ceragon fibeair-ip10 manual

FibeAir® RFU-C

Installation Guide

Part ID: BM-0133-0 Doc ID: DOC-00017708 Rev a.01

November 2008

Notice This document contains information that is proprietary to Ceragon Networks Ltd.

No part of this publication may be reproduced, modified, or distributed without prior written authorization of Ceragon Networks Ltd.

This document is provided as is, without warranty of any kind.

Registered TradeMarks Ceragon Networks® , FibeAir® and CeraView® are registered trademarks of Ceragon Networks Ltd.

Other names mentioned in this publication are owned by their respective holders.

TradeMarks CeraMapTM, ConfigAirTM, PolyViewTM, EncryptAirTM, CeraMonTM, EtherAirTM, and MicroWave FiberTM, are trademarks of Ceragon Networks Ltd.


Statement of Conditions The information contained in this document is subject to change without notice.

Ceragon Networks Ltd. shall not be liable for errors contained herein or for incidental or consequential damage in connection with the furnishing, performance, or use of this document or equipment supplied with it.

Information to User Any changes or modifications of equipment not expressly approved by the manufacturer could void the user’s authority to operate the equipment and the warranty for such equipment.

Copyright © 2008 by Ceragon Networks Ltd. All rights reserved.

Corporate Headquarters: Ceragon Networks Ltd. 24 Raoul Wallenberg St. Tel Aviv 69719, Israel Tel: 972-3-645-5733 Fax: 972-3-645-5499 Email: [email protected] www.ceragon.com

European Headquarters: Ceragon Networks (UK) Ltd. 4 Oak Tree Park, Burnt Meadow Road North Moons Moat, Redditch, Worcestershire B98 9NZ, UK Tel: 44-(0)-1527-591900 Fax: 44-(0)-1527-591903 Email: [email protected]

North American Headquarters: Ceragon Networks Inc. 10 Forest Avenue, Paramus, NJ 07652, USA Tel: 1-201-845-6955 Toll Free: 1-877-FIBEAIR Fax: 1-201-845-5665 Email: [email protected]

APAC Headquarters: Ceragon Networks APAC (S'pore) Pte Ltd 100 Beach Road #27-01/03 Shaw Towers Singapore 189702 Tel.: 65 65724170 Fax: 65 65724199

Contents

Chapter 1 Installation .................................................................................... 1-1

General ................................................................................................................................ 1-1

Installation Components ................................................................................................... 1-2

1+0 Direct Mount Installation ............................................................................................ 1-3

1+1 Direct Mount Installation ............................................................................................ 1-5

1+0 Remote Mount Installation ......................................................................................... 1-8

1+1 Remote Mount Installation ....................................................................................... 1-10

Media Device (Antenna Mount) Losses ......................................................................... 1-13

Direct Mount for Nokia FlexiHopper Antennas ............................................................. 1-14

Antenna Connection ........................................................................................................ 1-15

Antenna Adapter .............................................................................................................. 1-16

Packing.............................................................................................................................. 1-17

Transportation.................................................................................................................. 1-17

Inspection ......................................................................................................................... 1-17

Chapter 2 Acceptance & Commissioning Procedures............................... 2-1

General ................................................................................................................................ 2-1

Site Acceptance Procedure............................................................................................... 2-2

1+0 Commissioning Procedure ........................................................................................ 2-7

1+1 Commissioning Procedure ........................................................................................ 2-9

2+0 XPIC Commissioning Procedure............................................................................. 2-12

FibeAir RFU-C Commissioning Log............................................................................... 2-15

Appendix A Frequency Information.............................................................A-1

General ................................................................................................................................A-1

RFU Frequency Bands.......................................................................................................A-1

6-8 GHz Frequency Channels ...........................................................................................A-8

Safety Precautions & Declared Material

Fiber Optic Line Precautions

Before turning on the equipment, make sure that the fiber optic cable is intact and is connected to the transmitter.

Do not attempt to adjust the laser drive current.

Do not use broken or non-terminated fiber optic cables/connectors or look straight at the laser beam.

ATTENTION: The laser beam is invisible!

The use of optical devices with the equipment will increase eye hazard.

CLASS 1 LASER PRODUCT

Complies with IEC 60 825-1:1993 + A1:1997 + A2:2001, and EN 60825-1:1994 + A1:1996 + A2:2001

General Equipment Precautions

Use of controls, adjustments, or performing procedures other than those specified herein, may result in hazardous radiation exposure.

When working with a FibeAir IDU, note the following risk of electric shock and energy hazard: Diconnecting one power supply disconnects only one power supply module. To isolate the unit completely, disconnect all power supplies.

Machine noise information order - 3. GPSGV, the highest sound pressure level amounts to 70 dB (A) or less, in accordance with ISO EN 7779.

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Safety Precautions & Declared Material (continued)

Static electricity may cause body harm, as well as harm to electronic components inside the device.

Anyone responsible for the installation or maintainance of the FibeAir IDU must use an ESD Wrist Strap.

ESD protection measures must be observed when touching the IDU.

To prevent damage, before touching components inside the device, all electrostatic must be discharged from both personnel and tools.

RoHS Compliance Declaration

电子信息产品有毒有害物质申明 Electronic Information Products Declaration of Hazardous/Toxic Substances

危害物质 Hazardous Substance

成分名称 Component 铅

Lead (Pb)

汞 Mercury

(Hg)

镉 Cadmium

(Cd)

六价铬 Hexavalent

Chromium (Cr VI)

多溴联苯 Polybrominated Biphenyls (PBB)

多溴二苯醚 Polybrominated Diphenyl Ethers

(PBDE)

单板 / 电路模块 PCB/Circuit Modules

Comply Comply Comply Comply Comply Comply

结构件 Mechanical Parts


电缆 Cables


Précautions de sécurité

Précautions relatives à la ligne à fibre optique

Avant de mettre l'équipement en marche, s'assurer que le câble à fibre optique est intact et branché à l'émetteur.

Ne pas essayer de régler le courant de commande du laser.

Ne pas utiliser de câble/connecteur à fibre optique cassé ou sans terminaison et ne pas regarder directement le faisceau laser.

ATTENTION : le faisceau laser est invisible !

L’utilisation de dispositifs optiques avec l'équipement augmente le danger pour les yeux.

PRODUIT LASER DE CLASSE 1

Conforme aux normes CEI 60 825-1:1993 + A1:1997 + A2:2001, et EN 60825-1:1994 + A1:1996 + A2:2001

Précautions générales relatives à l'équipement

L’utilisation de commandes ou de réglages ou l'exécution de procédures autres que celles spécifiées dans les présentes peut engendrer une exposition dangereuse aux rayonnements.

L’usage de FibeAir IDU s’accompagne du risque suivant d'électrocution et de danger électrique : le débranchement d'une alimentation électrique ne déconnecte qu'un module d'alimentation électrique. Pour isoler complètement l'unité, il faut débrancher toutes les alimentations électriques.

Bruit de machine d’ordre - 3. GPSGV, le plus haut niveau de pression sonore s'élève à 70 dB (A) au maximum, dans le respect de la norme ISO EN 7779.

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Sicherheitsmaßnahmen

Vorsichtsmaßnahmen bei faseroptischen Leitungen

Vergewissern Sie sich vor dem Einschalten der Anlage, dass das faseroptische Kabel unbeschädigt und mit dem Sender verbunden ist.

Versuchen Sie nicht, den Laser-Antriebsstrom zu regulieren.

Verwenden Sie keine defekten oder gespleißten faseroptischen Kabel/Stecker und sehen Sie nicht direkt in den Laserstrahl.

ACHTUNG: Der Laserstrahl ist unsichtbar!

Durch den Einsatz optischer Geräte zusammen mit der Anlage erhöht sich das Gesundheitsrisiko für die Augen.

LASERPRODUKT DER KLASSE 1

Entspricht den Normen IEC 60 825-1:1993 + A1:1997 + A2:2001 sowie EN 60825-1:1994 + A1:1996 + A2:2001

Allgemeine Vorsichtsmaßnahmen für die Anlage

Wenn andere Steuerelemente verwendet, Einstellungen vorgenommen oder Verfahren durchgeführt werden als die hier angegebenen, kann dies gefährliche Strahlung verursachen.

Beachten Sie beim Arbeiten mit FibeAir IDU das folgende Stromschlag- und Gefahrenrisiko: Durch Abtrennen einer Stromquelle wird nur ein Stromversorgungsmodul abgetrennt. Um die Einheit vollständig zu isolieren, trennen Sie alle Stromversorgungen ab.

Maschinenlärminformations-Verordnung - 3. GPSGV, der höchste Schalldruckpegel beträgt 70 dB(A) oder weniger gemäß EN ISO 7779.

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FibeAir® RFU-C Installation Guide 1-1

Chapter 1: Installation

General This guide provides installation procedures for FibeAir RFU-C:

About FibeAir RFU-C

RFU-C is a state-of-the-art Radio Frequency Unit which is fully software configurable and supports a broad range of capacities and interfaces.

The RFU supports low to high capacities for traditional voice and Ethernet services, as well as PDH/SDH/SONET or hybrid Ethernet and TDM interfaces.

This innovative platform uses an “on-the-fly” upgrade method, whereby network operators only buy capacity as needed, benefiting from savings on initial investments and OPEX.

Traffic capacity throughput and spectral efficiency are optimized with the desired channel bandwidth. For maximum user choice flexibility, channel bandwidths can be selected together with a range of modulations of from QPSK to 256 QAM.

High spectral efficiency is ensured using the same bandwidth for double the capacity, via two carriers, with vertical and horizontal polarizations. This feature is implemented by a built-in XPIC mechanism.

RFU-C works together with two types of indoor units. For PDH/SDH/SONET, the RFU works with the FibeAir 1500R indoor unit. For Ethernet, RFU-C works with the FibeAir IP-10 indoor unit. Together, FibeAir RFU-C and FibeAir 1500R/IP-10 IDUs provide a powerful, reliable, and comprehensive solution for a variety of wireless network scenarios and requirements.

RFU-C works with:

FibeAir 1500R FibeAir IP-10

RFU-C operating in co-channel dual polarization (CCDP) mode, using the cross polarization interference canceller (XPIC) algorithm, two carriers signals can be transmitted over a single channel, using vertical and horizontal polarization. This enables double capacity in the same spectrum bandwidth.

Required Tools

The following tools are required for the RFU-C installation:

Socket key wrench metric set

Adjustable wrench


Installation Components The following illustrations show the components involved in the installation procedures.

RFU-C

Coupler Holder with Coupler V/H Twist

Remote Pole Mount Kit


1+0 Direct Mount Installation

To install RFU-C in a direct mount 1+0 configuration, do the following:

1. If needed, change the antenna polarization by rotating the RFU-C in accordance with the relevant antenna installation guide.

Vertical Pole Horizontal Pole

2. Spread grease on the O-ring supplied with the antenna.

3. Place the O-ring in its location on the antenna transition.

4. Remove the sticker from the RFU-C antenna interface.

5. Mount the RFU-C on the antenna according to the system configuration, and make sure that the twist is set for the desired polarization (horizontal or vertical).


6. Insert four screws and washers provided with the kit, and tighten them.


1+1 Direct Mount Installation To install RFU-C in a direct mount 1+1 configuration, do the following:

1. If needed, change the antenna polarization according to the relevant antenna installation guide.

2. Spread grease on the two O-rings supplied with the kit and place them in their locations.

3. Mount the twist on the coupler according to the relevant antenna polarization (as shown in the illustrations below), using four screws and washers supplied with the kit.


4. Spread grease on the O-ring supplied with the antenna.

5. Place the O-ring on the antenna transition.

6. Mount the coupler holder on the antenna using the screws and washers supplied with the kit.

7. Spread grease on the O-rings supplied with the holder coupler kit.

8. Place one O-ring on each side of the coupler.

9. Remove the sticker from both RFU-C antenna interfaces.

10. Mount both RFU-Cs on the holder coupler.

11. For each RFU-C, insert four screws and washers, and tighten them, as shown in the following illustration.


1+0 Remote Mount Installation 1. Mount the Ceragon remote mount device on the pole, as shown in the following illustration.

2. Remove the sticker from the RFU-C antenna interface.

3. Mount the RFU-C on the Ceragon remote mount device.

4. Insert four screws and washers, and tighten them.

5. Spread grease on the O-ring supplied with the flexible waveguide.


6. Place the O-ring in the flexible waveguide flange groove.


8. Place the O-ring in the other end of the flexible waveguide flange groove.

9. Mount the flexible waveguide on the antenna, and tighten the screws and washers.

6-13 GHz

15-38 GHz


1+1 Remote Mount Installation 1. Mount the Ceragon remote mount device on the pole.

2. Mount the coupler holder on the Ceragon remote mount device using the screws and washers supplied with the kit.


3. Spread grease on the O-rings supplied with the coupler holder kit.

4. Remove the sticker from both RFU-C antenna interfaces.

5. Place one O-ring on each side of the coupler.

6. Mount both RFU-Cs on the coupler holder.

7. For each RFU-C, insert four screws and washers, and tighten them.


9. Place the O-ring in the flexible waveguide flange groove.

10. Mount the flexible waveguide on the Ceragon coupler, and tighten the screws and washers.


12. Place the O-ring in the other end of the flexible waveguide flange groove.

13. Mount the flexible waveguide on the antenna, and tighten the screws and washers.


Mediation Device (Antenna Mount) Losses

Per Terminal Losses (dB) Configuration Mount Path

6-8 GHz 11 GHz 13-15 GHz 18 GHz 23-32 GHz 38 GHz

Direct - 0.1 0.1 0.1 0.1 0.1 0.1 1+0

Remote - 0.5 0.5 1.2 1.5 1.5 1.5

Main-Main 1.4 1.4 1.4 1.4 1.6 1.8 Direct Sec-Main,

Main-Sec 6 6 6 6 6 6

Main-Main 1.9 1.9 2.6 2.9 3.1 3.3 1+1 HSB

Remote Sec-Main, Main-Sec 6.5 6.5 7.2 7.5 7.5 7.5

2+0 XPIC Remote - 0.5 0.5 1.2 1.5 1.5 1.5

Notes: 1. The antenna interface is always the RFU-C interface.

2. If other antennas are to be used, an adaptor with a 0.1 dB loss should be considered.

Loss (dB) Item

6-8 GHz 11 GHz 13-15 GHz 18-32 GHz 38 GHz

Flexible Waveguide 0.5 0.5 1.2 1.5 1.5

Main Coupler 1.4 1.4 1.4 1.5 1.5

Secondary Coupler 6 6 6 6 6

Twist 0 0 0 0 0

Note: The numbers above are typical losses per component.


Direct Mount for Nokia FlexiHopper Antennas RFU-C can be directly mounted on a Nokia FlexiHopper 6-38 GHz, 1-6 ft antenna, in 1+0 and 1+1 configurations.

An adapter is used for the direct mount, as shown in the following illustration.

RFU-C to Nokia

FlexiHopper Antenna Adapter


Antenna Connection RFU-C uses Andrew, RFS and antennas Xian Putian,

The following catalog items should be used:

• Andrew: VHLP/HP series

• RFS: SB/SU series

• Xian Putian: WTG series

RFU-C can be mounted directly for all frequencies (6-38 GHz) using the following antenna types (for integrated antennas, specific antennas PNs are required):

• Andrew: VHLP series

• RFS: SB/SU series

• Xian Putian: WTG series

For remote mount installations, the following flexible waveguide flanges should be used (millimetric). The same antenna type (integrated) as indicated above can be used (recommended).

Other antenna types using the flanges listed in the table below may be used.

Frequency (GHz)

Waveguide Standard

Waveguide Flange

Antenna Flange

6 WR137 PDR70 UDR70

7/8 WR112 PBR84 UBR84

11 WR90 PBR100 UBR100

13 WR75 PBR120 UBR120

15 WR62 PBR140 UBR140

18-26 WR42 PBR220 UBR220

28-38 WR28 PBR320 UBR320

If a different antenna type (CPR flange) is used, a flange adaptor is required. Please contact your Ceragon representative for details.


Antenna Adaptor When mounting RFU-C on an antenna upon which a 1500P ODU (11-38 GHz) direct mount was installed previously, the following adaptor is required (frequency-dependent).

Antenna adaptor used when replacing 1500P ODU direct mount


Packing The equipment should be packed and sealed with moisture absorbing bags.

Transportation The equipment should be prepared for public transportation. The cargo must be kept dry during transportation, in accordance with ETS 300 019-1-2, Class 2.3.

It is recommended that the equipment be transported to the installation site in its original packing case.

If intermediate storing is required, the packed equipment must be stored in a dry and cool environment, and out of direct sunlight, in accordance with ETS 300 019-1-1, Class 1.2.

Inspection Check the packing lists and verify that the correct equipment part numbers and quantities are found in the packages that arrived.


Chapter 2: Acceptance & Commissioning Procedures

General This chapter provides Ceragon's recommended Acceptance and Commissioning Procedure for FibeAir RFU-C. Acceptance and commissioning should be performed after initial setup is complete.

The purpose of this procedure is to verify correct installation and operation of the installed link and the interoperability with customer end equipment.

Ceragon's Acceptance and Commissioning procedure includes the following stages:

Site Acceptance Procedure

Commissioning of radio link in a 1+0 configuration

Commissioning of radio link in a 1+1 configuration

Commissioning of radio link in a 2+0 XPIC configuration

The Site Acceptance Procedure is a checklist that summarizes the installation requirements of the site at which the products were installed.

The commissioning tests cover the required configuration information that should be recorded, and the tests that should be performed on the radio link in 1+0, 1+1 and 2+0 configurations.

Note: RFU-C works together with two types of indoor units. For SDH/SONET, the RFU works with the FibeAir 1500R indoor unit. For Ethernet, RFU-C works with the FibeAir IP-10 indoor unit.


Site Acceptance Procedure The purpose of the following procedures is to verify that all installation requirements were noted and checked. Following this procedure will ensure proper, long-lasting, and safe operation of the product.

The checklist below summarizes the installation requirements of the site.

SITE ACCEPTANCE CHECKLIST

1. SITE INFORMATION

Customer:

Radio model:

Site name:

Site code:

Radio link code:

Site address:

2. ANTENNA MOUNTING

Antenna mount type:

Mount is of sufficient height to clear local obstructions OK

Mount is safely positioned to not cause a safety hazard OK

Mount is secure and perpendicular OK

Mount is grounded as per site specifications OK

All steelwork is Galvanized or Stainless Steel as appropriate OK

3. ANTENNA

Antenna type (model and size):

Antenna is securely fixed to mount OK

Antenna is grounded as per site specifications OK

Antenna sway braces are installed correctly (where applicable) OK

Antenna Radome is securely fitted (where applicable) OK

Water drain plugs are fitted and removed, as appropriate OK

Antenna sealing O-Ring is properly fitted and not damaged OK

Antenna/Launch unit polarization is as per link requirements OK



(continued)

4. OUT-DOOR UNIT

Type of RFU mount: (Direct or Remote mount)

RFU is securely mounted to the antenna or pole OK

RFU is grounded as per installation instructions OK

RFU polarization is as per link requirements OK

RFU is installed properly and has no physical damage OK

For Remote-Mount Only:

Remote mount kit is securely mounted to the pole OK

Waveguide has no physical damage and connectors are sealed OK

All waveguide bolts are secured using washers and lock-washers, as appropriate OK

Flexible waveguide is secured to the pole OK

6. COAX CABLE

Overall cable length:

Cable type:

N-Type connectors assembled properly on the cable OK

Cable connected securely to RFU and IDU OK

Cable connector is weather-proofed (sealed) at the RFU OK

At the RFU, cable has a service/drip loop to prevent moisture from entering the connector OK

Cable is secured using suitable restraints to fixed points at regular intervals (0.5 m recommended) OK

Cable has no sharp bends, kinks, or crushed areas. All bends are per manufacturer specifications OK

Grounding/lightning protection is as per site specifications OK

Lightning protection type and model:

Cable point-of-entry to building/shelter is weather-proof OK

Cable ends are properly labeled OK



(continued)

7. WAVEGUIDE

WG type:

WG is connected securely to RFU and Antenna OK

WG connector is weather-proofed (sealed) at the RFU OK

At the RFU, the WG has a service/drip loop to prevent moisture from entering the connector OK

WG is secured using suitable restraints to fixed points at regular intervals (0.5 m recommended) OK

WG has no sharp bends, kinks, or crushed areas. All bends are per manufacturer specifications OK

WG ends are properly labeled OK

8. IN-DOOR UNIT

IDU is securely mounted to the rack OK

IDU is located in a properly ventilated environment OK

IDU fans are functional and air flow to the fans is not disrupted OK

IDU and rack are grounded as per site specifications OK

Traffic cables and connections are properly terminated as per manufacturer/cable instructions OK

All cabling is secured, tidy, and visibly labeled OK

9. DC POWER SUPPLY - Two Inputs

Measured DC voltage input to the IDU: (-40.5 to -60 VDC)

Power-Supply maximum current: (at least 3 Ampere)

Power-Supply is properly grounded OK

DC power backup type:

IDU DC connector is secure and the DC input leads are correctly terminated (no bare wires are visible) OK

IDU DC connector (+) and (GND) leads are shorted and GND is grounded OK

10. RACK INSTALLATION

Rack is mounted to the shelter floor with four screws OK

Rack is mounted to the shelter wall with two screws OK



(continued)

11. REMARKS/NOTES

12. GENERAL INFORMATION

Name:

Title:

Company:

Signature:

Site accepted by:

Date:

Name:

Title:

Company:

Signature:

Site approved by:

Date:

Site Acceptance Checklist Notes

The following notes provide important additional information about the Site Acceptance Checklist.

1. Antenna Mounting

Mounting pole is of sufficient height to clear local obstructions, such as parapets, window cleaning gantries, and lift housings.

Mounting Pole is of sufficient height, and is safely positioned, so as not to cause a safety hazard. No person should be able to walk in front of, or look directly into the path of the microwave radio beam. Where possible, the pole should be away from the edge of the building.

Mounting pole is secure and perpendicular. A pole that is not perpendicular may cause problems during antenna alignment.

Mounting pole is grounded as per site specifications. All operators and site owners have specific requirements regarding the grounding of installations. As a minimum, typical requirements are such that any metal structure must be connected to the existing lightning protection ground of the building. Where it extends beyond the 45 degree cone of protection of existing lightning conductors, additional lightning protectors should be installed.

All steelwork is Galvanized or Stainless Steel, as appropriate to prevent corrosion.


2. Antenna

Antenna is grounded as per site specifications. See the third point in the Antenna Mounting section above.

Antenna sway braces are fitted and installed correctly, where applicable. Typically, for an antenna of 1.2 m or larger, an extra sway brace is fitted to the mounting frame of the antenna. This sway brace should not be mounted to the same pole as the antenna, but should be installed directly back to the tower or an alternative point.

Antenna Water Drain Plugs are fitted and removed, where appropriate. Some antennas have moisture drain plugs installed at various points around the antenna. The purpose of these plugs is to allow any moisture that forms on the inside of the antenna or radome to drip out and prevent a pool within the antenna. Only the plugs at the bottom of the antenna, after installation, should be removed. All other plugs should be left in position.

3. RFU (Radio Frequency Unit)

The RFU is grounded as per installation instructions. See the third point in the Antenna Mounting section above.

The RFU polarization is as per link requirements and matches the polarization of the antenna.

4. Indoor Unit

The main traffic connections are correctly terminated and crimped as per cable and connector manufacturer instructions. All fiber optic patch leads should be routed carefully and efficiently, using conduits to prevent damage to the cables.

All other user terminations are secure and correctly terminated.

All labeling is complete as per site requirements. Labeling is specific to each customer. At a site with only one installation, labeling may be unnecessary. However, at sites with multiple installations, correct and adequate labeling is essential for future maintenance operations.

Typical labeling requirements include:

Antenna labels - for link identity and bearing RFU labels - for link identity, frequency, and polarization Coax cable labels - for link identity, close to the RFU, IDU, and either end of any joint IDU labels - for link identity


1+0 Commissioning Procedure

Scope This section describes the recommended commissioning tests for a FibeAir RFU-C radio link in a 1+0 configuration.

The purpose of the commissioning tests is to verify correct and proper operation of the product.

Commissioning Test The following tests should be performed on each installed link.

Link Verification

“Radio” LED on the IDM front panel is green, indicating the radio link is up.

Received Signal Level (RSL) is up to +/- 4 dB from the expected (calculated) level at both ends of the link.

Radio Bit Error Rate (BER) is 10E-11 or higher.

If working with ATPC, ATPC is operating as expected (RSL = reference level).

After connecting test equipment or end equipment to the line interfaces, all LEDs on the front panel of the IDM are green.

Line Interfaces Test

155 Mbps Interface - connect SDH/SONET/ATM test equipment to the 155 Mbps interface and verify error-free operation for at least 1 hour. Use a physical or software loop at the far end.

FE/GbE Interface - connect a Packet Analyzer to the Fast Ethernet interface and verify error-free operation (no packet loss) for at least 1 hour. Use a physical loop at the far end.

2 Mbps/1.5 Mbps - connect PDH test equipment to the E1/T1 interface and verify error-free operation for at least 1 hour. Use a physical or software loop at the far end.

Interoperability Verification

Connect customer end equipment to the line interfaces, and verify correct operation.

Further interoperability tests should be performed in accordance with the specific requirements of the connected end equipment.


Management Verification

Install CeraView element manager software on the PC, and launch the program.

Verify that you can manage the link and that you are able to perform changes to the link configuration (frequency channel, Tx power, system name, time & date, etc.) via CeraView.

Verify that CeraView reports the correct parameters when performing the above.

Verify that there are no active alarms on the link.

If the management station is located at a remote site (Network Operation Center), verify that the management station can manage the link and receive traps.

Loopback Operation

Perform line loopback, IDU loopback, RFU loopback, and Remote loopback, and verify that the system operates accordingly.


1+1 Commissioning Procedure

Scope This section describes the recommended commissioning tests for a FibeAir RFU-C radio link in 1+1 HSB (Hot Standby) and SD (Space Diversity) or FD (Frequency Diversity) configurations (internal protection).


Note that in this section:

Primary refers to the RFUs connected to the top-most antenna in an SD configuration.

Secondary refers to the RFUs connected to the bottom antenna in an SD configuration.

Commissioning Tests

The following tests should be performed on each installed link.

Link Verification

The following steps should be repeated for each of the four RFU combinations (Primary-Primary, Primary-Secondary, Secondary-Primary, Secondary-Secondary).

“Radio” LED on the IDM front panel is green, indicating the radio link is up.

Received Signal Level (RSL) is up to +/- 4 dB from the expected (calculated) level at both ends of the link.

Radio Bit Error Rate (BER) is 10E-11 or higher.

If working with ATPC, ATPC is operating as expected (RSL = reference level).

After connecting test equipment or end equipment to the line interfaces, all LEDs on the front panel of the IDM are green.

Line Interfaces Test

155 Mbps interface - connect SDH/SONET/ATM test equipment to the 155 Mbps interfaces using splitters, and verify error-free operation for at least 1 hour. Use physical loop between the splitters at the far end.

FE, GbE interface - connect a Packet Analyzer to the Fast Ethernet interfaces using an FE splitter, and verify error-free operation (no packet loss) for at least 1 hour. Use a physical loop at the far end.

2 Mbps/1.5 Mbps - connect PDH test equipment to the E1/T1 interfaces using splitters, and verify error-free operation for at least 1 hour. Use a physical loop between the splitters at the far end.


Switching Tests

Define each of the N channels as preferred (one at a time) for errorless switching to the +1 channel. The regular channel supports hitless switching to the +1 channel.

155 Mbps Interface

Connect SDH/SONET/ATM test equipment to the 155 Mbps interfaces using splitters. Use physical loop between the splitters at the far end. Verify that there are no alarms.

Perform the following switching tests from one IDM to the other, and verify the system switches automatically.

- Power: power off the active IDM

- Radio: disconnect the coax cable of the active IDM

- Line: disconnect the 155 Mbps line input of the active IDM

- Management: force a switch using CeraView

For diversity configurations, verify that each receiver is receiving its own signal, and then mute the active RFU. Verify that the receiver at the far end still receives from the diversity path. Verify that there are no errors in the test equipment.

FE, GbE Interface

Connect a Packet Analyzer to the Fast Ethernet interfaces using splitters. Use a physical loop between the splitters at the far end. Verify no alarms exist.





2/1.5 Mbps Interface

Connect PDH test equipment to the interfaces using splitters. Use a physical loop between the splitters at the far end. Verify no alarms exist.





Interoperability Verification

Connect the customer end equipment to the line interfaces and verify correct operation.

Further interoperability tests should be performed in accordance with the specific requirements of the connected end equipment.


Management Verification

Install CeraView element manager software on the PC and launch the program.

Verify that you can manage the link and that you are able to perform changes to the link configuration (frequency channel, Tx power, system name, time & date, etc.) via CeraView.

Verify that CeraView reports the correct parameters when performing the above.

Verify that there are no active alarms on the link.

If the management station is located a t a remote site (Network Operation Center), verify that the management station can manage the link and receive traps.


2+0 XPIC Commissioning Procedure

Scope

This section describes the recommended commissioning tests for a FibeAir RFU-C radio link in a 2+0 XPIC Co-Channel-Dual-Polarization configuration.


Important! Since operation of the XPIC system depends on correct installation, make sure the guidelines for XPIC system installation provided below are followed correctly.

XPIC Installation Guidelines

Antenna and RFU Installation

1. Install the dual polarization antenna and point it in the direction of the other site.

2. Install the two RFUs on a dual polarization antenna using the appropriate mounting kit, and mark the RFUs with V and H respectively.

IDU-RFU Cable Installation

1. Install two cables between the RFUs and the drawers (IDMs). Note that cable length difference should not exceed 10 meters.

2. Mark the cables with V and H respectively, and make sure V is connected to the right drawer and H is connected to the left drawer.

3. Mark the drawers respectively.

Antenna Alignment

1. Power up drawer V on both ends of the link and configure it to the desired frequency channel and maximum power.

2. Align the antennas, one at a time, until expected RSL is achieved. Make sure the achieved RSL is no more than +/-4 dB from the expected level.

Polarization Alignment

Polarization alignment is required to verify that the antenna feeds are adjusted, to ensure that the antenna XPD (Cross Polarization Discrimination) is achieved.

Polarization adjustment should be done on one antenna only.

1. Power up drawer V on both ends of the link and record the RSL reading on one end.

2. Power off drawer V on that end and power on drawer H.


3. Check the RSL obtained on this RFU on H pol, and compare it to the RSL obtained by the RFU installed on the V pol.

4. Verify that XPI (Cross Polarization Interference) is at least 25 dB

where:

sites.both at used onspolarizati orthogonal with RSLLink RSLsites.both at usedon polarizati same with theRSLLink RSL

XPOL

POL

→→

−= XPOLPOL RSLRSLXPI

5. If XPI is less than 25 dB, adjust the feed polarization by opening the polarization screw and gently rotating the feed to minimize the RSLXPOL.

Note that polarization alignment is not always possible since the RSLXPOL may fall below the sensitivity threshold of the RFU.

It is also recommended to try to maximize the XPI as much as possible, by aligning the polarization.

XPIC Commissioning Tests

Individual Link Verification

Before operating in XPIC configuration, each of the links (V and H) should be commissioned individually in order to verify its proper operation.

1 Power up only drawer V at both ends and verify its frequency channel and Tx power configuration.

2 Verify that the RSL is no more than +/-4 dB from the expected level.

3 Run BER stability test on the link for at least 15 minutes to ensure error-free operation.

4 Power up only drawer H at both ends and verify its frequency channel and Tx power configuration.

5 Verify that the RSL is no more than +/-4 dB from the expected level.

6 Run BER stability test on the link for at least 15 minutes to ensure error-free operation.

XPIC Configuration Verification

1 Using the XPIC cable, connect the two RFUs at each end to the TNC connectors. Make sure the cable is no longer than 3 meters.

2 Configure the drawers to work in XPIC mode.

3 Verify that the RSL at all four RFUs is no more than +/-4 dB from the expected level.

4 Verify that no alarms exist (if a 155 Mbps line is connected).

5 Run BER stability test on each of the 155 Mbps links for at least 1 hour to ensure error-free operation.

Note: In a 2+2 configuration, repeat each step above for each of the four coupled RFU combinations.


XPIC Recovery Verification

In order to verify XPIC operation, simulate the faults described below.

1 Disconnect the IDU-RFU cable for each of the drawers (one at a time), and verify that the other link is operating.

2 Disconnect the XPIC cable and check that the relevant alarms are generated.

3 Power down each of the drawers and verify that the other link is operating.

4 Swap the V and H cables and check that the relevant alarm is generated.

5 Mute and then un-mute one RFU at a time and verify that the other link is operating.

Note: In a 2+2 configuration, repeat each step above for each of the four coupled RFUs connected to the two standby IDUs.

2+2 Verification

Perform the tests specified in Switching Tests in the 1+1 Commissioning Procedure section earlier in this guide.

In this case, the switch will be from a main IDU connected to the main V and main H RFUs, to the secondary IDU connected to the coupled V and coupled H RFUs.


FibeAir RFU-C Commissioning Log The Commissioning Log is an integral part of the commissioning procedure and should be filled in for each installed link.

The Commissioning Log gathers all relevant information regarding the installed link and contains a checklist of all recommended commissioning tests.

Maintaining the Commissioning Log is important for tracking your installations, and to provide essential data for Ceragon Networks.

Upon completing the Commissioning Log, send the log to Ceragon support center at [email protected].

FIBEAIR RFU-C LINK COMMISSIONING LOG

1. GENERAL INFORMATION

Customer:

Radio model:

Configuration:

Radio link code:

Site 1 name & add:

Site 2 name & add:

2. IN-DOOR UNIT Site 1 Drawers

Right / Left Site 2 Drawers

Rigt / Left

IDC model:

Wayside channel:

IDC p/n:

IDC s/n:

SW IDC:

Drawer model

Main channel

Drawer p/n

Drawer s/n

Modem s/n

FW Mux:

FW Modem:

Cfg Modem:



(continued)

3. RFU Site 1 Drawers


Right / Left

RFU model:

RFU p/n:

RFU Main s/n:

SW RFU:

Tx frequency (MHz):

Rx frequency (MHz):

Link ID:

Tx power (dBm):

ATPC on/off:

ATPC ref level:

RFU polarization:

4. ANTENNA Site 1 Drawers Right / Left

Site 2 Drawers Right / Left

Antenna model:

Antenna size:

Manufacturer:

Mounting type:

Mounting losses:

5. LINK PARAMETERS Site 1 Drawers


Right / Left

Link distance:

Rain zone:

Expected RSL (dBm):

Expected Diversity RSL (dBm):

RSL Main (dBm):

RSL Diversity (dBm):

Deviation from exp?

RSL ≤4 dB?



(continued)

6. COMMISSIONING TESTS Site 1 Drawers


Right / Left

Front panel LEDs: All green All green All green All green

Line loopback: Pass Pass Pass Pass

IDU loopback: Pass Pass Pass Pass

RFU loopback: Pass Pass Pass Pass

Radio BER: Pass Pass Pass Pass

STM-1 test: Pass Pass Pass Pass

Fast Ethernet test: Pass Pass Pass Pass

8 x E1/T1 test: Pass Pass Pass Pass

E3/DS3 test: Pass Pass Pass Pass

Wayside E1 test: Pass Pass Pass Pass

Wayside Eth test: Pass Pass Pass Pass

XPIC test: Pass Pass Pass Pass

Switching test: Pass Pass Pass Pass

7. MANAGEMENT CONFIGURATION Site 1 Site 2

Eth Main IP address:

Eth Coupled IP address:

Eth IP mask:

Serial IP address:

Serial IP mask:

Default router:

In-band enabled?

Gateway/NE:

In-band channel 1:

In-band channel 2:

Ring IP address:

Ring IP mask:

Network ID:

8. REMARKS/NOTES



(continued)

9. INSTALLATION INFORMATION

Name:

Company:

Date: Installed by:

Signature:

Name:

Company:

Date: Commissioned by:

Signature:

FibeAir® RFU-C Installation Guide A-1

Appendix A: Frequency Information

General This appendix provides frequency information for FibeAir RFU-C.

RFU Frequency Bands

RFU-C is available for ITU-R, CEPT, and FCC channels, in accordance with the table below.

All RFU-Cs (6-38 GHz) support 7-56 MHz bands (for capacities of from 10 to 500 Mbps).

56 MHz bandwidth is supported for all frequencies (6-38 GHz).

The following table lists the frequency bands, sub-bands, and duplex spacing supported by RFU-C.

For a detailed list of the low frequency channels, see the appendix at the end of this document.

Frequency Band

Separation MHz Standard Tx Low

MHz Tx High

MHz

* 6L GHz

(variable) 252.04,

240,260, 266, 300

ITU-R F.383-7,

ITU-R F.384-7

CEPT 14-01E

ITU-R F.497-6

CFR47 101.147

5900-6500 5900-6501

* 6H GHz (variable) 340,160,

170,500

ITU-R F.383-7

CEPT 14-01E

CFR47 101.147

6400-7100 6400-7101

* 7 GHz

(variable) 154,161,168,182,196,2

45,300

ITU-R F.385-7, Annex 3

ITU-R F.385-8, Rec 1-4, Annex 1,3,4

CEPT 02-06 Annex 1

7100-7900 7100-7900

* 8 GHZ

(variable) 119,154,208,266,300,310,311.32,5

30

ITU-R F.386-6,

Annex 4,3

CEPT 02-06

7700-8500 7700-8500


Frequency Band


MHz Tx High

MHz

490 10721-10949 11211-11439

490

ITU-R F.387-9,

CEPT 12-06 rec.12

CFR47 101.147 10961-11189 11451-11679

530 10701-10929 11231-11459

11 GHz

530 ITU-R F.387-9, Annex 2

CEPT 12-06 rec.3 10941-11169 11471-11699

266 12751-12863 13017-13129 13 GHz

266

ITU-R F.497-6,

CEPT 1202F 12863-12975 13129-13241

315 14648-14760 14963-15075

315 14732-14844 15047-15159

420 14501-14725 14921-15145

420 ITU-R F.636-3

14697-14921 15117-15341

490 14403-14657 114893-15117

490 ITU-R F.636-3

14627-14851 15117-15341

644 ACA (ITU-R F.636-3) 14613-14697 15257-15341

15 GHz

728 CEPT 12-07E 14501-14613 15229-15341

1008,1010 17700-18200 18710-19210

1008,1010

ITU-R F.595-8

CEPT 12-03E 18150-18690 19160-19700

1120 17728-18113 18848-19233

1120 18113-18553 19233-19673 18 GHz

1560 ITU-R F.595-8

CFR47 101.147 17700-18150 19260-19710

1008 ITU-R F.637-3, Annex 3

CEPT 12-02E 22000-22600 23000-23600

1200 CFR47 101.147 21200-21800 22400-23000

1200 ITU-R F.637-3, Annex 4 21800-22400 23000-23600

1232 21224-21784 22456-23016

23 GHz

1232 ITU-R F.637-3, Annex 1

21784-22344 23016-23576

800 24250-24450 25050-25250

1008 24549-24997 25557-26005 26 GHz

1008 24997-25445 26005-26453

1008 27548-27996 28556-29004 28 GHz

1008

ITU-R F.748-4, Annex 2 CEPT 13-02E

27996-28444 29004-29452


Frequency Band


MHz Tx High

MHz

812 31815-32207 32627-33019 32 GHz

812

ITU-R F.1520-2

CEPT (01) 32179-32571 32991-33383

700 38600-38950 39300-39650

700

ITU-R F.749-2, Annex1

CEPT 12-01E

CFR47 101.147 38950-39300 39650-40000

1000 38050-38500 39050-39500

1260 37058-37618 38318-38878

38 GHz

1260

ITU-R F.749-2,

Annex 3,1 37618-38178 38878-39438


* Low Frequency Bands and Frequency Channel Allocation

Frequency TR Spacing/Block Channel Tx Low

MHz Tx High

MHz

1-3 5941-6049 6181-6289 240A

4-6 6061-6169 6301-6409

1-4 5931.2-6048.2 6183.2-6300.2

3-6 5992-6106 6244-6358 252A

5-8 6049.8-6166.8 6301.8-6418.8

1-4 5916.4-6033.3 6168.4-6285.4 252B

5-8 6035-6151.9 6287-6404

1-2 5941-6029 6201-6289 260A

3-4 6061-6149 6321-6409

1-4 5927-6039 6193-6305

L6 GHz

266A 5-8 6039-6151 6305-6417

300A 2-3 5973.5-6091.5 6273.5-6391.5

1-6 6540.5-6609.5 6710.5-6769.5

7-12 6610.5-6669.5 6770.5-6829.5 170A

13-16 6670.5-6709.5 6830.5-6869.5

1-4 6446-6594 6786-6934 340A

5-8 6606-6754 6946-7094

1-4 6426-6574 6766-6914 340B

5-8 6586-6734 6926-7074

H6 GHz

340C 1-2 6694-6750 7034-7090

1-2 7428-7484 7582-7638

2-3 7456-7512 7610-7666

3-4 7484-7540 7638-7694 154A

4-5 7512-7568 7666-7722

1-2 7442-7498 7596-7652

2-3 7470-7526 7624-7680 154B

4-5 7526-7582 7680-7736

1-2 7128-7184 7282-7338

2-3 7156-7212 7310-7366

3-4 7184-7240 7338-7394

7 GHz

154C

4-5 7212-7268 7366-7422



MHz Tx High

MHz

1-2 7124.5-7180.5 7285.5-7341.5

2-3 7152.5-7208.5 7313.5-7369.5

3-4 7180.5-7236.5 7341.5-7397.5 161A

4-5 7203-7264.5 7364-7425.5

1-2 7249.5-7305.5 7410.5-7466.5

2-3 7277.5-7333.5 7438.5-7494.5 161B

4-5 7333.5-7389.5 7494.5-7550.5

1-2 7424.5-7480.5 7585.5-7641.5

2-3 7452.5-7508.5 7613.5-7669.5 161C

4-5 7508.5-7564.5 7669.5-7725.5

1-2 7549.5-7605.5 7710.5-7766.5

2-3 7577.5-7633.5 7738.5-7794.5 161D

4-5 7633.5-7689.5 7794.5-7850.5

1-2 7115.5-7189.5 7276.5-7350.5

2-3 7164.5-7238.5 7325.5-7399.5

4-5 7415.5-7489.5 7576.5-7650.5 161F

5-6 7464.5-7538.5 7625.5-7699.5

1-2 7421-7477 7582-7638

2-3 7449-7505 7610-7666 161I

4-5 7505-7561 7666-7722

1-2 7414-7470 7582-7638

2-3 7442-7498 7610-7666

7 GHz

161J

4-5 7498-7554 7666-7722



MHz Tx High

MHz

1-2 7485.5-7538.5 7646.5-7699.5 161K

2-3 7513.5-7566.5 7674.5-7727.5

1-2 7443-7499 7611-7667

2-3 7471-7527 7639-7695 168B

4-5 7527-7583 7695-7751

1-2 7414-7470 7596-7652

2-3 7442-7498 7624-7680 182A

4-5 7498-7554 7680-7736

1-3 7107-7191 7303-7387 196A

3-5 7163-7247 7359-7443

1-4 7428-7540 7673-7785 245A

5-8 7540-7652 7785-7897

1-5 7136-7284 7436-7584

7 GHz

300A 6-9 7286-7404 7586-7704

1-3 8279-8335 8398-8454 119A

4-6 8321-8377 8440-8496

1-2 8203-8259 8357-8413

2-3 8231-8287 8385-8441 154A

4-5 8287-8343 8441-8497

1-4 8050-8162 8258-8370 208A

5-7 8162-8246 8370-8454

1-4 8025-8095 8275-8345 250A

5-8 8081-8151 8331-8401

252A 1-2 7976-8034 8228-8286

1-4 7912-8024 8178-8290 266A

5-8 8024-8136 8290-8402

266B 1-2 7926-8010 8192-8276

1-4 7726-7844 8026-8144 300A

5-8 7846-7964 8146-8264

1-3 7731-7839 8041-8149

8 GHz

310A 4-6 7851-7959 8161-8269



MHz Tx High

MHz

1-3 7905-7989 8215-8299

2-4 7933-8017 8243-8327 310C

4-6 7989-8073 8299-8383

1-2 7905-7989 8215-8299

2-3 7933-8017 8243-8327 310D

4-5 7989-8073 8299-8383

1-4 7733.7-7850.7 8045-8162 311A

5-8 7852.3-7969.3 8163.6-8280.6

1-4 7718.9-7835.8 8030.2-8147.1 311B

5-8 7837.5-7954.4 8148.8-8265.7

8 GHz

530A 1-2 7746-7774 8276-8304


6-8 GHz Frequency Channels Note: For additional channel schemes, please contact your Ceragon representative.

6L GHz (5.85-6.45 GHz)

ITU-R F.383-7 [1-3]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 5955.00 1 6195.00

2 5995.00 2 6235.00

3 6035.00 3 6275.00

4 6075.00 4 6315.00

5 6115.00 5 6355.00

240

6 6155.00 6 6395.00

ITU-R F.383-7 [0] / FCC 101.147(i8)

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 5945.20 1 6197.24

2 5974.85 2 6226.89

3 6004.50 3 6256.54

4 6034.15 4 6286.19

5 6063.80 5 6315.84

6 6093.45 6 6345.49

7 6123.10 7 6375.14

252.04

8 6152.75 8 6404.79


FCC 101.147(i7)

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 5935.32 1 6187.36

2 5945.2 2 6197.24

3 5955.08 3 6207.12

4 5964.97 4 6217.01

5 5974.85 5 6226.89

6 5984.73 6 6236.77

7 5994.62 7 6246.66

8 6004.5 8 6256.54

9 6014.38 9 6266.42

10 6024.27 10 6276.31

11 6034.15 11 6286.19

12 6044.03 12 6296.07

13 6053.92 13 6305.96

14 6063.8 14 6315.84

15 6073.68 15 6325.72

16 6083.57 16 6335.61

17 6093.45 17 6345.49

18 6103.33 18 6355.37

19 6113.22 19 6365.26

20 6123.1 20 6375.14

21 6132.98 21 6385.02

22 6142.87 22 6394.91

23 6152.75 23 6404.79

252.04

24 6162.63 24 6414.67


ITU-R F.384-7

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 5955.00 1 6215.00

2 6015.00 2 6275.00

3 6075.00 3 6335.00 260

4 6135.00 4 6395.00

ITU-R F.497-6 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 5941.00 1 6207.00

2 5969.00 2 6235.00

3 5997.00 3 6263.00

4 6025.00 4 6291.00

5 6053.00 5 6319.00

6 6081.00 6 6347.00

7 6109.00 7 6375.00

266

8 6137.00 8 6403.00


6H GHz (6.45-7.1 GHz)

ITU-R F.384-7

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 6460.00 1 6800.00

2 6500.00 2 6840.00

3 6540.00 3 6880.00

4 6580.00 4 6920.00

5 6620.00 5 6960.00

6 6660.00 6 7000.00

7 6700.00 7 7040.00

340

8 6740.00 8 7080.00

FCC 101.147(k7)

T/R Separation

n (L)

Center Frequency

MHz n (H)

Center Frequency

MHz

1 6545 1 6715

2 6555 2 6725 170

3 6565 3 6735

4 6585 4 6745

5 6595 1 6755

6 6605 2 6765

7 6615 3 6775

8 6625 4 6785

9 6635 5 6795

10 6645 6 6805

11 6655 7 6815

12 6665 8 6825

13 6675 9 6835

14 6685 10 6845

15 6695 11 6855

160

16 6705 12 6865


7 GHz (7.1-7.9 GHz)

ITU-R 385-7 [1]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7442 1 7596

2 7470 2 7624

3 7498 3 7652

4 7526 4 7680

154A

5 7554 5 7708

ITU-R 385-7 [1]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7456 1 7610

2 7484 2 7638

3 7512 3 7666

4 7540 4 7694

154B

5 7568 5 7722

ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7138.5 1 7299.5

2 7226 2 7387

3 7428 3 7589 161

4 7526 4 7687


ITU-R 385-7 [1]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7442 1 7687

2 7470 2 7715

3 7498 3 7743

4 7526 4 7771

5 7554 5 7799

6 7582 6 7827

7 7610 7 7855

245

8 7638 8 7883

ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7138.5 1 7299.5

2 7166.5 2 7327.5

3 7194.5 3 7355.5

4 7222.5 4 7383.5

5 7250.5 5 7411.5

11 7145.5 11 7306.5

12 7173.5 12 7334.5

13 7201.5 13 7362.5

14 7229.5 14 7390.5

21 7152.5 21 7313.5

22 7180.5 22 7341.5

23 7208.5 23 7369.5

24 7236.5 24 7397.5

31 7159.5 31 7320.5

32 7187.5 32 7348.5

33 7215.5 33 7376.5

161A

34 7243.5 34 7404.5


ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7263.5 1 7424.5

2 7291.5 2 7452.5

3 7319.5 3 7480.5

4 7347.5 4 7508.5

5 7375.5 5 7536.5

11 7270.5 11 7431.5

12 7298.5 12 7459.5

13 7326.5 13 7487.5

14 7354.5 14 7515.5

21 7277.5 21 7438.5

22 7305.5 22 7466.5

23 7333.5 23 7494.5

24 7361.5 24 7522.5

31 7284.5 31 7445.5

32 7312.5 32 7473.5

33 7340.5 33 7501.5

161B

34 7368.5 34 7529.5


ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7438.5 1 7599.5

2 7466.5 2 7627.5

3 7494.5 3 7655.5

4 7522.5 4 7683.5

5 7550.5 5 7711.5

11 7445.5 11 7606.5

12 7473.5 12 7634.5

13 7501.5 13 7662.5

14 7529.5 14 7690.5

21 7452.5 21 7613.5

22 7480.5 22 7641.5

23 7508.5 23 7669.5

24 7536.5 24 7697.5

31 7459.5 31 7620.5

32 7487.5 32 7648.5

33 7515.5 33 7676.5

161C

34 7543.5 34 7704.5


ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7563.5 1 7724.5

2 7591.5 2 7752.5

3 7619.5 3 7780.5

4 7647.5 4 7808.5

5 7675.5 5 7836.5

11 7570.5 11 7731.5

12 7598.5 12 7759.5

13 7626.5 13 7787.5

14 7654.5 14 7815.5

21 7577.5 21 7738.5

22 7605.5 22 7766.5

23 7633.5 23 7794.5

24 7661.5 24 7822.5

31 7584.5 31 7745.5

32 7612.5 32 7773.5

33 7640.5 33 7801.5

161D

34 7668.5 34 7829.5

ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7435 1 7596

2 7463 2 7624

3 7491 3 7652

4 7519 4 7680

161I

5 7547 5 7708


ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7428 1 7589

2 7456 2 7617

3 7484 3 7645

4 7512 4 7673

161J

5 7540 5 7701

ITU-R 385-7 [0]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7498 1 7659

2 7526 2 7687 161K

3 7554 3 7715

ITU-R 385-7 [3]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7457 1 7625

2 7485 2 7653

3 7513 3 7681

4 7541 4 7709

168B

5 7569 5 7737


ITU-R 385-7 [1]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7428 1 7610

2 7456 2 7638

3 7484 3 7666

4 7512 4 7694

182

5 7540 5 7722

ITU-R 385-7 [3]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7121 1 7317

2 7149 2 7345

3 7177 3 7373

4 7205 4 7401

196

5 7233 5 7429

ITU-R 385-7 [4]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7442 1 7687

2 7470 2 7715

3 7498 3 7743

4 7526 4 7771

5 7554 5 7799

6 7582 6 7827

7 7610 7 7855

245

8 7638 8 7883


8 GHz (7.8-8.5 GHz)

ITU-R 386-6 [4]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7926 1 8192

2 7954 2 8220

3 7982 3 8248

4 8010 4 8276

5 8038 5 8304

6 8066 6 8332

7 8094 7 8360

266

8 8122 8 8388

ITU-R 386-6 [1]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7747.70 1 8059.02

2 7777.35 2 8088.67

3 7807.00 3 8118.32

4 7836.65 4 8147.97

5 7866.30 5 8177.62

6 7895.95 6 8207.27

7 7925.60 7 8236.92

311.32A

8 7955.25 8 8266.57


ITU-R 386-6 [1]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 7732.875 1 8044.195

2 7762.525 2 8073.845

3 7792.175 3 8103.495

4 7821.825 4 8133.145

5 7851.475 5 8162.795

6 7881.125 6 8192.445

7 7910.775 7 8222.095

311.32B

8 7940.425 8 8251.745

ITU-R 386-6 [3]

T/R Separation

n (L)

Center Frequency

MHz

n (H)

Center Frequency

MHz

1 8293 1 8412

2 8307 2 8426

3 8321 3 8440

4 8335 4 8454

5 8349 5 8468

119

6 8363 6 8482

FibeAir® IP-10

IDU Installation

Guide

Part ID: BM-0137-0 Doc ID: DOC-00018767 Rev a.01

September 2008

Notice This document contains information that is proprietary to Ceragon Networks Ltd.

No part of this publication may be reproduced, modified, or distributed without prior written authorization of Ceragon Networks Ltd.

This document is provided as is, without warranty of any kind.

Registered TradeMarks Ceragon Networks® , FibeAir® and CeraView® are registered trademarks of Ceragon Networks Ltd.


TradeMarks CeraMapTM, ConfigAirTM, PolyViewTM, EncryptAirTM, CeraMonTM, EtherAirTM, and MicroWave FiberTM, are trademarks of Ceragon Networks Ltd.


Statement of Conditions The information contained in this document is subject to change without notice.

Ceragon Networks Ltd. shall not be liable for errors contained herein or for incidental or consequential damage in connection with the furnishing, performance, or use of this document or equipment supplied with it.

Information to User Any changes or modifications of equipment not expressly approved by the manufacturer could void the user’s authority to operate the equipment and the warranty for such equipment.

Copyright © 2008 by Ceragon Networks Ltd. All rights reserved.

Corporate Headquarters: Ceragon Networks Ltd. 24 Raoul Wallenberg St. Tel Aviv 69719, Israel Tel: 972-3-645-5733 Fax: 972-3-645-5499 Email: [email protected] www.ceragon.com

European Headquarters: Ceragon Networks (UK) Ltd. 4 Oak Tree Park, Burnt Meadow Road North Moons Moat, Redditch, Worcestershire B98 9NZ, UK Tel: 44-(0)-1527-591900 Fax: 44-(0)-1527-591903 Email: [email protected]

North American Headquarters: Ceragon Networks Inc. 10 Forest Avenue, Paramus, NJ 07652, USA Tel: 1-201-845-6955 Toll Free: 1-877-FIBEAIR Fax: 1-201-845-5665 Email: [email protected]

APAC Headquarters: Ceragon Networks APAC (S'pore) Pte Ltd 100 Beach Road #27-01/03 Shaw Towers Singapore 189702 Tel.: 65 65724170 Fax: 65 65724199

Contents

Chapter 1: Installation................................................................................... 1-1

General.................................................................................................................. 1-1

Site Requirements................................................................................................ 1-1

Pre-Installation ..................................................................................................... 1-1

Unpacking Equipment at the Site ....................................................................... 1-2

Installation Requirements ................................................................................... 1-2

FibeAir IP-10 Description .................................................................................... 1-4

Installing the IDU in a Rack................................................................................. 1-5

Grounding the IDU ............................................................................................... 1-7

Connecting the IDU.............................................................................................. 1-9

Configuring the IDU ........................................................................................... 1-10

Appendix A: Line Interfaces .........................................................................A-1

Appendix B: Connector Pin-Outs.................................................................B-1

Appendix C: Protection Information ............................................................C-1

Appendix D: Accesories ...............................................................................D-1

Safety Precautions & Declared Material

Fiber Optic Line Precautions

Before turning on the equipment, make sure that the fiber optic cable is intact and is connected to the transmitter.

Do not attempt to adjust the laser drive current.

Do not use broken or non-terminated fiber optic cables/connectors or look straight at the laser beam.

ATTENTION: The laser beam is invisible!

The use of optical devices with the equipment will increase eye hazard.

CLASS 1 LASER PRODUCT

Complies with IEC 60 825-1:1993 + A1:1997 + A2:2001, and EN 60825-1:1994 + A1:1996 + A2:2001

General Equipment Precautions

Use of controls, adjustments, or performing procedures other than those specified herein, may result in hazardous radiation exposure.

When working with a FibeAir IDU, note the following risk of electric shock and energy hazard: Diconnecting one power supply disconnects only one power supply module. To isolate the unit completely, disconnect all power supplies.

Machine noise information order - 3. GPSGV, the highest sound pressure level amounts to 70 dB (A) or less, in accordance with ISO EN 7779.

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Safety Precautions & Declared Material (continued)

Static electricity may cause body harm, as well as harm to electronic components inside the device.

Anyone responsible for the installation or maintainance of the FibeAir IDU must use an ESD Wrist Strap.

ESD protection measures must be observed when touching the IDU.

To prevent damage, before touching components inside the device, all electrostatic must be discharged from both personnel and tools.

RoHS Compliance Declaration

电子信息产品有毒有害物质申明 Electronic Information Products Declaration of Hazardous/Toxic Substances

危害物质 Hazardous Substance

成分名称 Component 铅

Lead (Pb)

汞 Mercury

(Hg)

镉 Cadmium

(Cd)

六价铬 Hexavalent

Chromium (Cr VI)

多溴联苯 Polybrominated Biphenyls (PBB)

多溴二苯醚 Polybrominated Diphenyl Ethers

(PBDE)

单板 / 电路模块 PCB/Circuit Modules


结构件 Mechanical Parts


电缆 Cables


Précautions de sécurité

Précautions relatives à la ligne à fibre optique

Avant de mettre l'équipement en marche, s'assurer que le câble à fibre optique est intact et branché à l'émetteur.

Ne pas essayer de régler le courant de commande du laser.

Ne pas utiliser de câble/connecteur à fibre optique cassé ou sans terminaison et ne pas regarder directement le faisceau laser.

ATTENTION : le faisceau laser est invisible !

L’utilisation de dispositifs optiques avec l'équipement augmente le danger pour les yeux.

PRODUIT LASER DE CLASSE 1

Conforme aux normes CEI 60 825-1:1993 + A1:1997 + A2:2001, et EN 60825-1:1994 + A1:1996 + A2:2001

Précautions générales relatives à l'équipement

L’utilisation de commandes ou de réglages ou l'exécution de procédures autres que celles spécifiées dans les présentes peut engendrer une exposition dangereuse aux rayonnements.

L’usage de FibeAir IDU s’accompagne du risque suivant d'électrocution et de danger électrique : le débranchement d'une alimentation électrique ne déconnecte qu'un module d'alimentation électrique. Pour isoler complètement l'unité, il faut débrancher toutes les alimentations électriques.

Bruit de machine d’ordre - 3. GPSGV, le plus haut niveau de pression sonore s'élève à 70 dB (A) au maximum, dans le respect de la norme ISO EN 7779.

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Sicherheitsmaßnahmen

Vorsichtsmaßnahmen bei faseroptischen Leitungen

Vergewissern Sie sich vor dem Einschalten der Anlage, dass das faseroptische Kabel unbeschädigt und mit dem Sender verbunden ist.

Versuchen Sie nicht, den Laser-Antriebsstrom zu regulieren.

Verwenden Sie keine defekten oder gespleißten faseroptischen Kabel/Stecker und sehen Sie nicht direkt in den Laserstrahl.

ACHTUNG: Der Laserstrahl ist unsichtbar!

Durch den Einsatz optischer Geräte zusammen mit der Anlage erhöht sich das Gesundheitsrisiko für die Augen.

LASERPRODUKT DER KLASSE 1

Entspricht den Normen IEC 60 825-1:1993 + A1:1997 + A2:2001 sowie EN 60825-1:1994 + A1:1996 + A2:2001

Allgemeine Vorsichtsmaßnahmen für die Anlage

Wenn andere Steuerelemente verwendet, Einstellungen vorgenommen oder Verfahren durchgeführt werden als die hier angegebenen, kann dies gefährliche Strahlung verursachen.

Beachten Sie beim Arbeiten mit FibeAir IDU das folgende Stromschlag- und Gefahrenrisiko: Durch Abtrennen einer Stromquelle wird nur ein Stromversorgungsmodul abgetrennt. Um die Einheit vollständig zu isolieren, trennen Sie alle Stromversorgungen ab.

Maschinenlärminformations-Verordnung - 3. GPSGV, der höchste Schalldruckpegel beträgt 70 dB(A) oder weniger gemäß EN ISO 7779.

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FibeAir® IP-10 Installation Guide 1-1

Chapter 1: Installation

General This chapter provides instructions for the installation of the FibeAir IP-10 IDU at the customer site.

Site Requirements Must be located indoors.

The environment temperature must be between -5 C and +55 C.

Easily accessible, but only by authorized personnel.

Available power source of -48 VDC, and the site must comply with National Electric Code (NEC) standards.

Available management connection (Ethernet or dial-up).

No more than 300 m from RFU location.

In addition, since the IDU will be connected to the RFU, when considering a site, it is important to check for current and future obstacles on the roof or tower. Possible future obstacles may include trees, new buildings, window cleaners on the roof, snow that may accumulate in front of the antenna, etc. The site should be accessible to certified personnel only.

Note about Heat Dissipation: The IP-10 IDU overall heat dissipation is 25W max (~85 BTU/h).

Note about Antenna Location: As with any type of construction, a local permit may be required before installing an antenna. It is the owner’s responsibility to obtain any and all permits.

Pre-Installation

Packing

The equipment is packed at the factory, and sealed moisture-absorbing bags are inserted.

Transportation

The equipment is prepared for public transportation. The cargo must be kept dry during transportation, in accordance with ETS 300 019-1-2, Class 2.3.

It is recommended to transport the equipment to the installation site in its original packing case.

If intermediate storage is required, the packed equipment must be stored in dry and cool conditions and out of direct sunlight, in accordance with ETS 300 019-1-1, Class 1.2.

FibeAir® IP-10 IDU Installation Guide 1-2

Inspection

Check the packing lists, and ensure that the correct part numbers and quantities of components arrived.

Unpacking Equipment at the Site A single FibeAir system (1+0) is shipped in 5 crates. Upon delivery, make sure that the following items are included:

Two indoor units and accessories

Two outdoor units

One CD with a management user guide.

Unpack the contents and check for damaged or missing parts. If any part is damaged or missing, contact your local distributor.

Installation Requirements

Required Tools

The following tools are required to install the IDU:

Philips screwdriver (for mounting the IDU to the rack and grounding screw)

Flathead small screwdriver (for PSU connector)

Sharp cutting knife (for wire stripping)

Crimping tool for ground cable lug crimping (optional: if alternative grounding cable is used).

Cables

In addition to the tools mentioned above, the interface connectors and their pin-outs, can be found in the following sections in this guide:

Appendix A: Line Interfaces

Appendix B: Connector Pin-Outs


Requirements for North America

Restricted Access Area: DC powered equipment should only be installed in a Restricted Access Area.

Installation Codes: The equipment must be installed according to country national electrical codes. For North America, equipment must be installed in accordance to the US National Electrical Code, Articles 110-16, 110-17 and 110-18, and the Canadian Electrical Code, Section 12.

Overcurrent Protection: A readily accessible Listed branch circuit overcurrent protective device, rated 15 A, must be incorporated in the building wiring.

CAUTION: This equipment is designed to permit connection between the earthed conductor of the DC supply circuit and the earthing conductor at the equipment.

Grounded Supply System: The equipment shall be connected to a properly grounded supply system. All equipment in the immediate vicinity shall be grounded the same way, and shall not be grounded elsewhere.

Local Supply System: The DC supply system is to be local, i.e. within the same premises as the equipment.

Disconnect Device: A disconnect device is not allowed in the grounded circuit between the DC supply source and the frame/grounded circuit connection.


FibeAir IP-10 Description FibeAir IP-10 is Ceragon's comprehensive high capacity migration-to-IP network solution. The innovative IP-10 was designed as a native Ethernet microwave radio platform that can integrate smoothly in any network, while providing a broad range of software-configurable licensed channel schemes.

IP-10 follows in the tradition of Ceragon's Native2, which allows your network to benfit from both native TDM and native Ethernet using the same radio. Flexible bandwidth sharing between the TDM and Ethernet traffic ensures optimal throughput for all your media transfer needs.

IP-10 features a flexible design capable of addressing all network migration scenarios. With its Native2 capability for optimal traffic delivery, and modular architecture for all sites (Tail, Chain, Agg3, Agg2), this state-of-the-art radio platform offers the best approach to IP migration for advanced networks.

With the widest capacity range (10-500 Mbps) for all capacity needs, advanced Adaptive Code Modulation for the best spectrum utilization, and a scalable system that ensures future-proof network expansion, IP-10 is the ideal solution for risk-free migration.

Some of the important points that place IP-10 at the top of the wireless IP market include:

Supports all licensed bands, from 6 to 38 GHz

Supports channel bandwidths of from 7 MHz to 56 MHz

Supports throughputs of from 10 to 500 Mbps per radio carrier (QPSK to 256 QAM)

Incorporates advanced integrated Ethernet switching capabilities

In addition, using unique Adaptive Code & Modulation (ACM), your network benefits from non-stop, dependable capacity deliverance.

FibeAir IP-10 IDU


Installing the IDU in a 19"/ETSI Rack

Warning! The intra-building port(s) of the equipment or subassembly is suitable for connection to intra-building or exposed wiring or cabling only. The intra-building port(s) of the eqiupment or subassembly MUST NOT be metallically connected to interfaces that connect to the OSP or its wiring. These interfaces are designed for use as intra-building interfaces only and require isolation from the exposed OSP cabling. The addition of Primary Protectors is not sufficient protection in order to connect these interfaces metallically to OSP wiring.

The FibeAir IP-10 IDU is installed in a standard 19" ETSI rack as shown in the following illustration.

As shown in the illustration, four screws, supplied with the installation kit, are used to secure the IDU to the rack.


IDU Dimensions

The following illustration shows the dimensions (in millimeters) of the FibeAir IP-10 IDU.


Grounding the IDU

The following illustration shows how the IDU is grounded to the rack.

A grounding wire is connected below the IDU-RFU interface using a single screw with two washers.

IDU Grounding Notes

• The IDU is suitable for installation in a Common Bonding Network (CBN).

• Only copper wire should be used.

• The wire must be at least 6 AWG.

• Connector and connection surfaces must be plated. Bare conductors must be be coated with antioxidant before crimp connections are made to the screws.

• FibeAir provides a ground for each IDU, via a one-hole mounted lug onto a single-point stud. The stud must be installed using a UL-listed ring tongue terminal, and two star washers for anti-rotation.

Single Point Stud

Grounding Wire


• For antenna ports, lightning protection is used that does not permit transients of a greater magnitude than the following:

Open Circuit: 1.2-50us 600V

Short Circuit: 8-20us 300A

• The ampacity of the conductor connecting the IDU frame to the DC return conductor is equal to, or greater than, the ampacity of the associated DC return conductor.

Power Supply Notes

When selecting a power source, the following must be considered:

• DC power can be from -40.5 VDC to -60 VDC.

• Recommended: Availability of a UPS (Uninterrupted Power Source), battery backup, and emergency power generator.

• Whether or not the power source provides constant power (i.e., power is secured on weekends or is shut off frequently and consistently).

• The power supply must have grounding points on the AC and DC sides.

Caution! The user power supply GND must be connected to the positive pole in the IDU power supply. Any other connection may cause damage to the system!

Power supply grounding should be in accordance with the following illustration:


Connecting the IDU

This section describes how the IDU interfaces are connected for a 1+0 system. The interfaces include line, system (IDU-RFU), and management ports.

For interface specifications, see Appendix A - Line Interfaces and Cables.

For connector pin-outs, see Appendix B - Connector Pin-Outs.

For a list of accessories, see Appendix D - Accessories.

Note: For a 1+1 system, a protection panel is used, as described in Appendix C - Protection Information.

Interface Descriptions

The following photo shows the different IDU ports and their functions.

IDU Front Panel

The IDU front panel includes the following auxiliary interfaces:

Terminal console

Ethernet out-of-band management

Ethernet wayside

Craft Terminal

(DB9) Engineering Order Wire

External Alarms (DB9)

Optional 16xE1/T1 (MDR68)

User Channel (RJ45)

1 GbE Optical

1000baseX (SFP) 1 GbE

Copper 10/100/

1000baseT (RJ45)

FE Copper 10/100baseT

(RJ45) or

Protection Channel

RFU Interface (N-Type)

Power -48 VDC


(RJ45) or

Wayside Channel


(RJ45) or

Out-of-Band Management

Fan Unit


Optional:

Engineering Order Wire (EOW)

User channel (V11, RS232)

External alarms

Note: The Fast Ethernet interface channels can be logically configured for either Fast Ethernet traffic, or protection, wayside, or management traffic.

IDU-RFU Coax Cable

The Coax Cable that connects between the IDU and the RFU should be terminated with N-type male connectors.

Important! Make sure that the inner pin of the connector does not exceed the edge of the connector.

The cable should have a maximum attenuation of 30 dB at 350 MHz.

Configuring the IDU After the system is installed and tested, and antenna alignment is performed, the next step is IDU setup and configuration.

Setup procedures are performed using the FibeAir IP-10 CLI (Command Line Interface) or Web Based Management.

For an explanation of the CLI, see the FibeAir IP-10 CLI Guide.

For an explanation of the Web Based Management, see the FibeAir IP-10 Web Based Management Guide.

FibeAir® IP-10 IDU Installation Guide A-1

Appendix A: Line Interfaces This section provides a description of the FibeAir main channel, wayside channel, and order wire channel interfaces.

The interfaces are located on the FibeAir IDU front panel.

The following interface terms should be noted:

For connectors or signals labeled TX, the signals are sent from FibeAir.

For connectors or signals labeled RX, the signals are sent to FibeAir.

Main Channel Interfaces

Main channel interfaces include the following:

Gigabit Ethernet (Optical)

1000Base-SX (Multi Mode)

Wavelength: 850 nm

Receptacle: MSA compliant, SFP (Small Form Factor Pluggable Ports)

Connector: LC

Max Segment Length: 220 m (1351 ft), 500 m (1650 ft)

Cable Type: For Max Segment = 220 m: 62.5 µm MMF

For Max Segment = 500 m: 50 µm MMF

1000Base-LX (Single Mode)

Wavelength: 1350 nm

Receptacle: MSA compliant, SFP (Small Form Factor Pluggable Ports)

Connector: LC

Max Segment Length: 550 m (1805 ft), 5000 m (16404 ft)

Cable Type: For Max Segment = 550 m: 62.5 µm MMF, 50 µm MMF

For Max Segment = 5000 m: 10 µm SMF


Gigabit Ethernet / Fast Ethernet (Electrical)

100/1000BaseT (Twisted Pair Cable)

Connector: RJ-45

Max Segment Length: Up to 100 m (328 ft) per IEEE802.3

Cable Type: Compatible with shielded and unshielded twisted pair category 5 cables.

Optional 16xE1/T1 Connector MDR 69-pin

Used with: Twisted pair

Interface Type E1/T1

Number of ports 16 per unit (optional)

Timing mode: Retimed

Framing Unframed (full transparency)

Coding E1: HDB3 T1: AMI/B8ZS

Range: 5 m

Line Impedance 120 Ω/100 Ω balanced. Optional module for 75 Ω unbalanced

Compatible Standards ITU-T G.703, G.736, G.775, G.823, G.824, G.828, ITU-T I.432, ETSI ETS 300 147, ETS 300 417, ANSI T1.105, T1.102-1993, T1.231, Bellcore GR-253-core, TR-NWT-000499

Wayside Channel Interface The wayside channel is used as an auxiliary audio or data channel.

10/100BaseT (Ethernet)

Connector: Shielded RJ-45

Used with: UTP Cat 5

Protocols supported: Ethernet (10/100BaseT), half or full duplex


Range: 100 m

Impedance: 100 Ω


Protection Channel Interface

Protection





Range: 100 m

Impedance: 100 Ω

Management Channel Interface

Out-of-Band Management





Range: 100 m

Impedance: 100 Ω

Order Wire Channel Interface

The Order Wire is used for audio transmission for testing or maintenance purposes.

The specifications for this channel are as follows:

Termination Type: Headset stereo plug, 2.5 mm

Frequency band (KHz) 0.3-3.4

Input impedance (ohms) ~2000

Output impedance (ohms) 32


User Channel Interface The user channel is a CVSD audio channel that delivers 64 Kbps, via an RJ-45 connector.

The interface can be used for one of the following:

Asynchronous RS-232

Asynchronous V-11

Co and Contra Directional

FibeAir® IP-10 IDU Installation Guide B-1

Appendix B: Connector Pin-Outs

General

This appendix provides pin-outs for FibeAir IDU connectors, including the following:

External Alarms Connector

Protection/Wayside/Management Connector

Power Connector

16 x E1/T1 Connector

Ethernet 10/100/1000 Connector

Ethernet 10/100 Connector

User Channel Connector


External Alarms Connector Pin-Out The External Alarms connector is a D-type 9-pin connector.

Pin Signal I/O Description

1 EXT_IN5 Input External input alarm #5





6 GND GND GND

7 RELAY_1_NO Output Relay #1, normally open pin

8 RELAY_1_C Output Relay #1, common pin

9 RELAY_1_NC Output Relay #1, normally closed pin

Protection/Wayside/Management Connector Pin-Out The Protection/Wayside/Management connector is an RJ-45, 8-pin, female type connector.

RJ-45 Male Connector

Pin Signal

1

2 Twisted Pair, Out - Tx

3

6 Twisted Pair, In - Rx

4

5 Not Connected

7

8 Not Connected


Power Connector Pin-Out The power connector pin-out is as follows:

Left Pin (#1) Right Pin (#2)

-48V (return current)

0V

Note that right/left refers to viewing the panel from the front.

16 x E1/T1 Connector The 16 x E1/T1 connector is a SCSI 68-pin connector.

Pin # Signal Label on the Twisted Pair Type

1 OUT - TIP1

35 OUT - RING1 Ch1 Tx TWISTED PAIR

2 OUT - TIP2


3 OUT - TIP3


4 OUT - TIP4


5 OUT - TIP5


6 OUT - TIP6


7 OUT - TIP7


8 OUT - TIP8


9 OUT - TIP9


10 OUT - TIP10


11 OUT - TIP11


12 OUT - TIP12




13 OUT - TIP13


14 OUT - TIP14


15 OUT - TIP15


16 OUT - TIP16


19 IN - TIP1

53 IN - RING1 Ch1 Rx TWISTED PAIR

20 IN - TIP2


21 IN - TIP3


22 IN - TIP4


23 IN - TIP5


24 IN - TIP6


25 IN - TIP7


26 IN - TIP8


27 IN - TIP9


28 IN - TIP10


29 IN - TIP11


30 IN - TIP12


31 IN - TIP13


32 IN - TIP14




33 IN - TIP15


34 IN - TIP16


17 SHELL - SHIELD

18 SHELL - SHIELD

51 SHELL - SHIELD

52 SHELL - SHIELD

Ethernet 10/100/1000 Connector Pin-Out The Ethernet 10/100/1000 connector is an RJ-45, 8-pin, female type connector.

RJ-45 Female

Connector Pin

Signal

1

2 Twisted Pair (Tx & Rx)

3


4


7



Ethernet 10/100 Connector Pin-Out The Ethernet 10/100 connector is an RJ-45, 8-pin, female type connector.

RJ-45 Female

Connector Pin

Signal

1

2 Twisted Pair, Out - Tx

3

6 Twisted Pair, In - Rx

4

5 Not Connected

7

8 Not Connected

User Channel Connector Pin-Out

The user channel connector is an RJ-45 connector.

Pin Asynchronous RS-232

AsynchronousV11 I/O

1 NC UC_TXD_P Out

2 NC UC_TXD_N Out

3 NC NC NC

4 GND Signal Ground

GND Signal Ground

COM

5 UC_RS232_TXD Transmitted Data NC Out

6 UC_RS232_RXD Received Data NC In

7 NC UC_RXD_P In

8 NC UC_RXD_N In

FibeAir® IP-10 IDU Installation Guide C-1

Appendix C: Protection Information

General This appendix provides information about the FibeAir IP-10 protection equipment.

Protection Patch Panel In IP-10 protection configurations, a protection patch panel is used to connect the units and provide protection switching.

As shown in the illustration above, the protection panel (in the middle) provides the ports used to link the two IP-10 units for protection switching when a system fault occurs.


Panel Components The following illustration shows the panel components.

Part Numbers

The part numbers for the MDR cables are as follows:

16 x E1/T1 MDR Connector:

WA-0276-0, 0.6 meters

User 16 x E1/T1 MDR Connector:

WA-0277-0, 5 meters

WA-0278-0, 10 meters

WA-0309-0, 25 meters

Optical splitter used for GbE 1+1 systems (see the following section):

AO-0038-0

AO-0039-0

AO-0059-0

AO-0060-0

User Optical GbE

LC/LC Connector

User FE Open-EndedCross RJ-45Connector

IDU #1 4 x FE

Straight RJ-45

Connectors

IDU #2 4 x FE

Straight RJ-45

Connectors

IDU #1 16xE1/T1

MDR Connector

IDU #2 16xE1/T1

MDR Connector

User 16xE1/T1

Open-Ended MDR Connector


GbE Optical Splitter

The following illustration shows the rear side of the IP-10 protection panel, with the optical splitter.

The optical splitter is an LC/LC female adapter.

Optical Splitter

FibeAir® IP-10 IDU Installation Guide D-1

Appendix D: Accessories The following tables list the FibeAir IP-10 accessories.

Cables

Part Number Marketing Model Marketing Description

WA-0242-1 X-WSC-E1/T1 E1/T1 WSC x-ed cable

WA-0246 IDU-EXT-ALARMS-CBL-2.5m IDU External Alarms open cable 2.5m

WA-0259 CBL-16E1-CB-120-75 16E1 cable MDR/2xDB44 5m to CB-120-75

WA-0275 IDU-UC-CBL-2m User channel cable 2m D-type 9 pin male

WA-0276-0 IP10-CBL-16IO-PROT-0.6m IP-10 16 I/O port protection cable straight 0.6m

WA-0277-0 IP10-CBL-16IO-5M IP-10 16 I/O port cable open 5M

WA-0278-0 IP-10-CBL-16IO-10M IP-10 16 I/O port cable open 10M

WA-0284-0 IP10-CBL-16IO-XED-0.6m IP-10 16 I/O port crossed cable 0.6m

WA-0309-0 IP-10-CBL-16IO-25M IP-10 16 I/O port cable open 25M

Panels

Part Number Marketing Model Marketing Description

EN-0254-0 IP10-ETH-16E1-PROT-PANEL IP-10 Eth + 16E1 protection panel

EN-0256-0 IP10-ETH-16T1-PROT-PANEL IP-10 Eth + 16T1 protection panel

EN-0258-0 IP10-16E1-PROT-PANEL IP-10 16E1 protection panel

EN-0259-0 IP10-16T1-PROT-PANEL IP-10 16T1 protection panel

EN-0262-0 IP10-ETH-PROT-PANEL IP-10 Eth only protection panel


Optical Splitters

Part Number Marketing Model Marketing

Description Item Description

AO-0038-0 GBE-SPL-SM SM/LC Optical Splitter conn. 1300nm 50/5

1x2 Single mode Fiber Dual Windows Wideband Couplers, ±40nm, LC/LC, 1310nm,1m length, PVC 2.0mm cable (yellow), 50/50 coupling ratio.

AO-0039-0 GBE-SPL-MM-2M MM/LC Optical Splitter 62.5/125 2M

1x2 multimode mode Fiber Dual Windows Wideband Couplers, ±40nm, LC/LC, 850nm,1m length for each port, PVC 2.0mm cable, 50/50 coupling ratio

AO-0059-0 GBE-SPL-MM-1M MM/LC Optical Splitter 62.5/125 1M

1x2 multimode mode Fiber Dual Windows Wideband Couplers, ±40nm, LC/LC, 850nm,0.5m length for each port, PVC 2.0mm cable, 50/50 coupling ratio

AO-0060-0 GBE-SPL-MM-0.6M MM/LC Optical Splitter 62.5/125 0.6M

1x2 multimode mode Fiber Dual Windows Wideband Couplers, ±40nm, LC/LC, 850nm,0.3m length for each port, PVC 2.0mm cable, 50/50 coupling ratio

Optical Cables



AO-0033-0 OP-SM-CBL-LC-SC-DPLX 15M

Duplex Optical Cable LC-SC SM 15M

Pairs of Fiber Patchcord Single mode- LC/SC, Length:15M, Duplex PVC 2mm cable, with LC connector type on one end and SC connector on the other end.


Duplex Optical Cable LC-SC SM 3M

Pairs of Fiber Patchcord Single mode- LC/SC, Length:3M, Duplex PVC 2mm cable, with LC connector type on one end and SC connector on the other end.


Duplex Optical Cable LC-SC SM 1m

DUPLEX LC-SC (Tx TO Tx) SM 9/125 YELLOW COLOR R-9D-1-P, 13MM, 1M

AO-0044-0 OP-MM-CBL-LC-SC-DPLX 2M

Duplex Optical Cable LC-SC MM 2M

DUPLEX FIBER OPTIC MM PATCH CORD WITH LC/UPC-SC/UPC (Tx TO Tx) 62.5/125, ORANGE COLOR, 2M, 3MM O.D.

AO-0045-0 OP-MM-CBL-LC-SC-DPLX 10M

Duplex Optical Cable LC-SC MM 10M

DUPLEX FIBER OPTIC MM PATCH CORD WITH LC/UPC-SC/UPC (Tx TO Tx) 62.5/125, ORANGE COLOR, 10M, 3MM O.D.

AO-0048-0 OP-MM-CBL-LC-LC-DPLX 0.5M

Duplex Optical Cable LC-LC MM 0.5M

DUPLEX FIBER OPTIC MM PATCH CORD WITH LC/UPC-LC/UPC (Tx TO Tx) 62.5/125 ORANGE COLOR, 0.5M, 2MM O.D.



DUPLEX LC-SC (Tx TO Tx) SM 9/125 YELLOW COLOR, 3MM, 10M






DUPLEX LC-SC (Tx TO Tx) SM 9/125 YELLOW COLOR, 3MM, 5M

AO-0066-0 OP-MM-CBL-LC-LC-DPLX 3M

Duplex Optical Cable LC-LC MM 3M

DUPLEX FIBER OPTIC MM PATCH CORD WITH LC/UPC-LC/UPC (Tx TO Tx) 62.5/125 ORANGE COLOR, 3M, 2MM O.D.

AO-0067-0 OP-MM-CBL-LC-LC-DPLX 6M

Duplex Optical Cable LC-LC MM 6M

DUPLEX FIBER OPTIC MM PATCH CORD WITH LC/UPC-LC/UPC (Tx TO Tx) 62.5/125 ORANGE COLOR, 6M, 2MM O.D.

AO-0071-0 OP-SM-CBL-LC-LC-DPLX 3M

Duplex Optical Cable LC-LC SM 3M

Pairs of Fiber Patchcord Single mode- LC/LC, Length:3M, Duplex PVC 2mm cable, with LC connector type on one end and LC connector on the other end.

Optical Adaptors



AO-0042-0 OP-SM-LC-LC-ADPT-SMPLX

Adaptor Female/Female LC-LC Simplex

SM SIMPLEX LC-LC SM ADAPTOR

ceragon fibeair-ip10 manual

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