with no redistribution from OSPFv3 RIB: 1000
ARP Table: Max number of ARP entries per system Up to 8K (8,192) L3 ARP entries are supported.
OSPFv3 Specifications The following values are the maximum limits enforced by the code. Maximum number of Areas (per router): 5
Maximum number of Interfaces (per router): 20 Maximum number of Link State Database entries (per router): 5K
Maximum number of adjacencies (per router): 20
Maximum number of OSPF- ECMP gateways (per destination): 4 Maximum number of neighbors (per router): 16
Maximum number of routes (per router): Up to 50K (Depending on the number of Areas, Interfaces, Adjacencies, and Neighbors configured, the maximum number of routes may vary.) Max number of OSPF Sessions: 1
The following values are the tested limits functionally verified.
The following configuration is used as a stress test: On an OS6855 non-ABR Routers:
(a) Min. usable Hello Interval with 20 Interfaces in 5 Areas with 4 Interfaces in each Area: 5 sec (b) Min. usable Router Dead Interval with 20 Neighbors, 4 each in 1 Area for a total of 5 Areas: 20 sec
(c) Max. usable number of LSAs that the OS6855 router can stably hold: 5K
(d) Max. usable number of Ospfv3 Routes that the OS6855 router can stably hold in this scenario: 5K (e) Max. number of usable Ospfv3 Interfaces between any two OS6855 or OS6855/OS9000 routers: 4
(f) Max number of IP Routes on OS6855 router: 5K
(g) Max number of OSPFv3 Routes on OS6855 router: 5K On an OS6855 ABR:
(a) Min. usable Hello Interval with 20 Interfaces in 5 Areas with 4 Interfaces in each Area: 5 sec
(b) Min. usable Router Dead Interval with 20 Neighbors, 4 each in 1 Area for a total of 5 Areas: 20 sec (c) Max. usable number of LSAs that the OS6855 router can stably hold: 5K
(d) Max. usable number of Ospfv3 Routes that the OS6855 router can stably hold in this scenario: 5K
(e) Max. number of usable Ospfv3 Interfaces in 5 areas with 5K LSAs: 20 (f) Max. number of usable Ospfv3 Neighbors in 5 areas with 5K LSAs: 20
(g) Max. number of usable Ospfv3 Interfaces between any two OS6855 routers: 4
(l) Max. number of usable Ospfv3 Areas on an OS6855 ABR: 5
Notes:
Please note that, the above OSPFv3 specifications may vary depending on the available system resources, and/or customer specific networking requirements & configurations. Please also note that, depending on the number of Areas, Interfaces, Adjacencies, and Neighbors
configured, the maximum number of routes may vary.
Please contact our customer Service & Support team, should your required specifications fall between "the limits as enforced by the code" and "the limits as functionally tested".
IPv6 REDISTRIBUTION (a) Maximum number of route-maps that can be created on an OS6855 router: 200
(b) Maximum number of route-map sequences that can be created on an OS6855 router: 400
(c) Maximum number of IPv6 access-lists that can be configured on an OS6855 router: 200 (d) Maximum number of OSPFv3 routes that can be redistributed into RIPng: 1K
(e) Maximum number of RIPng routes that can be redistributed into OSPFv3: 1K
Layer-3 forwarding, known IP@64 bytes pkt Wire-speed
Layer-3 forwarding, known IP@1518 bytes pkt Wire-speed
Layer-3 forwarding, known IP@ Jumbo pkt Wire-speed
Trunking 2 VLANs, 64 Bytes pkt Wire-speed
Trunking 2 VLANs, 1518 Bytes pkt Wire-speed
RIP Learning Rate 500 / sec
OSPF Learning Rate 500 / sec
Route Convergence for OSPF 1.2 sec
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Multinetting Multinetting
This feature allows IP traffic from multiple subnets to coexist on the same VLAN. A network is said to be
multinetted when multiple IP subnets are brought
together within a single broadcast domain (VLAN). It is possible to assign up to eight different IP interfaces
per VLAN. Each interface is configured with a
different subnet.
A network is said to be multinetted when multiple IP subnets are brought together within a single
VLAN. For example, one may configure the subnet 192.168.1.0/24 and 194.2.10.0/24 to run on the same switch interface. In other words, traffic from the 192.168.1.0 subnet and traffic from the
194.2.10.0 subnet would coexist on the same physical VLAN.
Within a Layer 2 environment, the traffic is broadcast between all subnets configured in the same VLAN. Layer-3 traffic is routed between the configured subnets in the same VLAN.
Possible uses for Multinetting:
• Subnet renumbering – used during transition from one addressing scheme to another to maintain connectivity.
• Ability to support more hosts on one physical link – used to add more hosts to a broadcast domain than the addressing scheme allows.
• Supporting multiple subnets on one interface where configurations do not allow complete separation of subnet traffic. For example, a college campus may have departments where
users are connected to a switch via hubs. Connected to each of the hubs are users configured to be in different subnets. The hubs are connected to the switches using port-
based vlan configuration. Network administrators use Multinetting so they do not have to
worry about re-cabling or reconfiguring ports for users in different subnets.
Supported features: • Up to 8 subnets per VLAN
• All existing dynamic routing protocols, routing between each of the multinetted subnets in
one VLAN and routing between each of the multinetted subnets and other VLANs
• VRRP
DHCP is only supported on the primary interface of the multinetted vlan. All devices are assigned to the same scope (the one for the primary interface)
With VRRP and Multinetting, you can still configure multiple instances to load balance the master role
among the sub-netted interfaces.
Routing In Multinetting Routing protocols (RIP, OSPF, BGP) are supported in a multinetted environment. The routing interfaces are now based on ip interfaces, instead of the VLANs. Therefore, routing protocols are
totally independent of VLANs and their data structures are maintained as part of an array indexed by ip
interface only. There is no difference between running a routing protocol on an interface part of a multinetted vlan or a regular interface. Each subnet (interface) on the multinetted vlan can run its own
routing protocol.
Multicast Routing In Multinetting
The multicast routing protocols will be supported on one interface per VLAN. One interface designated the primary interface, will be used for the multicast routing protocols. The multicast routing
protocols will not allow configuration on any non-primary interfaces. By default the first interface is
the primary interface. DVMRP and PIM-SM will only allow configuration on the primary interface of a VLAN. This is to ensure consistency between the multicast routing protocols (DVMRP, PIM-SM,
IPMRM), IPMS and IGMP.
Layer-3 Routing (IPX) Routes 1K Routes
1K Host entries
IPX Routing 64 IPX interfaces Static routing (256 routes)
RIP/SAP, 1K routes
5000 RIP and SAP entries each are supported. IPX routing is limited to 1900 packets per second per NI.
Each NI can independently route up to 1900 p/s.
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Policy/QoS QoS / ACLs Features summary:
• 802.1p classification
• TOS/DSCP classification
• Ethertype classification
• IP protocol classification
• ICMP type and code classification
• TCP Flag classification and “established” for implicit “reflexive” tcp flows
• “qos apply” will not impact existing flows
• Port disable rules to shutdown a port when incoming packets matches a rule
• Rule logging
• Port redirect action to force a packet to be sent out on a given port
• User port profiles to filter and shutdown ports for BPDUs, IP spoofing and routing protocols (rip, ospf, bgp)
• DropServices to drop tcp/udp ports
• IGMP ACLs
• L2/L3/L4 QoS fully supports IP multicast traffic (priority, bandwidth shaping..)
• 8 hardware queues per port
Convergence / Triple Play • Traffic prioritization: Flow-based QoS with internal and external (a.k.a., remarking) prioritization
• Bandwidth management: flow based bandwidth management, ingress policing/egress shaping and port based egress shaping
• Queue management: Random Early Detect/Discard (RED), configurable de-queuing algorithm;
Strict Priority, Weighted and Deficit Round Robin. • Power-over-Ethernet: IEEE 802.3af
QoS Conditions & Actions supported The following types of conditions are available:
• L1 conditions: source port, destination port, source port group, destination port group
• L2 conditions: source mac, source mac group, destination mac, destination mac group,
802.1p, ethertype, and source vlan (Destination vlan is not supported).
• L3 conditions: ip protocol, source ip, source network group, destination ip, destination network group, TOS, DSCP, ICMP type, ICMP code.
• L4 conditions: source TCP/UDP port, source TCP/UDP port range, destination TCP/UDP port, destination TCP/UDP port range, service, service group, tcp flags
• IP multicast condition: An ip multicast condition is used for IGMP ACLs. The multicast ip is actually the multicast group address used in the IGMP report packet.
IP multicast can be combined with destination port, destination vlan, destination Mac,
destination ip, that are the port/vlan/mac/ip of the device that sent the IGMP report The following actions are available:
• ACL (disposition drop/accept – default is accept)
• Priority
• 802.1p/TOS/DSCP Stamping
• 802.1p/TOS/DSCP Mapping
• Maximum bandwidth
• Redirect Port Note: Condition combinations and Action combinations are also supported.
Priority Queues Eight hardware based queues per port
Traffic Prioritization Flow based QoS
Internal & External (aka remarking) prioritization
Bandwidth Management Port & Flow based ingress policing with 64kbps granularity
Port based egress shaping, with 64kbps granularity
Queue Management Configurable de-queuing algorithm
• Strict Priority
• Weighted Round Robin
• DRR (Deficit Round Robin). This mode is quite similar as WRR In the Strict Priority mode, a port has 8 strict priority queues (SPQ) and all the queues on the port are
serviced strictly by priority.
In the WRR or DRR, queues are serviced on a round robin based on their weight. The higher the queue weight, the higher is the throughput for that queue. Any queue can be configured with a weight of 0 to
make that queue strict priority. The weight ordering does not need to follow the queue order.
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Queuing Scheme and Servicing Mode OS6855 has 8 queues per egress port OS6855 has 3 Queuing schemes per egress port:
• Strict-Priority (default mode)
• WRR (Weighted Round Robin)
• DRR (Deficit Round Robin). This mode is quite similar as WRR In the Strict Priority mode, a port has 8 strict priority queues (SPQ) and all the queues on the port are
serviced strictly by priority.
In the WRR or DRR, queues are serviced on a round robin based on their weight. The higher the queue weight, the higher is the throughput for that queue. Any queue can be configured with a weight of 0 to
make that queue strict priority. The weight ordering does not need to follow the queue order.
Queue Mapping Table
Queue Mapping Table
802.1p TOS / DSCP Priority Rule Egress Queue Servicing (*)
0 0 / 0-7 0 0 SPQ or WFQ
1 1 / 8-15 1 1 SPQ or WFQ
2 2 / 16-23 2 2 SPQ or WFQ
3 3 / 24-31 3 3 SPQ or WFQ
4 4 / 32-39 4 4 SPQ or WFQ
5 5 / 40-47 5 5 SPQ or WFQ
6 6 / 48-55 6 6 SPQ or WFQ
7 7 / 56-63 7 7 SPQ or WFQ
(*) SPQ Strict Priority Queue or Weighted Fair Queue if configured with a weight > 0
Max number of Rules 128 per port; 2048 policy rules per chassis
OS6855: 2048 rules per slice
Max number of Actions 128 per port; 2048 policy actions per chassis
Max number of Conditions 128 per port; 2048 policy Conditions per chassis
Max number of Policy Services 256
1024 Max number of Policy Groups
512 entries per policy group
Max number of Queues 8 / port
Filtering or ACL Throughput Wire-speed
Configurable policies OS6855-24 Models port unit (1 TCAM)
Max available HW rules per slot: 1664 Max available tcp/udp port ranges per slot: 16
Max available bandwidth shaping rules per slot: 832
Rule logging OS6855 can log the packets matching a policy rule. The most common use of that feature is to log packet matching an ACL drop policy. To enable logging
configure the policy rule with “log [log interval x]”
The log interval is optional and the default interval is 30 sec. You can configure a log interval between 1 and 3600 sec.
Depending on the configured log interval, the system periodically set the hardware to send copy of the
packet matching the rule to CPU. As soon as the CPU receives a packet matching the rule, the system reset the hardware to no longer send copy to CPU until the next interval, to keep CPU low. The first packet is always logged. If one packet matching the rule is seen during the log interval time, it
will be logged. Limitation:
• More than one packet can be logged depending on the rate of the traffic (because of time required by the CPU to stop the sampling).
• Log interval less than 5 seconds will be accepted by CLI , but logging will be done every 5
sec
• Logging does not lot all matching packets (not an IDS)
Note: CPU stays low with rule logging enable. We tested a logging drop rule with 10 Gbps of incoming traffic and CPU stays low.
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Egress Bandwidth Shaping Port shaping Shaping limits the bandwidth on the egress port. Shaping implies that the shaping function controls the
rate at which the egress port sends the packets, regardless of egress queues. The granularity is 64Kbps.
Queue shaping You can also configure maximum and minimu bandwidth on a per egress queue basis. Configuring an egress queue max bandwidth will shape priority traffic mapped to that queue.
Configuring an egress queue min bandwidth will guarantee that bandwidth for priority traffic mapped to that queue.
When a queue has a minimum bandwidth configured, traffic within that bandwidth has the HIGHEST
priority, regardless the servicing mode or the priority of that queue.
Limitation:
The egress bandwidth shaping is only on a per port basis; the system cannot do a per flow basis egress
bandwidth shaping.
Ingress Max Bandwidth Policing Using policy rule with maximum bandwidth action, you can limit the bandwidth on the ingress. Policing implies dropping the traffic when the programmed rate is exceeded. Policing is on a per flow
basis. The granularity is 64kpbs.
You can do the following:
• Ingress port rate limiting by configure a policy using a source port
• Ingress flow based rate limiting by configure a policy defining that flow
• Mixed of ingress and flow based rate limiting
Limitations:
• Ingress rate limiting is done at the ingress NI. Policies spread out on multiple NIs will make
the total egressing rate to be higher than the configured value (up to the N time the limit where N is the number of NI being spread)
• “Show active policy rule” will count the packets that exceed the rate limiting, not the
packets that matches the rule
Untrusted Ports and Packet Priority On untrusted ports the priority/queue of the incoming packet is based on the “port default 802.1p
value”. By default, the port default 802.1p value is 0 making traffic to be mapped to Q0 (best effort). Also, regardless or bridging or routing:
• 802.1p within the packets is set to the port default 802.1p
• DSCP within the packets is set to the port default dscp Changing the port default 802.1p will:
• Change the priority of all traffic from that port. That is like a “port priority”
• Set the 802.1p value in the packet to that port default 802.1p
Changing the port default DSCP will:
• NOT change the internal priority
• Set the DSCP value in the packet to that of the port default DSCP Notes:
On untrusted port, the default 802.1p defines the default internal priority for all packets.
Untagged packets on untrusted ports get an 802.1p value from the port default 802.1p (if going out on tagged interface).
Limitation:
On untrusted ports, if the packet matches a policy rule, the DSCP in the packet is unchanged; it is not set to the port default dscp
Trusted Ports and Packet Priority On trusted ports the priority/queue of the incoming packet is based on the ingress packet 802.1p or
ToS/DSCP value.
• Non IP packets are prioritized based on the packet 802.1p value
• IP packets are prioritized based on the packet TOS/DSCP value Port default 802.1p or DSCP has no effect on trusted ports.
Notes:
On IP packets, the 802.1p is set to match the packet ToS value. Untagged non-IP packets always get an 802.1p of 0 and priority 0 (if going out on tagged interface).
The port default 802.1p is not applied.
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802.1p/TOS/DSCP Stamping/Mapping policies Regardless the condition or classification, the following stamping/mapping actions are allowed
• Stamp 802.1p
• Stamp TOS (precedence)
• Stamp DSCP
• Stamp 802.1p and TOS/DSCP
• Map 802.1p to 802.1p
• Map 802.1p to TOS
• Map 802.1p to DSCP
• Map ToS to 802.1p
• Map ToS to TOS
• Map ToS to DSCP
• Map DSCP to 802.1p
• Map DSCP to TOS
• Map DSCP to DSCP Stamping/mapping policies change the internal priority of the packets:
• Internal Priority is always based on the new 802.1p or TOS/DSCP being stamped/mapped
• Stamp/map TOS/DSCP also gives internal priority for non IP packets matching the rule
• Mapping rules takes one TCAM rule entry for each entry in the map group
• If both 802.1p and TOS/DSCP are stamped in a policy rule, priority is based on the stamped
802.1p value Notes:
On trusted ports, stamping/mapping a tos/dscp also change the 802.1p value in the packet to the packet
ToS value. If the policy rule has both a 802.1p stamp/map action and a priority action, the packet priority comes from the stamped/mapped 802.1p value, not the priority action.
Policy Based Routing Policy Based Routing (PBR) allows a network administrator to define QoS policies that will override
the normal routing mechanism for traffic matching the policy condition. Note. When a PBR QoS rule is applied to the configuration, it is applied to the entire switch, unless
you specify a built-in port group in the policy condition. Policy Based Routing may be used to redirect
traffic to a particular gateway based on source or destination IP address, source or destination network group, source or destination TCP/UDP port, a service or service group, IP protocol, or built-in source
port group. Traffic may be redirected to a particular gateway regardless of what routes are listed in the
routing table. Note that the gateway address does not have to be on a directly connected VLAN; the address may be
on any network that is learned by the switch.
Note. If the routing table has a default route of 0.0.0.0, traffic matching a PBR policy will be redirected to the route specified in the policy. Policy Based Routing may be used to redirect untrusted traffic to a
firewall. In this case, note that reply packets will be not be allowed back through the firewall.
Policy Based Routing (Permanent Mode)
Policy Based Routing may be used to redirect traffic to a particular gateway based on source or destination IP address, source or destination network group, source or destination TCP/UDP port, a
service or service group, IP protocol, or built-in source port group. Traffic may be redirected to a
particular gateway regardless of what routes are listed in the routing table. Note that the gateway address does not have to be on a directly connected VLAN; the address may be
on any network that is learned by the switch.
Policy Rules with Multiple Actions Multiple policy actions can be combined together within a single rule. The policy actions that can be
combined in the same rule are:
• Priority
• Stamping/mapping
• Max BW
• Redirect Port
QoS Precedence with Multiple Policy Rules A flow can match multiple rules but ONLY the action for the highest precedence-matching rule is then
enforced. When rule are configured without precedence (default precedence is 0), the first created rule
has the highest precedence.
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IPv6 Classification & Combinations
Classification & Combinations The following classification criteria are available (in Release 6.1.3.r01) for ipv6 packets
• source ipv6 address
• destination ipv6 address • Next header. Policies specifying the NH parameter, classify based on the first NH value present in the V6 header of the IPV6 packet
• Flow label • TCP Flags/Established. Policies specifying “established” or “tcpflags”, expect the first NH
value present in the V6 header to be 6
• ToS/DSCP • source vlan
• 802.1p
• source Mac • destination Mac
• source port
• destination port (only for bridged traffic) • Multicast ipv6 for MLD report filtering (similar to IGMP filtering)
IPv6 Actions
Actions
All actions are available for Ipv6 policies
• ACL (disposition drop/accept – default is accept) • Priority
• 802.1p/TOS/DSCP Stamping
• 802.1p/TOS/DSCP Mapping • Maximum bandwidth/depth • Redirect Port / Link aggregation
User-port shutdown profile
Instead of filtering packets, you can configure a user-port profile to administratively disable an interface upon reception of spoof/bpdu/rip/ospf/bgp packets. To make the interface operational again,
the port must be unplugged/plugged back or disabled/enabled using “interfaces s/p admin down” and
“interfaces s/p admin up”. Also, a SNMP trap will be sent when an interface goes down because of the user-port shutdown profile.
Port Disable
You can configure a “Port Disable” rule to administratively disable an interface when matching a
policy rule. To make the interface operational again, the port must be unplugged/plugged back or
disabled/enabled using “interfaces s/p admin down” and “interfaces s/p admin up”. Also, a SNMP trap will be sent when an interface goes down when matching a port disable rule
Policy Based Routing
This feature is supported on OS6855/9000 in 6.1.3.R01. Policy routing allows the user to specify gateways to be used for routed data flows based on various
criteria. • IP Protocol (i.e. ICMP, TCP, ICMP)
• Source IP address (or network group)
• Destination IP address (or network group) • Source TCP/UDP port
• Destination TCP/UDP port
• Souce TCP/UDP service • Destination TCP/UDP service
• Source TCP/UDP service group
• Destination TCP/UDP service group • TOS, DSCP
• Source vlan
• Source slot/port • Source slot/port group
The action that can be specified is a gateway to be used overriding the routing database. Permanent gateway is supported in 6.1.1.R02, alternate gateway is not supported. Permanent gateway
can be set to local next hop IP or remote hop IP.
PBR is done in hardware. Note regarding bridged data flows
PBR is also supported on bridged packets if a static ARP is configured for the permanent gateway.
That way you can force bridged packets to be routed to that permanent gateway.
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High Availability High Availability
The switch provides a broad variety of availability features. Availability features are hardware- and
software-based safeguards that help to prevent the
loss of data flow in the unlikely event of a subsystem failure. In addition, some availability features allow
users to maintain or replace hardware components
without powering off the switch or interrupting switch operations. Combined, these features provide added
resiliency and help to ensure that the switch or virtual
chassis is consistently available for day-to-day network operations.
• Smart Continuous Switching: Hot Swap, Management Module Fail-over, Power Monitoring, Redundant subsystems in stacked configurations, and Stackability
• Virtual chassis design that provide management functionality and automatic election of primary and secondary managers
• Redundant Management & Switch Fabric (stacking configuration)
o Virtual chassis that provides management functionality and automatic election of primary and secondary managers
• Fault tolerant loop stacking (Redundant Stacking link)
• Hot swappable components & hot insertable support: switch modules, SFPs/XFPs
o Hot swappable switch units and power supplies
• Redundant (Backup) Power Supplies (Redundant 1:1 power provided by the OS6855-BPS)
• Redundant 1: 1 PoE power provided by the PoE Power Supplies
• Spanning Tree robustness (Single or Multiple STP options): IEEE 802.1D (STP) (802.1D
spanning tree for loop free topology and link redundancy) and IEEE 802.1w-Rapid Reconfiguration of Spanning Tree (allows sub-second failover to redundant link)
o Ring Rapid Spanning Tree optimized for ring topology to provide less than
100ms convergence time o IEEE 802.1s multiple spanning tree and Alcatel per-VLAN spanning tree (1x1)
o PVST+
• Fast forwarding mode on user ports to bypass 30-second delay for spanning tree
• Prevents unauthorized spanning-tree enabled attached bridges from operating.
• BPDU blocking – automatically shuts down switch ports being used as user ports if a spanning tree BPDU packet is seen. Prevents unauthorized spanning-tree enabled attached
bridges from operating.
• Priority queues: eight hardware-based queues per port
• VRRP (Virtual Router Redundancy Protocol), and OSPF ECMP (Equal Cost Multipath Protocol)
• Dynamic link aggregation IEEE 802.3ad (that supports automatic configuration of link aggregates with other switches) with resilient uplink capabilities
• Static link aggregation with OmniChannel (that supports automatic configuration of link aggregates with other switches)
• IEEE 802.1s: MISTP (802.1s) is an IEEE standard which allows several VLANs to be
mapped to a reduced number of spanning-tree instances. This is possible since most networks do not need more than a few logical topologies. Each instance handles multiple
VLANs that have the same Layer 2 topology.
• Software Resiliency: The AOS OmniSwitch product family provides fully redundant and resilient system components to insure continuous, non-stop operation. This includes
redundant subsystems, hot swappable modules, load-sharing components,” hitless software loading”, downloadable bootstrap, and image rollback which allows the system to
automatically re-load previous configurations and software versions.
o Software image and configuration recovery (Software Rollback) � Image rollback to automatically re-load previous configurations and
software versions
o Image and configuration synchronization for Management Modules o Hitless loading of optional advanced routing software without re-booting
• Broadcast storm control
• Downloadable bootstrap
• Chassis thermal protection/shutdown
• Hardware monitoring, temperature monitoring, and power monitoring & management
• Short “cold” and “warm” boot times
• Built-in security and device hardening
• Network and Link Resiliency: Network and link resiliency are important parts of network availability, and the AOS OmniSwitch product family supports advanced routing, load
sharing, and mechanisms for fast reconfiguration of links between switches, servers, and other network devices. These include:
o VRRP (Virtual Router Redundancy Protocol), and OSPF Equal Cost Multipath
Protocol
• Topological Network Redundancy: In order to provide the highest levels of availability
throughout an enterprise, it is important to build redundancy and resiliency into the topology at the network level to insure that links have backups and traffic is always
flowing. This includes:
o Physical redundancy o Layer 2 and layer 3 redundancies
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Security Advanced Security
The following is only a highlight of the advanced security features supported:
• Partitioned Management – PM: Protected multiple user access control (i.e. the switch provides a full suite of commands that allow the user to create and modify User IDs and
Passwords (multiple administrative profiles) for access to switch management). The PM feature utilizes an on-board database, or RADIUS, LDAP authentication servers (user
profiles are stored within these servers).
• Authenticated Switch Access (ASA): the ASA feature (user access control or device access control) with Secure Access Logging (AAA service) utilizes an on-board database,
RADIUS, LDAP, or ACE authentication servers
• Automatic Log-out based on a pre-configured timer
• Denial of Service Attack Defense (DOS protection)
• IEEE 802.1x industry standard port based authentication challenges users with a password before
allowing network access o IEEE 802.1x multi-client, multi-VLAN support for per-client authentication and
VLAN assignment
� IEEE 802.1x with group mobility � IEEE 802.1x with MAC based authentication, group mobility or
“guest” VLAN support
� MAC-based authentication for non-802.1x host � Alcatel-Lucent Access Guardian support
• Port Mapping (Private VLANs)
• Port Binding
• Authenticated VLAN that challenges users with username and password and supports dynamic VLAN access based on user
• Support for host integrity check and remediation VLAN
• Security through the implementation of OmniVista Quarantine Manager (OV2770-QM)
and quarantine VLAN, with OneTouch Security automation
• PKI authentication for SSH access
• Learned Port Security or MAC address lockdown allows only known devices to have network access preventing unauthorized network device access
• RADIUS and LDAP admin authentication prevents unauthorized switch management
• TACACS+ client allows for authentication-authorization and accounting with a remote TACACS+ server
• Secure Shell (SSH), Secure Socket Layer (SSL) for HTTPS and SNMPv3 for encrypted remote management communication
• Access Control Lists (ACLs) to filter out unwanted traffic including denial of service attacks; Access control lists (ACLs) are per port, MAC SA/DA, IP SA/DA, TCP/ UDP
port; Flow based filtering in hardware (L1-L4)
• Support for Access Control List Manager (ACLMAN)
• Supports Microsoft Network Access Policy (NAP) protocol
• Switch protocol security
o MD5 for RIPv2, OSPFv2 and SNMPv3
o SSHv2 for secure CLI session with PKI support o SSLv3 for secure HTTP session
• DHCP Snooping, DHCP-option 82, and DHCP IP Spoof protection
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Switch accessibility under DoS Attack The following type of packets are processed in software and will increase the CPU usage:
• Unresolved L3 packet: unknown destination IP on a local subnet
• Broadcast L2 packet (including ARP requests):
• IP multicast packet on range 224.0.0.0-224.0.0.255: that includes routing protocol packets
such as OSPF, RIPv2 and VRRP packets
• All IP packets going to a switch ip interfaces: ping, telnet, http
Under normal conditions, the protocol packets are always prioritized in order to maintain the network
topology. The following protocol packets are by default prioritized:
• BPDUs
• OSPF, RIPv2
• VRRP
• IP multicast protocol (IGMP...)
• ARP (both request and reply)
ARP
To prevent an ARP attack, the system limits at 500 pps the number of arp packets sent to CPU
(flooding of arp on the network is not limited). Also, there is an early arp discard mechanism to prevent the CPU from processing arp request not destined to a switch ip address. However, under
attacks towards the switch, the CPU usage could rise dramatically and makes the switch unreachable
for management (WebView, OmniVista or Telnet). In order to keep the switch reachable under attacks, some policies can be created to protect the management access.
IP security enhancement Supported platform: OS6800, OS6855, and OS9000 � Detect ARP Flood
� Detect packets received with invalid Source IP addresses � Detect packets received with invalid Destination IP addresses
� Detect multicast packets with a source MAC that is multicast
� Detect multicast packets with mismatching destination IP and MAC address � Detect multicast packets with a Unicast destination IP and Multicast destination MAC
address
� Detect ping overload � Detect packets with Loopback source IP address
802.1X/Device Authentication Supported platform: OS6800, OS6855, and OS9000
There are 4 levels of 802.1x/device classification:
-Basic 802.1x port. Only successful authenticated 802.1x devices are allowed in the network -Basic 802.1x port + fail authentication policies. Only 802.1x capable devices are allowed in the
network. These policies allow the failed authenticated 802.1x devices to access non-secured (or non authenticated) VLANs
-802.1x + non supplicant policies without Mac authentication. Non 802.1x devices are allowed on non-
secured VLANs according to the non-supplicant policies. -802.1x + non supplicant policies with Mac authentication. In this mode, the non 802.1x devices will
follow either the “non-supplicant authentication pass policies” when the Mac authentication is successful or the “non-supplicant authentication fail policies” when the Mac authentication failed
The open-unique and open-global options are no longer applicable.
Device Authentication: Maximum number of supplicants / non-supplicant users per system: 1024
Maximum number of non-supplicant users per port: 1024
Maximum number of supplicant users per port: 253 Maximum combined number of supplicant and non-supplicant users per port: 1024
The system supports up to 1024 authenticated/mobile Mac-addresses.
Supported/non-supported mobile rule on device authentication: 1. Support rule per tagged/untagged packet type.
Mac rule – apply on UNTAGGED packet
IP subnet rule – apply on UNTAGGED packet Protocol rule – apply on UNTAGGED packet
Port-protocol binding rule– apply on UNTAGGED packet
Mac-port binding rule – apply on UNTAGGED packet Mac-IP-port binding rule– apply on UNTAGGED packet
Mobile-tag – apply on TAGGED packet
* Mobile tag only apply on tagged packets, all other rules apply on untagged packet. 2. DHCP related mobile rules are not supported with device authentication (i.e. supplicant/non-
supplicant cases)
DHCP generic rule DHCP port rule
DHCP Mac / Mac range rule
Device authentication with Alcatel-Lucent IP phone:
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Alcatel-Lucent Dynamic IP phone has 3 modes:
1.Untagged dynamic Packet is always untagged.
2.Tagged dynamic
Packet is always tagged based on administrator config on phone. 3.Alcatel-Lucent dynamic
First packet is untagged, second packet onward is tagged.
ACLMAN ACLMAN is a function of the QoS subsystem in AOS. ACLMAN allows a network administrator to
manage ACLs using default industry standard syntax on Alcatel-Lucent switches. To enforce the ACLs, ACLMAN translates default industry standard syntax into Alcatel-Lucent QoS filtering policies
in a manner transparent to the ACLMAN user.
ACLMAN provides the following: · The ability to import text files from flash containing default industry standard ACL syntax
· An interactive shell emulating the default industry standard CLI ACL command syntax ACLMAN supports the following default industry standard ACL types:
· Standard ACLs
· Extended ACLs · Numbered ACLs
· Named ACLs
These are the limitations for the 6.1.2.R03 release. - Only supported on the OS6855 Series
- No stacking support
- ACLMAN is restricted by the same number of rule limitations that QoS supports - ACL names are limited to 16 characters
DHCP Snooping Number of DHCP Bindings per ASIC: 126 Number of DHCP Bindings per port: 126
Traffic Filtering Flow based filtering in hardware (L1-L4)
User Authentication IEEE 802.1x, with Group Mobility & Guest VLAN support MAC based Authentication for non-802.1x host
Authenticated VLAN (web & telnet based authentication)
Switch protocol security MD5 for RIPv2, OSPFv2 and SNMPv3
SSH for secure CLI session and SSL for secure HTTP session
Switch management Local authentication database Remote authentication RADIUS, LDAP & ACE servers
User-port shutdown profile Instead of filtering packets, you can configure a user-port profile to administratively disable an
interface upon reception of spoof/BPDUs/rip/ospf/bgp packets. To make the interface operational
again, the port must be unplugged/plugged back or disabled/enabled using “interfaces s/p admin down” and “interfaces s/p admin up”. Also, a SNMP trap will be sent when an interface goes down because of
the user-port shutdown profile.
Port Disable You can configure a “Port Disable” rule to administratively disable an interface when matching a policy rule. To make the interface operational again, the port must be unplugged/plugged back or
disabled/enabled using “interfaces s/p admin down” and “interfaces s/p admin up”.
Also, a SNMP trap will be sent when an interface goes down when matching a port disable rule
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Denial of Services (DOS) attacks The system sustained Denial of Services attacks from Nessus and no switch anomalies (crash or service interruptions) were observed while running the attacks. Nessus has reported the following
vulnerabilities:
•alya.cgi (Backdoors) •AnalogX denial of service (Denial of Service) •cisco http DoS (Denial of Service)
•AnalogX denial of service by long CGI name (Denial of Service) •Jigsaw webserver MS/DOS device DoS (Denial of Service)
•Trend Micro OfficeScan Denial of service (Denial of Service)
•BadBlue invalid GET DoS (Denial of Service) •DCShop exposes sensitive files (General)
•OpenSSH < 3.0.1 (Gain a shell remotely)
•Quicktime/Darwin Remote Admin Exploit (Gain a shell remotely) •OpenSSL overflow via invalid certificate passing (Gain a shell remotely)
•TESO in.telnetd buffer overflow (Gain root remotely)
•OpenSSH AFS/Kerberos ticket/token passing (Gain root remotely) •OpenSSH <= 3.3 (Gain root remotely)
•OpenSSH < 3.7.1 (Gain root remotely)
•Oracle Application Server Overflow (Gain Root Remotely) •AliBaba path climbing (Remote file access)
Note:
The Nessus suite was tested under the following platform. The following are the versions of Nessus and the Linux platform used.
Nessus version: 2.2.0
Linux OS: Fedora Core Release 1 The reported failures are not a threat but a check against the switch which the test Nessus suite
reported as vulnerable. For example, when running port scan Nessus will report failures against ports
that should not respond or be open but are internal ports leveraged by the subsystem. As the report stated there is no anomalies detected or crashes from the scan.
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Management Simplified Manageability The following is only a highlight of the advanced network and switch management features supported
by the OmniSwitch 6855 Series: � OmniVista NMS: Alcatel-Lucent’s Single voice, data and services network management
including OneTouch QoS and SecureView.
� CCaarrrriieerr--CCllaassss DDyynnaammiicc MMoobbiilliittyy � Through the application of a comprehensive QoS feature set, the AOS OmniSwitch product
family is capable of supporting converged applications such as the VoIP
� Diagnosing Switch problems: o Port Mirroring; Port based, port mirroring for troubleshooting, supports two (2)
sessions with multiple sources-to-one destination configuration
(The maximum number of mirroring sessions is limited to one on OmniSwitch 6800, whereas two mirroring sessions are allowed on OmniSwitch 9000 and OmniSwitch 6855).
o Port monitoring feature that allows capture of Ethernet packets to a file, or for
on-screen display to assist in troubleshooting
o SFlow v5 support to monitor and effectively control and manage the network usage
o RMON: Supports RFC 2819 RMON group (1-Statistics, 2-History, 3-Alarm,
and 9-Events) o Switch Health
o Monitoring Memory Tools & Switch Configuration
o Switch Logging � Local (on the flash) and remote logging (Syslog)
• Logging into the Switch through Telnet, FTP, HTTP, SSH, SSL, and SNMPv1&v2&v3
o Remote telnet management or secure shell access using SSH o Secured file upload using SFTP, or SCP
o SNMPv1/v2/v3
� Authentication or AAA Servers � Policy Servers; Authentication Servers such as RADIUS, LDAP, and ACE servers
� Policy-Based Management with LDAP Directory Services � System File Management � Dual image and dual configuration file storage provides backup
� Intuitive Alcatel-Lucent CLI for familiar interface and reduced training costs � WebView Element Mgmt: Easy to use point & click web based element manager with
built-in help for easy configuration of new technology features
� Remote telnet management or secure shell � Secured file upload using SFTP, or SCP
� Human readable ASCII based config files for offline editing and bulk configuration
� Managing Switch Users Accounts & Partitioned Management feature � Managing Switch Security
� IGMPv1/v2/v3 snooping to optimize multicast traffic
� BootP/DHCP client allows auto-config of switch IP information to simplify deployment � Auto-negotiating 10/100/1000 ports automatically configure port speed and duplex setting
� Auto MDI/MDIX automatically configures transmit and receive signals to support straight
thru and crossover cabling � DHCP relay to forward client requests to a DHCP server
� DHCP Option-82 & DHCP Snooping
� Integration with SNMP manager OmniVista for network wide management � System event log
� Network Time Protocol (NTP) for network wide time synchronization
� Alcatel-Lucent Interswitch Protocols (AIP) o AMAP: Alcatel-Lucent Mapping Adjacency Protocol (AMAP) for building
topology maps within OmniVista
o 802.1AB with MED Extensions / LLDP-MED � GVRP for 802.1Q-compliant VLAN pruning and dynamic VLAN creation
Configuration Mode Command Line Interface (CLI), Telnet/SSH for remote CLI access, Web-based (HTTP/HTTPS)
and SNMPv1/v2c/v3 for complete NMS integration
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Management Access types Seriral & In-band
• Serial Console port for local & remote (modem dial up) access (RJ45) Console Port / Serial Connection: The console port, located on the chassis front panel, provides a console connection to the switch
and is required when logging into the switch for the first time. By default, this RJ-45 connector provides a DTE console connection.
• In-band Ethernet access
System Maintenance Port Mirroring (one-to-one, many-to-one) RMON (Remote Monitoring): Statistics, History, Alarm & Events, and sFlow
Local & Remote logging (Syslog)
Detailed Statistics / Alarm / Debug information per process L3 OAM (ICMP Ping and Traceroute)
NTP (Network Time Protocol)
Internal flash to feature:
• Working Directory
• Certified Directory
System file Transfer XModem and FTP (File Transfer Protocol) / SFTP (Secure FTP) / SCP
Max number of users in local database 65
Max number of users in LDAP/RADIUS/ACE Server
database (depends on server capabilities)
Greater than 1000
Max number of SNMP users (login) 50
Max number of simultaneous SNMPv3 requests 50
Max number of simultaneous HTTP sessions 4
Max number of simultaneous Telnet sessions 4
Max number of simultaneous FTP sessions 4
Max number of simultaneous Syslog servers 4 concurrent sessions
Syslog to Multiple Hosts: You can send Syslog files to multiple hosts, up to a maximum of 4 servers.
Max number of simultaneous
SSH Telnet / FTP sessions
8
Max number of simultaneous User Login sessions 13
Max number of simultaneous Authentications
sessions (A-VLAN, A-ACL with RADIUS)
30
Max number of authenticated ports 48
Port Disable You can configure a “Port Disable” rule to administratively disable an interface when matching a
policy rule. To make the interface operational again, the port must be unplugged/plugged back or disabled/enabled using “interfaces s/p admin down” and “interfaces s/p admin up”.
Also, a SNMP trap will be sent when an interface goes down when matching a port disable rule.
SNMP Traps A “pktDrop’ SNMP trap will be sent out to the SNMP station when a port goes down because of a user-port shutdown profile or a port disable rule.
Port Monitoring The same unit cannot support both mirroring and monitoring configuration i.e. a user cannot have a
port monitoring and a port mirroring session on the same unit
Only one monitoring session at a time across the entire system Only the first 64 bytes of the packet can be monitored. Due to the port monitoring file size, the system
can only store the first 2K packets (i.e. 140K/64 = 2187) Enabling the monitoring function affects the performance. As every single monitored packet is enqueued to the CPU, the Q-Dispatcher has to de-queue and look at each and every packet to
determine if the destination is PMM (port monitoring module). The performance will be limited by the
efficiency of Q-Dispatcher de-queuing speed and also the speed at which PMM can get the packets from Q-Dispatcher through IPC. Due to the performance limitations, monitoring wire rate traffic is not
possible at this time.
The packets coming to CPU are always tagged and undergo the same FFP modifications as mirroring Port Monitoring not supported on Link Aggregation
Port Mirroring The N-to-1 port mirroring allows the user to specify multiple numbers of ports, range of ports as
mirrored source in a single command. However the maximum number of mirror source ports could be set to 128 for the current release. A user can mirror multiple 10GigE towards 1 port GigE. Of course if
more than 1 GigE of traffic we don't expect one to mirror more that the port can deliver
Aggregate ports are allowed to be mirrored on the physical ports. Mirroring on the logical link aggregated port ID is not supported.
In mirroring, the packet coming out of mirroring port may be different from the ingress packet, based
on the type of switching. For all types of mirroring, the mirrored packet carries the FFP (Fast Filtering Processor) modification, mirrored packet may get modified.
To mirror port 1/1 to port 1/4, you can choose the following options:
• In-port
• Out-port
• Bi-directional
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Port Mapping (AKA Private VLAN)
• Allows traffic segregation at L2
• User ports in the same session cannot talk to each other
Note: this feature is part of
“Residential bridging features”
Port Mapping is a security feature that controls peer users from communicating with each other. A Port Mapping session comprises a session ID and a set of user ports and/or a set of network ports. User
ports within a session cannot communicate with each other and can only communicate via network
ports. In a Port Mapping session with user port set A and network port set B, ports in set A can only communicate with ports in set B. If set B is empty, ports in set A can communicate with rest of the ports in the system. A port mapping session can be configured in unidirectional or bidirectional mode.
In the unidirectional mode, the network ports can communicate with each other within the same session. In the bidirectional mode, the network ports cannot communicate with each other. Network
ports of a unidirectional port mapping session can be shared with other unidirectional sessions, but
cannot be shared with any sessions configured in bidirectional mode. Network Ports of different sessions can communicate with each other.
Port Mapping Specifications:
Ports Supported: Ethernet (10 Mbps)/Fast Ethernet (100 Mbps)/Gigabit Ethernet (1 Gb/1000 Mbps) /10 Gigabit Ethernet (10 Gb/10000 Mbps).
Mapping Sessions: Eight sessions supported per standalone switch and stack.
Port Mapping Defaults: Mapping Session: Creation: No mapping sessions
Mapping Status configuration: Disabled
Port Mapping Direction: Bi-directional
SCP (Secure Copy) “SCP” command can be used to get/put the file from/to the server. The scp CLI command is available for copying files in a secure manner between hosts on the network.
The scp utility performs encrypted data transfers using the Secure Shell (SSH) protocol. In addition,
scp uses available SSH authentication and security features, such as prompting for a password if one is required. Since OS6800/OS6855 does not have any SCP-daemon running on the switch, therefore this feature only works when OS6800/OS6855 works as a client instead of the server. This feature has been
validated with SSH 4.0 on Solaris and Linux platforms. Since SSH 4.0 contains SCP, SFTP and SSH features, therefore the system allows the network administrator to create the local user database to
specify all domain or family of features (i.e. the family of feature that a user can have access). When a
user is being created, all allowed access need to be defined.
SFLOW SFlow is a network monitoring technology that gives visibility to the activity of the network, by
providing network usage information. It provides the data required to effectively control and manage
the network usage. SFlow is a sampling technology that meets the requirements for a network traffic monitoring solution.
SFlow is a sampling technology embedded within switches/routers defined in RFC 3176. It provides
the ability to monitor the traffic flows. It requires an sFlow Agent running in the Switch/Router and a sFlow collector which receives and analyses the monitored data.
SFlow agent running on the OS6855, combines interface counters and traffic flow (packet) samples on
all the configured interfaces into sFlow Datagrams that are sent across the network to an sFlow collector (3rd Party software). Packet sampling is done in hardware and is non-CPU intensive.
Current release does not support IPv6 as Collector.
The switch sends the first 128 bytes of the sampled packet from which the entire layer 2/3/4 information can be extracted by the receiver. This could include:
- Source/Destination Mac address - Source IP/ Destination IP - Source/Destination TCP/UDP/ICMP port
- Source/Destination Physical port (Gigabit Port)
- IPv4/IPv6 - RIP/OSPF/BGP/PIM-SM/DM (OK, but if this info. falls within the first 128Bytes of the packet)
- VLAN
- QoS 802.1Q, ToS and DiffServ (DSCP) - Data Payload (OK, but if this information falls within the first 128 Bytes of the packet)
- Others (If this information falls within the first 128 Bytes of the packet)
Given an IP Address the SFLOW sampling information can be sent to a Collector such as the InMon and/or the Crannog.
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SFLOW Back-off Algorithm Since the CPU of switch is involved in the datagram processing, there is a built in back-off algorithm which will automatically adjust the sampling rate in the case of CPU congestion on switch.
This back-off mechanism is not user-configurable in Release 6.1.3r01. If CPU is congested it
automatically continues to double the sampling rate, and will continue to do so up to a very low rate of 1 sample in 2147483647 (2exp31)-1. For a 1Gig interface, the bit rate is 1,000,000,000 bits per second. The back-off algorithm is designed to take effect when the sample rate exceeds 10 samples per second
on any interface. Since each sample is configured by default for 128bytes this is 10x128x8 or 10 samples/sec x 1024 bits/sample or 10x1024 bps
1Gbps / 10x1024 bps = 97656 sampling rate.
Sampling with all available slot/ports at 10G wire-rates on OS9000 and all ports at 1G on the OS6855 keep backing-off up to 2,147,483,647 and stay fixed at this value until the traffic generation is halted
or reduced. That is even running only one 1G interface at wire rate on the OS6855 will back-off to
2147483647 and stay at this (maximum, safe) sampling rate. Recommended sampling rates for various speeds at various load:
Sampling Rates
Link Speed Light Load
Medium
Load
Heavy
Load
10Mb/s 256 512 8192*
100Mb/s 512 1024 65536*
1Gb/s 1024 2048 Max*
10Gb/s 2048 4096 Max*
*8192 is the empirical value found in the lab for 10Mbs, 65536 for 100 Mbps
*Max: because the OS6855 always backs-off to a max sampling rate of 2147483647 for wire rate at
these rates. All other values are those recommended by Inmon. Whatever the configured sampling rate, the back-off mechanism will set the ‘meanskipcount’ higher or lower depending on what is the
‘unaffecting’ sampling rate for the CPU.
TACACS+ Supported platform: OS6800, OS6855, and OS9000
Release 6.1.3.R01 is the first release to support TACACS+ AAA. AOS implementation is based on the Tacacs+ Protocol: draft-grant-tacacs-02.txt, January 1997.
Overview:
ASA or Authenticated Switch Access to AOS OmniSwitch running 6.1.3.R01 can be configured to add servers and forward AAA requests to TACACS+. TACACS+ servers are configured similar to
RADIUS or LDAP servers; however, (MD5) encryption key is optional.
AAA authentication and accounting services must be configured to point to the desired TACACS+ server. It is possible to set authentication and authorization to one TACACS+ server and accounting
requests to a different server.
The number of configurable servers and fail over to second server is uniform across all AAA server types: Up to 4 servers can be configured and all queries will be sent to the 1st server only. If 1st server
is online and user exists on 2nd server, the result will be failed authentication. If the 1st server is down,
authentication and authorization requests will only be sent to “next available” server. If all servers are down, all logins will fail.
Different AAA services can be configured to query different authentication servers. All services may
use a common authentication protocol or mix of supported protocols: Telnet service may be configured to query RADIUS while http/ftp may be configured to query TACACS+. Or all may query RADIUS.
Or all may query TACACS+. In all cases accounting server protocol must match authentication/authorization server protocol.
AOS TACACS+ does not support authentication for network or windows domain access. Only AOS
switch access with Partition Management type domain family attribute/value pairs is supported. This to say different users or groups of users may be assigned various levels of AOS switch
management privileges.
The TACACS+ servers run as an external server on Unix or Windows. We have tested with CISCO TACACS+ freeware for Unix and Cisco’s Secure ACSv4.0 TACACS+ uses TCP instead of UDP. Each login and supported command is queried back to the server
for authorization. TACACS+ configuration is fully supported with AOS WebView.
Notes:
•Tacacs+ supports Authenticated Switch Access and cannot be used for user authentication. •Authentication and Authorization operations are combined together and cannot be performed
independently. This implies that when Tacacs+ authentication is enabled, Tacacs+ authorization is also
enabled. Disabling Tacacs+ authentication automatically disables authorization. •A maximum of 50 simultaneous Tacacs+ sessions can be supported, when no other authentication
mechanism is activated. This is a limit enforced by the AAA application.
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Source Learning Source Learning Transparent bridging relies on a process referred to as source learning to handle traffic flow. Network
devices communicate by sending and receiving data packets that each contains a source MAC address
and a destination MAC address. When packets are received on switch network interface (NI) module
ports, source learning examines each packet and compares the source MAC address to entries in a MAC address database table. If the table does not contain an entry for the source address, then a new
record is created associating the address with the port it was learned on. If an entry for the source
address already exists in the table, a new one is not created. Packets are also filtered to determine if the source and destination address are on the same LAN
segment. If the destination address is not found in the MAC address table, then the packet is forwarded to all other switches that are connected to the same LAN. If the MAC address table does contain a
matching entry for the destination address, then there is no need to forward the packet to the rest of the
network. Source learning builds and maintains the MAC address table on each switch. New MAC address table entries are created in one of two ways: they are dynamically learned or statically
assigned. Dynamically learned MAC addresses are those that are obtained by the switch when source
learning examines data packets and records the source address and the port and VLAN it was learned on. Static MAC addresses are user-defined addresses that are statically assigned to a port and VLAN.
Accessing MAC Address Table entries is useful for managing traffic flow and troubleshooting network
device connectivity problems. For example, if a workstation connected to the switch is unable to communicate with another workstation connected to the same switch, the MAC address table might
show that one of these devices was learned on a port that belonged to a different VLAN or the source MAC address of one of the devices may not appear at all in the address table.
Hardware Learning The ASIC is capable of Hardware Learning where the unknown source address of a packet could be learned by the ASIC without software intervention. The advantage of Hardware Learning is to
eliminate excessive flooding problem due to the slow learning rate of Software Learning. OS6855
supports both hardware and software source learning modes. Default Chassis source learning mode is Hardware Learning.
Default Chassis source learning mode is Hardware Learning. New CLI commands are available to
allow user a choice of switching back to Software Learning mode. Mode will also change when the user configures to be mobile, authentication, and/or LPS port.
Source Learning Specifications Source Learning RFCs supported 2674 - Definitions of Managed Objects for Bridges with Traffic Classes, Multicast Filtering and
Virtual LAN Extensions
Source Learning IEEE Standards supported 802.1Q - Virtual Bridged Local Area Networks 802.1D - Media Access Control Bridges
MAC Address Table entries Source learning builds and maintains the MAC address table on each switch. New MAC address table entries are created in one of two ways: they are dynamically learned or statically assigned.
Dynamically learned MAC addresses are those that are obtained by the switch when source learning examines data packets and records the source address and the port and VLAN it was learned on. Static
MAC addresses are user-defined addresses that are statically assigned to a port and VLAN.
In addition, Source Learning also tracks MAC address age and removes addresses from the MAC address table that have aged beyond the configurable aging timer value.
Accessing MAC Address Table entries is useful for managing traffic flow and troubleshooting network
device connectivity problems. For example, if a workstation connected to the switch is unable to communicate with another workstation connected to the same switch, the MAC address table might
show that one of these devices was learned on a port that belonged to a different VLAN or the source
MAC address of one of the devices may not appear at all in the address table. There are two types of source learning modes currently available: software and hardware. The software
mode performs all source learning using switch software. The hardware mode takes advantage of
hardware resources that are now available to perform source learning tasks. At the present time, it is possible to select the mode that is active for the chassis and/or a given set of ports.
By default, hardware source learning mode is active for the switch. The exception to this is that
hardware source learning is not supported on mobile or Learned Port Security (LPS) ports. As a result, only software source learning is performed on these types of ports.
Maximum number of learned MAC addresses per
switch (distributed MAC mode disabled)
16K
Maximum number of learned MAC addresses total for a stack of up to 8 switches
8K
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Using Static MAC Addresses Static MAC addresses are configured using the Mac-address-table command. These addresses direct network traffic to a specific port and VLAN. They are particularly useful when dealing with silent
network devices. These types of devices do not send packets, so their source MAC address is never
learned and recorded in the MAC address table. Assigning a MAC address to the silent device’s port creates a record in the MAC address table and ensures that packets destined for the silent device are forwarded out that port.
When defining a static MAC address for a particular slot/port and VLAN, consider the following:
• Configuring static MAC addresses is only supported on non-mobile ports.
• The specified slot/port must already belong to the specified VLAN. Use the vlan port default command to assign a port to a VLAN before you configure the static MAC address.
• Only traffic from other ports associated with the same VLAN is directed to the static MAC address slot/port.
• Static MAC addresses are permanent addresses. This means that a static MAC address
remains in use even if the MAC ages out or the switch is rebooted.
• There are two types of static MAC address behavior supported: bridging (default) or
filtering. Enter filtering to set up a denial of service to block potential hostile attacks. Traffic sent to or from a filtered
• MAC addr. is dropped. Enter bridging for regular traffic flow to or from the MAC addr.
• If a packet received on a port associated with the same VLAN contains a source address
that matches a static MAC address, the packet is discarded. The same source address on
different ports within the same VLAN is not supported.
• If a static MAC address is configured on a port link that is down or disabled, an asterisk
appears to the right of the MAC address in the show Mac-address-table command display. The asterisk indicates that this is an invalid MAC address. When the port link comes up,
however, the MAC address is then considered valid and the asterisk no longer appears next
to the address in the display.
MAC address aging timer 300 seconds by default
Source learning also tracks MAC address age and removes addresses from the MAC address table that have aged beyond the aging timer value. When a device stops sending packets, source learning keeps
track of how much time has passed since the last packet was received on the device’s switch port.
When this amount of time exceeds the aging time value, the MAC is aged out of the MAC address table. Source learning always starts tracking MAC address age from the time since the last packet was
received. By default, the aging time is set to 300 seconds (5 min) and is configured on a global basis. Note. The MAC address table aging time is also used as the timeout value for the Address Resolution
Protocol (ARP) table. This timeout value determines how long the switch retains dynamically learned
ARP table entries.
Selecting the Source Learning Mode There are two types of source learning modes currently available: software and hardware. The software mode performs all source learning using switch software. The hardware mode takes advantage of
hardware resources that are now available to perform source-learning tasks. At the present time, it is
possible to select which mode is active for the chassis and/or a given set of ports. By default, hardware source learning mode is active for the switch. The exception to this is that
hardware source learning is not supported on mobile or Learned Port Security (LPS) ports. As a result,
only software source learning is performed on these types of ports.
Using Static Multicast MAC Addresses (L2 Static Multicast)
Using static multicast MAC addresses allows you to send traffic intended for a single destination multicast MAC address to selected switch ports within a given VLAN. To specify which ports will
receive the multicast traffic, a static multicast address is assigned to each selected port for a given
VLAN. The ports associated with the multicast address are then identified as egress ports. When traffic received on ports within the same VLAN is destined for the multicast address, the traffic is forwarded
only on the egress ports that are associated with the multicast address.
When defining a static multicast MAC address for a particular port and VLAN, consider the following: • A MAC address is considered a multicast MAC address if the least significant bit of the most
significant octet of the address is enabled. For example, MAC addresses with a prefix of 01, 03, 05, 13,
etc., are multicast MAC addresses. • If a multicast prefix value is not present, then the address is treated as a regular MAC address and not
allowed when using the Mac-address-table static-multicast command.
• Multicast addresses within the following ranges are not supported: 01:00:5E:00:00:00 to 01:00:5E:7F:FF:FF & 01:80:C2:XX.XX.XX & 33:33:XX:XX:XX:XX
• Configuring static multicast addresses is only supported on non-mobile ports. • In addition to configuring the same static multicast address for multiple ports within a given VLAN,
it is also possible to use the same multicast address across multiple VLANs.
• The specified port or link aggregate ID must already belong to the specified VLAN. Use the vlan port default command to assign a port or link aggregate to a VLAN before you configure the static multicast address.
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Software Third Party Licenses and Notices The licenses and notices related only to such third party software are set forth below:
• Booting and Debugging Non-Proprietary Software
• The OpenLDAP Public License: Version 2.4, 8 December 2000
• Linux
• GNU GENERAL PUBLIC LICENSE: Version 2, June 1991
• University of California
• Carnegie-Mellon University
• Random.c
• Apptitude, Inc.
• Agranat
• RSA Security Inc.
• Sun Microsystems, Inc.
• Wind River Systems, Inc.
• Network Time Protocol Version 4
Capability Maturity Model (CMM) Alcatel-Lucent's Software Engineering Institute (SEI) Capability Maturity Model (CMM) rating for software processes meets the Level-2 (CMM-level-2) requirements.
The Ethernet software The Ethernet software is responsible for a variety of functions that support the Ethernet, Gigabit
Ethernet and 10Gigabit Ethernet ports on OmniSwitch 6855 Series switches. These functions include diagnostics, software loading, initialization, and configuration of line parameters, gathering statistics, and responding to administrative requests from SNMP or CLI.
OOmmnniiSSwwiittcchh 66885555 SSeerriieess –– IIEETTFF // IIEEEEEE SSttaannddaarrddss The OmniSwitch 6855 Series is fully compliant with the relevant industry standards to include the following:
For further references on these Standards, refer to: www.IEEE.com
For further references on these Standards, refer to: www.IETF.org
IEEE Ethernet OAM IEEE Standards Supported: IEEE 802.1ag–Connectivity Fault Management
IEEE 802.3ah–CSMA/CD Access Method and Physical Layer Specifications (Future Release)
IEEE 802.1D–Media Access Control (MAC) Bridges IEEE 802.1Q–Virtual Bridged Local Area Networks
IEEE 802.1ad/D6.0 (VLAN Stacking) IEEE Standards Supported: 802.1ad/D6.0 Standard for Local and Metropolitan Area Networks -
Virtual Bridged Local Area Networks - Amendment 4: Provider Bridges
IEEE 802.1ag Connectivity Fault Management
IEEE 802.1D-1998 STP - Bridging (Media Access Control Bridges)
IEEE 802.1D for the GVRP support IEEE Std. 802.1D - 2004, Media Access Control (MAC) Bridges
IEEE Draft Std. P802.1Q-REV/D5.0
IEEE 802.1p CoS/QoS
IEEE 802.1Q VLANs - Virtual Bridged local Area Networks
Draft Standard P802.1Q/D11 IEEE Standards for Local And Metropolitan Area Network: Virtual Bridged Local Area Networks, July 30, 1998
IEEE 802.1QinQ VLAN Stacking
IEEE 802.1s MSTP - Multiple VLAN Spanning Tree
IEEE 802.1t (MAC Reduction) MAC Reduction
IEEE 802.1x Security - Port-based Network Access (supplement to 802.1D)
Extended 802.1x Authenticated VLAN (multiple MAC, multiple VLANs per port)
IEEE 802.1x MIB – Port Access IEEE 802.1x MIB – Port Access is supported.
IEEE 802.1v Protocol VLANs
IEEE 802.1w RSTP - Rapid reconfiguration
IEEE 802.3 Carrier Sense Multiple Access with Collision Detection (CSMA/CD)
IEEE 802.3i 10BASE-T
IEEE 802.3ab The IEEE 802.3ab standard describes the specifications for the 1000BASE-T twisted-pair GigEth.
IEEE 802.3ac VLAN tagging
IEEE 802.3ad Link Aggregation (Dynamic)
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IEEE 802.3ae 10-Gigabit Ethernet
IEEE 802.3af Power over Ethernet (PoE)
IEEE 802.3ak 10Gbps XFP 10GBASE-CX4 type cables are compliant with IEEE 802.3ak
IEEE 802.3x Ethernet flow control IEEE 802.3x (programmable threshold) flow control: Release 6.3.1r01 does not currently support
IEEE 802.3x flow control.
IEEE 802.3u The IEEE 802.3u standard describes the specification 100BASE-TX, & 100BASE-FX Ethernet
IEEE 802.3z The IEEE 802.3z standard describes the specifications for the 1000BASE-X fiber optic Gigabit Eth.
IETF -- RFCs RFC 768 UDP
RFC 791 / 894 / 1024 /1349 IP & IP / Ethernet
RFC 792 ICMP
RFC 793 / 1156 TCP / IP & MIB
RFC 826 / 903 ARP & Reverse ARP
RFC 854 / RFC 855 Telnet & Telnet options
RFC 855 Telnet & Telnet options
RFC 894 IP & IP / Ethernet
RFC 896 Congestion Control
RFC 903 ARP & Reverse ARP
RFC 919 / 922 Broadcasting Internet Datagram
RFC 922 Broadcasting Internet Datagram
RFC 925 / 1027 Multi-LAN ARP / Proxy ARP; Statically configured ARP entries
RFC 950 Subnetting
RFC 951 Bootstrap Protocol (BootP)
RFC 959 / 2640 FTP
RFC 1027 Multi-LAN ARP / Proxy ARP; Statically configured ARP entries
RFC 1058 RIPv1
RFC 1024 IP & IP / Ethernet
RFC 1075 DVMRPv2
RFC 1112 IGMPv1
RFC 1122 Internet Hosts
RFC 1142 OSI IS-IS Intra-domain Routing Protocol
RFC 1151 RDP
RFC 1155 / 2578-2580 SMIv1 & SMIv2
RFC 1156 TCP / IP & MIB
RFC 1157 / 2271 SNMPv1
RFC 1191 Path MTU Discovery
RFC 1195 Use of OSI IS-IS for routing in TCP/IP & dual environments
RFC 1212 / 2737 MIB & MIB-II
RFC 1213 / 2011-2013 SNMPv2 MIB
RFC 1215 Convention for SNMP Traps
RFC 1253 / 1850 / 2328 OSPFv2 & MIB
RFC 1256 ICMP Router Discovery Messages
RFC 1269 / 1657 BGPv3&v4 MIB
RFC 1305 / 2030 NTPv3 & Simple NTP
RFC 1321 MD5
RFC 1349 IP & IP / Ethernet
RFC 1370 Applicability Statement for OSPF
RFC 1403 / 1745 BGP / OSPF Interaction
RFC 1493 Bridge MIB
RFC 1518 / 1519 CIDR
RFC 1519 CIDR
RFC 1534 Interoperation Between DHCP and BOOTP
RFC 1541 / 1542 / 2131 / 3396 / 3442 Dynamic Host Configuration Protocol (DHCP)
RFC 1542 Clarifications and Extensions for the Bootstrap Protocol
RFC 1573 / RFC 2233 / RFC 2863 Private Interface MIB
RFC 1587 / 3101 OSPF NSSA Option
RFC 1643 / RFC 2665 Ethernet MIB
RFC 1657 BGPv3&v4 MIB
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RFC 1701 & 1702 1701–Generic Routing Encapsulation (GRE)
1702–Generic Routing Encapsulation over IPV4 Networks
RFC 1722 / 1723 / 2453 / 1724 RIPv2 Protocol Applicability Statement & MIB
RFC 1724 (which obsoletes RFC 1389) RIPv2 MIB Extension
RFC 1745 BGP / OSPF Interaction
RFC 1757 (formerly 1271) / 2819 RMON & MIB
RFC 1765 OSPF Database Overflow is not currently supported.
RFC 1771-1774 / 2842 / 2918 / 3392 BGPv4
RFC 1789 Connectionless Lightweight X.5000 Directory Access Protocol
RFC 1798
RFC 1812 / 2644 IPv4 Router Requirements
RFC 1850 OSPF Version 2 MIB
RFC 1886 DNS for IPv6
RFC 1901, 1902, 1903, 1904, 1905, 1906, 1907 -SNMPv2c Management Framework
RFC 1908 -Coexistence and transitions relating to SNMPv1 and SNMPv2c
RFC 1965 BGP AS Confederations
RFC 1966 BGP Route Reflection
RFC 1997/1998 BGP Communities Attributes
RFC 2003 -IP Encapsulation within IP.
RFC 2011 SNMPv2 MIB
RFC 2012 SNMPv2 MIB
RFC 2013 SNMPv2 MIB
RFC 2030 NTPv3 & Simple NTP
RFC 2042 BGP New Attribute
RFC 2080 RIPng
RFC 2096 IP MIB
RFC 2104 HMAC Message Authentication
RFC 2131 / 3046 Dynamic Host Configuration Control (relay) DHCP / BootP Relay
RFC 2132 DHCP Options and BOOTP Vendor Extensions
RFC 2138 / 2865 / 2868 / 3575 / 2618 RADIUS Authentication & Client MIB
RFC 2139 / 2866 / 2867 / 2620 RADIUS
Note on RFC 2620: We support this RFC 2620 through our own Proprietary Private MIB. Although, the mapping between the RFC 2620 and our own Private MIB is not one-to-one, we do
support many common objects between the standard version and that of our own Private MIB.
RFC 2154 OSPF MD5 Signature
RFC 2228 SFTP
RFC 2233 Private Interface MIB
RFC 2236 / 2933 IGMPv2 (Snooping for layer-2 multicast switching) & MIB
RFC 2247 Using Domains in LDAP/X.500 Distinguished Names
RFC 2251 Lightweight Directory Access Protocol (v3)
RFC 2252 Lightweight Directory Access Protocol (v3): Attribute Syntax Definitions
RFC 2253 Lightweight Directory Access Protocol (v3): UTF-8 String Representation of Distinguished Names
RFC 2254 The String Representation of LDAP Search Filters
RFC 2255
RFC 2256 A Summary of the X.500 (96) User Schema for Use with LDAPv3
RFC 2271 SNMPv1
RFC 2284 PPP Extensible Authentication Protocol (EAP)
RFC 2292 / 2373 / 2374 / 2460 / 2462 IPv6
RFC 2328 (which obsoletes RFC1583 and RFC2178) OSPFv2
RFC 2338 / 3768 / 2787 Virtual Router Redundancy Protocol (VRRP) & MIB
RFC 2362 PIM-SM Protocol Specifications
RFC 2365 Administratively Scoped IP Multicast
RFC 2370 / 3630 The OSPF Opaque LSA Option
RFC 2385 BGP MD5 Signature
RFC 2439 BGP Route Flap Damping
RFC 2452 / RFC 2454 IPv6 TCP/UDP MIB
RFC 2453 RIPv2
RFC 2461 NDP
RFC 2463 / 2466 ICMPv6 & MIB
RFC 2464 / 2553 / 2893 / 3493 / 3513 IPv6
Note: RFC 2893 has been obsoleted by RFC4213.
RFC4213 is now supported, but it does not include
Automatic tunnels. Therefore, the main difference is that the new RFC4213 does not contain an
automatic tunneling capability.
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RFC 2474 / 2475 / 2597 / 3168 / 3246 DiffServ
RFC 2475 DiffServ
RFC 2548 Microsoft Vendor-specific RADIUS Attributes
RFC 2570 Version 3 of the Internet Standard Network Management Framework
RFC 2571 Architecture for Describing SNMP Management Frameworks
RFC 2572 Message Processing and Dispatching for SNMP
RFC 2573 SNMPv3 Applications
RFC 2574 User-based Security Model (USM) for version 3 of the Simple Network Management Protocol
(SNMPv3)
RFC 2575 View-based Access Control Model (VACM) for SNMP
RFC 2576 Coexistence between SNMP versions
RFC 2578, RFC 2579, and RFC 2580 SMIv1 & SMIv2
RFC 2597 DiffServ
RFC 2616 / RFC 2854 HTTP & HTML
RFC 2618 RADIUS Authentication & Client MIB
Note: We support this RFC 2618 through our own Proprietary Private MIB.
Although, the mapping between the RFC 2618 and our own Private MIB is not one-to-one, we do support many common objects between the standard version and that of our own Private MIB.
RFC 2620 RADIUS Accounting & Client MIB
Note: We support this RFC 2620 through our own Proprietary Private MIB.
Although, the mapping between the RFC 2620 and our own Private MIB is not one-to-one, we do support many common objects between the standard version and that of our own Private MIB.
RFC 2640 FTP
RFC 2644 Changing the Default for Directed Broadcast in Routers (complements IP router requirements)
RFC 2665 Ethernet MIB
RFC 2667 IP Tunnel MIB
RFC 2668 / RFC 3636 IEEE 802.3 MAU MIB
RFC 2674 Definitions of Managed Objects for Bridges with Traffic Classes, Multicast Filtering and Virtual LAN Extensions / VLAN MIB
RFC 2715 / 2932 Multicast Routing MIB
RFC 2727
RFC 2737 MIB & MIB-II
RFC 2740 OSPFv3 for IPv6
RFC 2763 Dynamic Hostname Exchange for IS-IS
RFC 2784 –Generic Routing Encapsulation (GRE)
RFC 2787 Definitions of Managed Objects for the Virtual Router Redundancy Protocol
RFC 2796 BGP Route Reflection
RFC 2809 Implementation of L2TP Compulsory Tunneling via RADIUS
RFC 2819 Remote Network Monitoring Management Information Base
RFC 2842 BGPv4
RFC 2863 Private Interface MIB
RFC 2865 Remote Authentication Dial In User Service (RADIUS)
RFC 2866 RADIUS Accounting & Client MIB
RFC 2867 RADIUS Accounting Modifications for Tunnel Protocol Support / Accounting & Client MIB
RFC 2868 RADIUS Attributes for Tunnel Protocol Support
RFC 2869/2869bits RADIUS Extensions
RFC 2882 Network Access Servers Requirements: Extended RADIUS Practices
RFC 2890 –Key and Sequence Number Extensions to GRE (extensions defined are not supported)
RFC 2893 IPv6/IPv4 Dual Stacks
Note: RFC 2893 has been obsoleted by RFC4213.
RFC4213 is now supported, but it does not include
Automatic tunnels. Therefore, the main difference is that the new RFC4213 does not contain an
automatic tunneling capability.
RFC 2918 BGPv4
RFC 2924 Accounting Attributes and Record Formats
RFC 2932 IPv4 Multicast Routing MIB
RFC 2933 IGMP MIB
RFC 2934 PIM MIB for IPv4
RFC 2975 Introduction to Accounting Management
RFC 2989 Criteria for Evaluating AAA Protocols for Network Access
RFC 3046 Dynamic Host Configuration Control (relay) DHCP / BootP Relay
RFC 3056 IPv6 Tunneling
RFC 3060 Policy Core
RFC 3065 BGP AS Confederations
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RFC 3101 The OSPF Not-So-Stubby Area (NSSA) Option
RFC 3168 DiffServ
RFC 3176 RFC 3176 is for sFlow support
RFC 3246 DiffServ
RFC 3289 The RFC 3289 (DiffServ-MIB) IS NOT SUPPORTED.
RFC 3376 (IGMPv3) Snooping for layer-2 multicast switching
RFC 3392 BGPv4
RFC 3396 Dynamic Host Configuration Protocol (DHCP)
RFC 3411 SNMPv3
RFC 3412 SNMPv3
RFC 3413 SNMPv3
RFC 3414 SNMPv3
RFC 3415 SNMPv3
RFC 3416, RFC 3417, and RFC 3418 SNMPv2c
RFC 3442 Dynamic Host Configuration Protocol (DHCP)
RFC 3542 / RFC 3587 IPv6
RFC 3569 An Overview of Source-Specific Multicast (SSM)
RFC 3575 RADIUS Authentication & Client MIB
RFC 3623 Graceful OSPF Restart
RFC 3635 Pause Control
RFC 3636 IEEE 802.3 MAU MIB
RFC 3768 (which obsoletes RFC2338) Virtual Router Redundancy Protocol (VRRP) & MIB
RFC 4443/ 4293 ICMPv6 & MIB
RFC 4541 RFC 4541 Considerations for Internet Group Management Protocol (IGMP) and Multicast Listener
Discovery (MLD) Snooping Switches
Service & Support, Integration & Installation Alcatel-Lucent is fully committed to providing a comprehensive range of services and programs in support
of its vast array of products. Alcatel-Lucent’s ecosystem of more than 1,500 partners helps ensure that solutions will be installed,
integrated, fully supported and maintained according to Alcatel-Lucent’s high standards, following global
best practices. Alcatel-Lucent’s Accreditation Program ensures that its partners are fully trained on the latest technologies and techniques to meet and support customer requirements.
Technical Support
An Alcatel service agreement brings your company the assurance of 7x24 no-excuses technical support. You’ll also receive regular software updates to maintain and maximize your Alcatel product’s features and
functionality and on-site hardware replacement through our global network of highly qualified service
delivery partners. Additionally, with 24-hour-a-day access to Alcatel’s Service and Support web page, you’ll be able to view and update any case (open or closed) that you have reported to Alcatel’s technical
support, open a new case or access helpful release notes, technical bulletins, and manuals.
SUPPORTbasic 7 X 24 Technical Response Center (7x24 phone support)
Includes e-service web access, software releases and repair and return of hardware to be completed in 10
business days from receipt for same version only. Excludes NMS & Authentication Services software.
SUPPORTplus
hardware support
Includes 7X24 phone support, software releases for same version only, e-service web access, advance shipment for next business day arrival of replacement hardware. Excludes NMS & Authentication Services
software.
SUPPORTtotal hardware support
Includes 7X24 phone support, software releases for same version only, e-service web access, same day 4-hour hardware replacement (labor & parts) 7 days a week 24 hours a day. Allow 30 days lead time from receipt of sales order. Excludes NMS & Authentication Services software.
Escalation Upon opening a case, customers will receive a case number and may review, update, or escalate support
cases on-line. Escalation process is based on the severity level of the issue per the definitions below. •Severity 1: Production network is down resulting in critical impact on business—no workaround
•Severity 2: Segment or Ring is down or intermittent loss of connectivity across network.
•Severity 3: Network performances are slow or impaired—no loss of connectivity or data. •Severity 4: Information or assistance on product feature, functionality, configuration, or installation.
Key Partners Alcatel-Lucent has created a partnering program that enables it to work with a set of vendors in order to
provide solutions that fall outside of its core competencies. Partnerships provide channels and customers a
catalog of product solutions that are easy to find, evaluate, buy, install, and operate.
Customer support / Professional Services Customer’s can access customer support 24 x 7 x 365 via toll free number or Internet. Professional services can be contracted to perform a variety of functions, including customer network
operations center management, network audits, security installation, network design, equipment staging,
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 88 Alcatel.Lucent-ESD
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configuration and installation, resident engineering, proof of concept, solutions development and
integration. Customers may take advantage of professional services with regard to customizing the network management system for optimal tuning in a multi-vendor environment. Professional Services also offers
Customer Network Operations Center Service, which proactively monitors the customer network and
responds to alarms and traps.
Customer Training Alcatel-Lucent offers instruction on its enterprise data products in a variety of modes – instructor-led training (ILT), computer-based training (CBT), web-based training (WBT), and customized
seminars/workshops/webinars. ILT is offered at several locations or on-site at customer locations. All
instructors are Alcatel-Lucent Certified Switch Instructors (ACSIs). This means they have attended all of the courses, completed all of the certifications and attended the
weeklong Train-the-Trainer program that includes a review of Alcatel-Lucent training policies, procedures,
and practices to assure consistent delivery of information around the world.
Warranty Service & Support Programs & End Of Life
Lifetime Support
Standard Warranty Support All Alcatel-Lucent's products come with a standard one-year warranty on hardware and a three-month
warranty on software.
Hardware DOA Warranty
If hardware fails within the first 30 days after delivery, call Alcatel-Lucent's Internetworking Division
Customer Service by 2:00 p.m. (Pacific Standard Time) and they will send a replacement part overnight.
One-year Hardware Warranty
After the first 30 days, call Alcatel-Lucent's Internetworking Division Customer Service for a Return
material Authorization (RMA) and ship the part back to them for factory repair. The repaired unit will be shipped back to you from our facility within 10 business days. Next day, advanced replacement is available
for a small expedited fee.
All-in-One Maintenance: All maintenance fix releases will be provided free of charge during the first 90 days.
Service & Support Programs & End Of Life (EOL)
In accordance with Alcatel-Lucent’s established Product Life Cycle policy, as well as its customer satisfaction policy, Alcatel-Lucent will honor its obligations to customers currently under warranty or with
valid purchased service agreements relating to a product line for five (5) years (Software: three (3) years
and Hardware: five (5) years) beyond the EOL (End Of Life) of a product line.
Lifetime Support
All versions of the stackable product families come with a Limited Lifetime Hardware Warranty, limited to
the original owner, and will be provided for up to five (5) years. Faulty parts will be replaced via a five (5) business days AVR (Advance Replacement) RMA.
Limited Lifetime Warranty does not apply to SFPs.
Hardware Warranty Hardware – Alcatel.Lucent warrants that, for the applicable warranty period of one (1) year for hardware
(a) Equipment shall, under normal use and service, be free from defects in material and workmanship, and (b) Equipment shall materially conform to Alcatel.Lucent’s specification therefore in effect on the date of
shipment. The warranty period applicable to any product shall be one (1) year from the date of shipment
except if Alcatel.Lucent performs installation Services for any Product, then the warranty period applicable to the product shall be one (1) year from the date Purchaser is deemed to have accepted the Product in
accordance with the Agreement. Hardware warranty only includes Standard Repair or Replacement of
Defective Parts (Standard R&R) support.
Lifetime Support
All versions of the stackable product families come with a Limited Lifetime Hardware Warranty, limited to
the original owner, and will be provided for up to five (5) years. Faulty parts will be replaced via a five (5) business days AVR (Advance Replacement) RMA.
Limited Lifetime Warranty does not apply to SFPs.
Software Warranty Software & Firmware – Alcatel.Lucent warrants that, for the applicable warranty period of ninety (90) days for software, (a) Software media shall, under normal use and service, be free from defects in material
and workmanship, and (b) Software shall materially conform to Alcatel.Lucent’s specification therefore in
effect on the date of shipment. However, Alcatel.Lucent makes no warranty that any software will operate uninterrupted or error free. Software warranty includes software bug fixes and patches. Software upgrades
and/or enhancements are not included as a part of Alcatel.Lucent’s warranty, but can be purchased
separately.
Life Span The Alcatel Product Life Span depends on many conditions in the market place and varies from platform to platform. Historically speaking, some platforms have been out in the market more than seven (7) years and
still continue to exist on our product portfolio, while others may have experienced shorter life spans.
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AAppppeeddiixx AA -- SSmmaallll FFoorrmm FFaaccttoorr PPlluuggggaabbllee ((SSFFPP MMSSAA))
OmniSwitch 6855 Series switches use both copper-based and fiber-based optical Small Form Factor Pluggable (SFP) transceivers.
SFPs are fully hot-swappable and are available for both short-reach and long-reach applications.
Copper-based and fiber-based optical SFPs can be mixed on the same module. Note: The information discussed in this section is not exhaustive and the original manufacturer’s fiber optics references must be consulted to obtain further information for proper design guidelines.
• The maximum “distance” supported with fiber optics transceivers will be influenced by the following factors:
o Specified fiber plants standards for cable wiring such as ISO/IEC-11801, TIA 568, IEEE 802.3u,
o IEEE 802.3z/1000BASE-SX/LX/LH…etc.
o Modal Bandwidth (measured in MHZ*km: such as 200 MHZ*km, or 160 MHZ*km…etc)
o Fiber quality
o Attenuation or dB of loss per km (Attenuation is a measure of the loss of signal strength or light power
that occurs as light pulses propagate through a run of multimode or single-mode fiber. Measurements are
typically defined in terms of decibels or dB/km.). This loss could result from patch panels, splicing,
optical connectors, optical joints…etc.
o The Optical Power Budget (OPB) in dB allowance
o The Optical Power Budget (in dB) provides the necessary optical signal range to establish a working
fiber-optic link. The OPB is allocated for the fiber-optic cable. The OPB is the available optical power
for a fiber optic link to accommodate fiber cable losses plus losses due to in-line connectors, splices,
optical switches, and to provide margin for link aging and unplanned losses due to cable plant
reconfiguration or repair.
o The worst-case Optical Power Budget in “dB” for a fiber optic link is determined by: The difference
between the minimum transmitters’ output optical power and the lowest receiver sensitivity.
o The best way to determine the “distance” being supported is to take an OTDR (Optical Time Domain
Reflecto-meter) measurement on the fiber cable plant. (These measurements must be made using the same
wavelength of light as the transceiver that will be installed.) This will indicate the amount of loss per intended
distance. If the loss is within the transceiver’s allowed power budget, the connection will work.
• Minimum “distance” requirements must be carefully considered.
• Alcatel-Lucent supports several “alternate” sources of fiber optics transceiver manufacturers for its switching and
routing line of products. Alcatel-Lucent strongly recommends compliance with the original manufacture’s fiber
optics specifications, and fiber optics design guidelines. Therefore, as a general rule, Alcatel-Lucent stays within
the boundaries of the original manufacturer’s specifications. Any deviations from the norm require further
evaluations and testing.
• The insertion loss parameter value for the MiniGBICs requires a very specific testing which is normally
performed by the original manufacturer, but usually is not stated in their specification documents and the value
may vary from one manufacturer to another. Here at Alcatel-Lucent, our engineering normally does not carry out
such testing and therefore we rely on our approved manufacturer specifications data. Essentially, the original
manufacturer upon request must supply this specific parameter value. It is not anywhere in their specification
sheets. Here is what our Engineering suggests to do: Instead of relying on the manufacture's data for the insertion
loss value, which also varies from one manufacturer to another, we suggest looking into the IEEE Standard
Document. No matter what, all manufacturers must comply with the IEEE Standard. All of our MiniGBICs
comply with the IEEE 802.3z. You can easily look up the insertion loss parameter and its value for our
MiniGBICs in this document.
HHaannddlliinngg FFiibbeerr aanndd FFiibbeerr OOppttiicc CCoonnnneeccttoorrss
Using fiber is extremely simple, but several important standards should always be practiced. For best results, you should:
• Use premium grade jumper cables with duplex LC connectors
• Keep your fiber optic connectors clean
• Keep the transceiver interface clean
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• Attenuate properly Use Premium Grade Jumper Cables with Duplex LC Connectors
There are many brands of fiber optic jumper cables, with a wide range of quality between each manufacturer.
Premium cables do three things well:
• They provide a good polish on the fiber optic connector end-face (where the light exits the cable).
• End-face geometries must be exceptionally precise and aligned to extremely tight tolerances. The better the end-
face geometry, the lower the loss and more consistent the connection. Poor connector interfaces will reflect light
back into the laser, causing an increase in laser noise.
• They mate well with other connector interfaces. Chances are the manufacturer of the jumper cable will not be the
same as the manufacturer of the transceiver connector interface. Premium jumper cables mechanically align
themselves well into most transceiver interfaces. This provides both better performance as well as better
repeatability. You will always see a variance in transceiver power due to connector alignment, often as much as
0.3 to 0.7 dB. Good jumper cables help reduce this variance.
• They continue to mate well after many insertions and removals. Premium grade jumper use premium connectors
that maintain their mechanical integrity up to and beyond 2000 insertion cycles
For better repeatability, always use duplex (two connectors fused together and terminated to two cables) LC connectors on
your jumper cables when connecting to a fiber-optic transceiver. Two simplex connectors inserted into a transceiver
interface will often have up to 3 dB greater variations in repeatability compared to duplex connectors.
Never bend the fiber optic cable beyond its recommended minimum bend radius. This introduces bend losses and
reflections that will degrade the performance of your system. It can also damage the fiber, although fiber is much tougher
than most would assume. Still, it is highly recommended to buy only jumper cables with 3mm Kevlar jacketing, which
offer superior protection and longer life.
Keep Your Fiber Optic Connectors Clean
Unlike electrical connectors, fiber-optic connectors must be extremely clean in order to ensure optimum system
performance. Microscopic particles such as dust on the connector end-face (i.e., where the light exits the connector) can
degrade the performance of your system, often to the point of failure.
If you have low-power output from a fiber-optic transceiver or a fault signal from your equipment, begin the
troubleshooting process by cleaning your fiber-optic connectors per manufacturer recommendations.
Keep the Transceiver Interface Clean
If you have cleaned your connectors, but still experience low-power output from a fiber-optic transceiver or a fault signal
from your equipment, you should clean the transceiver interface by blowing inert dusting gas inside the transceiver
interface. This removes dust and other small particles that may block the optical path between the optics of the transceiver
and the connector’s end-face.
Attenuate Properly
Often, equipment using laser-based transceivers need to have the optical path attenuated when performing loop-back
testing or testing between two pieces of equipment. Too much optical power launched into the receiver will cause
saturation and result in system failure. If you are using single mode fiber and you do not know the power output of the
laser, it is always best to use a 10 dB attenuator when testing. Using the wrong type of attenuator will introduce problems,
most notably reflection of light back into the laser, often resulting in excess noise and causing system failure.
Inline attenuators eliminate the need for additional jumper cables and thus reduce the number of connection interfaces.
This increases the integrity of the optical path resulting in a more accurate test.
SFP MSA Specifications
• SFP-MSA Connector: The SFP connector consists of a 20-pin receptacle and a SFP housing cage. The 20-pin connector provides the
interface for the hot Pluggable SFP module. Each SFP module contains a serial interface to provide identification information that
describes the SFP capabilities, standard interfaces, manufacturer and other information.
• LC Connector: The LC connector is a fiber-optic cable connector that uses one-half the size of current industry standards. It
increases panel density and provides duplex connection in 50% less space with duplex fits of RJ-45 footprint. It is available in SM,
MM versions with Super, Ultra and Angle (APC) polishing. It provides a user-friendly audible latch to indicate proper mating and
supports pull – proof.
Notes:
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 91 Alcatel.Lucent-ESD
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• *The worst-case Optical Power Budget in “dB” for a fiber optic link is determined by:
The difference between the minimum transmitters output optical power and the lowest receiver sensitivity.
• Alcatel-Lucent switching & routing platforms support alternate sources of fiber-optics vendors, which are subject to change from
time to time. Please be sure to contact Alcatel-Lucent Internetworking Product Marketing for a complete list of approved vendors.
• The following fiber optics transceivers specifications have been taken from Alcatel-Lucent IP Networking approved vendor’s original
Specification Sheets.
AAppppeennddiixx BB -- PPiinn--OOuuttss
RRJJ--4455 CCoonnssoollee PPoorrtt –– CCoonnnneeccttoorr PPiinnoouuttss
Pin Number Description (Signals as DCE Console Port)
1 CTS
2 NC
3 RXD
4 Ground
5 Ground
6 TXD
7 NC
8 RTS (Request to Send)
Shell Chassis Ground
RRJJ--4455 CCoonnssoollee PPoorrtt –– CCoonnnneeccttoorr PPiinnoouuttss
Pin Number Description (Signals as DTE Console Port)
1 NC
2 NC
3 RXD
4 Ground
5 Ground
6 TXD
7 & 8 NC
Shell Chassis Ground
1100//110000MMbbppss EEtthheerrnneett PPoorrtt RRJJ--4455 PPiinnoouuttss ((NNoonn--PPooEE))
Pin Number Description
1 RX+
2 RX-
3 TX+
4 Not used
5 Not used
6 TX-
7 & 8 Not used
PPoowweerr oovveerr EEtthheerrnneett PPoorrtt ––RRJJ--4455 PPiinnoouuttss ((wwiitthh PPooEE))
Pin Number Description
1 RX+ (-VDC)
2 RX- (-VDC)
3 TX+ (+VDC)
4 & 5 -----
6 TX- (+VDC)
7 & 8 -----
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 92 Alcatel.Lucent-ESD
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11 GGiiggaabbiitt EEtthheerrnneett PPoorrtt RRJJ--4455 PPiinnoouuttss ((NNoonn--PPooEE))
Pin Number Description
1 BI_DB+
2 BI_DB-
3 BI_DA+
4 BI_DD+
5 BI_DD-
6 BI_DA-
7 BI_DC+
8 BI_DC-
1100//110000//11000000MMbbppss PPoowweerr oovveerr EEtthheerrnneett PPoorrtt --RRJJ--4455 PPiinnoouuttss
Pin Number Description
1 RX+ (-VDC)
2 RX- (-VDC)
3 TX+ (+VDC)
4 N/C
5 N/C
6 TX- (+VDC)
7 N/C
8 N/C
CCoonnssoollee PPoorrtt // SSeerriiaall CCoonnnneeccttiioonn DDeeffaauulltt SSeettttiinnggss
The console port, located on the chassis front panel, provides a console connection to the switch and is required when
logging into the switch for the first time. By default, this RJ-45 connector provides a DTE console connection.
The factory default settings for the serial connections are as follows:
Baud rate 9600
Parity None
Data bits (word size) 8
Stop bits 1
Flow Control None
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 93 Alcatel.Lucent-ESD
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OOSS66885555 DDBB--2255 PPppoowweerr CCoonnnneeccttiioonn PPIINN--OOUUTT
Pin Number Description Pin Number Description
OS6855 PoE Models OS6855 Non-PoE Models
1 -50V 1 N/C
2 -50V 2 N/C
3 -50VRTN 3 N/C
4 -50VRTN 4 N/C
5 N/C 5 N/C
6 +12V 6 +12V
7 +12V 7 +12V
8 +12V 8 +12V
9 GND 9 GND
10 GND 10 GND
11 PS_ALTER 11 PS_ALTER
12 PS_GOOD 12 PS_GOOD
13 PS_PRESENT 13 PS_PRESENT
14 -50V 14 N/C
15 -50V 15 N/C
16 -50VRTN 16 N/C
17 -50VRTN 17 N/C
18 N/C 18 N/C
19 +12V 19 +12V
20 +12V 20 +12V
21 GND 21 GND
22 GND 22 GND
23 GND 23 GND
24 PS_TYPE0 24 PS_TYPE0
25 PS_TYPE1
25 PS_TYPE1
Note: This the pin-outs for the external power supplies DB-25 connectors as located on the rear panel of OmniSwitch 6855 24 port platforms (as
applicable). There are three DB-25 connectors. These connectors are used for connecting the appropriate power supply (s) to the OmniSwitch 6855 unit.
AAppppeennddiixx CC -- MMTTBBFF CCaallccuullaattiioonn SSttaannddaarrddss aanndd RReeqquuiirreemmeennttss
MTBF Notes:
• One MTBF-Yr. = 8,760 MTBF-Hrs.
• MTBF Prediction was based on Bellcore Handbook Technical Reference TR-332, Issue 6, Method I, and Case 3.
• M.S.R. 5: Mission Success Rate (%) for 5 years (43,800 Hours) without failure.
• M.S.R. 1: Mission Success Rate (%) for 1 year (8,760 Hours) without failure.
• All MTBF calculations are performed at 25ºC Ground Benign
1. PURPOSE
The purpose of this section is to specify the basic standards and requirements for the MTBF calculations of all the
products of Alcatel’s Network Infrastructure Business Unit (NIBU).
2. RELIABILITY PREDICTION
PIN 13
PIN 14 PIN 25
OS6855 Series Boilerplate Doc. Rev.—2.1a / Nov. ‘09 Page 94 Alcatel.Lucent-ESD
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A reliability prediction is simply the analysis of parts and components in an effort to predict and calculate the rate at which
an item will fail. Reliability predictions provide a quantitative basic for evaluating product reliability. A reliability
prediction is one of the most common forms of reliability analyses for calculating failure rate and MTBF.
3. MTBF DEFINITION
There are many forms of the MTBF definition. In general, MTBF (Mean Time Between Failures) is the mean value of the
lengths of time between consecutive failures, under stated conditions, for a stated period in the life of a functional unit. A
more simplified MTBF definition for reliability predictions can be stated as the average time (usually expressed in hours)
that a component works without failure.
3.1 Limitations of Reliability Prediction
Like all engineering models, the failure rate models that used for MTBF calculations, are approximations to reality. Thus,
one should not treat a reliability prediction number for a product as an absolute prediction of its field failure rate. In
general, higher MTBF correlates with fewer component failures, but an MTBF claim is not a guarantee of product
reliability and does not represent a condition of warranty. It is generally agreed that these predictions can be very good
when used for relative comparisons, such as comparing design alternatives, or comparing products. Note also that
reliability predictions do not account for substandard quality control for purchased parts, bad workmanship, poor product
level quality control, overstressed field operation, etc.
4. MTBF CALCULATION STANDARDS
The two most popular MTBF calculation standards are Telcordia (Bellcore) and MIL-HDBK-217.
The MTBF calculations of all the NIBU products, even for the industrial and military specifications products, are based on
the Telcordia standard document number SR-332, Issue 1 (which is an update of the Bellcore Handbook Technical
Reference TR-332, Issue 6), since the Telcordia models are specifically designed and oriented to focus on the
telecommunications products.
Furthermore, the Telcordia models are also widely accepted in the telecom market; they seem to give much more realistic
results; they are much more up to date; they can handle larger gate count ICs much better; they are quicker and easier to
use, since the Telcordia models require many less part parameters than the MIL-HDBK-217 models.
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5. MTBF CALCULATION REQUIREMENTS
5.1 Bill of Materials
The Bill of Materials (BOMs) is normally used to calculate the MTBFs of all the ESD products.
5.2 MTBF Calculations
MTBF is a basic measure of reliability for repairable items. It can be described as the number of hours that pass before a
component, assembly, or system fails. It is a commonly-used variable in reliability and maintainability analyses.
MTBF can be calculated as the inverse of the failure rate for constant failure rate systems. For
Example: If a component has a failure rate of 2 failures per million hours, the MTBF would be the inverse of that failure rate:
MTBF = (1,000,000 hours) / (2 failures/million hours) = 500,000 hours
Thus, for an assembly with multiple components, the MTBF is calculated as the inverse of all the failure rates, as follows:
MTBF = 1 / (sum of all the part failure rates); or:
MTBF = 1 / (FR1 + FR2 + FR3 + ............ FRn)
Note: FR = Failure Rate
For a combination of multiple assemblies in SSeerriiaall MMooddee::
MTBF (Combined) = 1 (1/MTBF1 + 1/MTBF2 + 1/MTBF3 + …..+1/MTBFn)
To ease the complexity of the MTBF calculations, a reliability prediction program called RelCalc for Windows, Version 5.0-
BELL7 (Release 2004.1), produced by T-Cubed Systems, Inc. (http://www.t-cubed.com/), is used to calculate the MTBFs of all
the NIBU products, with Telcordia SR-332, Issue 1, Method I (Parts Count), Case 3, Environment GB (Ground Benign),
Correction Factor 1, 100% Duty Cycle, components Quality Level II and under an ambient temperature of 25°C.
5.3 Minimum MTBF Expectation
The minimum MTBF value for all NIBU products, including any module, unit or system is expected to be 43,800 hours (5 years).
Thus:
The minimum Mission Success Rate for 1 year (M.S.R. 1) = exp (-8760/43800) = 81.87%
The minimum Mission Success Rate for 5 years (M.S.R. 5) = exp (-43800/43800) = 36.79%
5.4 MTBF Calculation Results
A so called MTBF table is used to summarize the MTBF calculation results of all products. The MTBF table is periodically
updated to include the additional MTBF calculation results of new products. After each update, it will be sent out to interested
parties such as Engineering, Quality Assurance, Marketing and Sales departments. Beside the MTBF calculation results of each
product, the MTBF table also displays other results such as backplanes, fans, power supplies, PCBAs, fiber optic transceivers,
products with and without power supplies, products with and without fiber optic transceivers.
6. Additional Information
6.1 The History of the MTBF Standards
For electronic components, the two most popular and widely accepted reliability prediction handbooks are MIL-HDBK-217 and
Telcordia (Bellcore). These handbooks offer procedures for predicting electronic product reliability, providing a standard basis for
comparing reliability numbers.
6.2 MIL-HDBK-217
The original reliability prediction handbook was MIL-HDBK-217, the Military Handbook for “Reliability Prediction of
Electronic Equipment”. MIL-HDBK-217 (commonly referred to as 217) is published by the Department of Defense, based on
work done by the Reliability Analysis Center and Rome Laboratory at Griffiss AFB, NY.
The 217 handbook contains failure rate models for the various part types used in electronic systems, such as ICs, transistors,
diodes, resistors, capacitors, relays, switches and connectors.
These failure rate models are based on the best field data that could be obtained for a wide variety of parts and systems; this data
is then analyzed and massaged, with many simplifying assumptions thrown in, to create usable models.
The latest version of 217 is MIL-HDBK-217F, Notice 2 (217F2). A copy of MIL-HDBK-217F-2 can be obtained from any source
that provides Mil Specs, Mil Standards, Mil Handbooks, etc.
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6.3 Telcordia (Bellcore)
Bellcore was purchased by SAIC in 1997. The purchase agreement required Bellcore to change its name: Bellcore became
Telcordia Technologies in 1999. However, people still continue to use the Bellcore name in their documentation. Note that
Bellcore (Bell Communications Research, a spin-off of AT&T Bell Labs) was the research arm of the Bell Operating Companies.
Bellcore previously used MIL-HDBK-217 for their reliability predictions, but found that 217 gave pessimistic numbers for its
commercial quality products. A few years ago, Bellcore used 217 as a starting point, modified (and simplified) the models to
better reflect their field experience, and developed the Bellcore reliability prediction procedure, which is applicable to commercial
electronic products. A copy of the Telcordia document “Reliability Prediction Procedure for Electronic Equipment” (document
number SR-332, Issue 1) can be obtained directly from Telcordia Customer Service in New Jersey.
Many commercial electronic product companies, making products such as computers, telecommunications systems, medical
systems, and power supplies, are now choosing to use the Bellcore handbook for their reliability predictions.
6.4 Failure Rate Unit Conversions
Failure rate numbers can be expressed in many different units as shown in the following conversion equations.
Note that the FITs (Failures In Time) unit is failures per billion hours, and that the MTBF is in hours.
(Failures/million hours) = (1,000,000) / (MTBF)
(Failures/million hours) = (0.001) * (FITs)
(Failures/million hours) = (1000) * (failures/1000 hours)
(Failures/million hours) = (10) * (%failures/1000 hours)
(Failures/million hours) = (114.2) * (failures/year)
(Failures/million hours) = (1.142) * (%failures/year)
(FITs) = (1,000,000,000) / (MTBF)
(FITs) = (1000) * (failures/million hours)
(FITs) = (1,000,000) * (failures/1000 hours)
(FITs) = (10,000) * (%failures/1000 hours)
(FITs) = (114,200) * (failures/year)
(FITs) = (1142) * (%failures/year)
(MTBF) = (1,000,000) / (failures/million hours)
(MTBF) = (1,000,000,000) / (FITs)
6.5 MTBF Mission Success Rate
The Mission Success Rate (M.S.R.) is the probability that the circuit, including redundancy, will operate without failure for the
mission time. For example, if the Mission Success Rate = 0.999405, then the circuit has a probability of 99.94% of working
without a failure for the mission time duration.
Assuming that failures occur randomly during the useful life of a product, they can be described as an exponential distribution. So
the probability that a product will work for some time T without failure is given by:
R (T) = exp (-T/MTBF)
Thus, for a product with an MTBF of 250,000 hours, and an operating time of interest of 5 years (43,800 hours):
R = exp (-43800/250000) = 0.839289 = 83.93% (Mission Success Rate for 5 years = 83.93%)
This means that there is an 83.93% probability that the product will operate for the 5 years without a failure, or that 83.93% of the
units in the field will still be working at the 5 year point.
6.6 Serial and Parallel Mode MTBF Calculations
The following two typical model types are used to calculate the MTBFs of all the NIBU products:
• Serial Mode MTBF Calculation
• Parallel Mode MTBF Calculation
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6.6.1 Serial Mode MTBF Calculation
The MTBF calculation under serial mode requires all of the parts in the circuit to function for success. In other words, the whole
assembly will be considered failed if only one single component failed. Under serial mode MTBF calculation, the MTBF
calculation result usually goes lower with additional components. The serial mode is normally used to calculate the
MTBFs of all the modules and systems, except redundancy configurations, with the following formula:
MTBF (Combined) = 1 (1/MTBF1 + 1/MTBF2 + 1/MTBF3 +…+ 1/MTBFn)
6.6.2 Parallel Mode MTBF Calculation
The MTBF calculation under parallel mode requires only 1 of the parts in the circuit to function for success. The parallel mode is
usually used to calculate the MTBFs of the units in redundancy mode, such as redundant power supplies or redundant chassis
management modules (CMMs). Under parallel mode MTBF calculation, the MTBF calculation result usually goes higher with
additional redundant units. There is no simple formula to calculate the MTBFs of the redundant modules or systems under parallel
mode. A reliability prediction program such as RelCalc for Windows is used instead to perform the MTBF calculations under
parallel mode.
6.7 MTBF and Other Related Terms
6.7.1 MTTF
MMTTTTFF ((MMeeaann TTiimmee ttoo FFaaiilluurreess)) is a basic measure of reliability for non-repairable systems items (such as fans). It is the mean
time expected until the first failure of a piece of equipment. MTTF is a statistical value and is meant to be the mean over a long
period of time and a large number of units. For constant failure rate systems, MTTF is the inverse of the failure rate. If the
failure rate is in failures/millions of failure hours, MTTF = 1,000,000/Failure Rate for components with exponential distributions.
Technically, MTBF should be used only in reference to repairable items, while MTTF should be used for non-repairable items.
However, MTBF is commonly used for both repairable and non-repairable items. The MTBF figures can be used for this purpose.
MTTF = 1 / (sum of all the part failure rates); or:
MTTF = 1 / (FR1 + FR2 + FR3 + ............ FRn)
Note: FR = Failure Rate
MTTF = (1,000,000) / (failures/million hours)
6.7.2 MMTTTTRR ((MMeeaann TTiimmee ttoo RReeppaaiirrss)) for our systems depends on the failure. Our systems are designed to recover from simple
failures, but our systems engineers can help our customers develop a fault tolerant network that would use a combination of local
spares, distributed inventories and advanced replacements to optimize the availability rating.
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6.7.3 Availability Calculations
Availability (Ai) is the probability that the system will be available when required, or the proportion of total time that the system
is available for use. If the repair time is very small compared to the MTBF time, then the availability of the system can approach
to 100%. Availability is typically specified in nines notation. For example: 3-nines availability corresponds to 99.9% availability.
5-nines availability corresponds to 99.999% availability.
The following table shows the relationship of the availability and the corresponding percentage and downtime:
Availability Availability Percentage Down Time per Year
1-nine 90% 36.5 days/year
2-nines 99% 3.65 days/year
3-nines 99.9% 8.76 hours/year
4-nines 99.99% 52.56 minutes/year
5-nines 99.999% 5.26 minutes/year
6-nines 99.9999% 31.54 seconds/year
The Availability can be calculated as:
Ai = MTBF / (MTBF + MTTR)
MTTR = Mean Time To Repair (average service or repair time in hours)
Example:
• With MTBF = 100,000 hours and MTTR = 4 hours
Ai = 100000 / (100000 + 4) = 0.999960001 99.99% (4-nines availability)
• With MTBF = 500,000 hours and MTTR = 4 hours
Ai = 500000 / (500000 + 4) = 0.999992 99.999% (5-nines availability)
AAvvaaiillaabbiilliittyy iiss ccaallccuullaatteedd aass:: MTTF / (MTTF + MTTR) or MTBF / (MTBF + MTTR)
CCoommmmeenntt oonn 44 xx 99’’ss aavvaaiillaabbiilliittyy oorr 9999..9999%% uuppttiimmee ccaarrrriieerr ggrraaddee aavvaaiillaabbiilliittyy ((AAvvaaiillaabbiilliittyy iinn %% ((eexx:: 110000..0000%%))))::
To achieve the highest levels of availability there must be cooperative efforts between Alcatel-Lucent and the customer, this
requires that in addition to device and network level capabilities, operational processes must also be in place across the many
facets of the network – hardware, software, applications, security, networking, backup systems, local spares and server farms.
Network management must be designed to maintain availability with automated features to prevent and resolve problems, and
incorporate security with ease of use to reduce human error and the associated downtime.
6.7.4 Spare Units Calculations
The Mission Success Rate (M.S.R.) calculation should be used to determine the spare units that a customer should acquire:
M.S.R (T) = exp (-T/MTBF)
Example:
• With 100 units that had an MTBF = 100,000 hours
M.S.R. for 1 year (8,760 hours) = exp (-8760/100000) = 91.61% ≈ 92%
M.S.R. for 5 years (43,800 hours) = exp (-43800/100000) = 64.53% ≈ 65%
This means that at the end of the first year, there is a probability that 92 units are still running with 8 units failed. Thus, the
customer needs to acquire about 8 spare units for the first year.
At the end of the 5th year, there is a probability that 65 units are still running with 35 units failed.
Thus, the customer needs to get about 35 units for their replacement.
However, some people prefer to use the following simpler method to calculate the spare units as an estimation figure:
Spare units in a period = (number of units) * (period in hours) / (MTBF in hours)
Example:
• With 100 units that had an MTBF = 100,000 hours
Spare units in 1 year (8760 hours) = (100 units) * (8760 hours) / 100000 hours = 8.76 units ≈ 9 units
Spare units in 5 years (43,800 hours) = (100 units) * (43800 hours) / 100000 hours = 43.80 units ≈ 44 units
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