fiber optics & electronics
DESCRIPTION
Fiber Optics & Electronics. Security. Speed. A utomatic S ource T ransfer < 8 Cycles < 150ms. Build an asset. Fiber has a 20 year + life Any excess fiber can be leased or sold. Fiber Optic Glass Types. Multimode Fiber Large Core most common 62.5um Only good for < 4KM - PowerPoint PPT PresentationTRANSCRIPT
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Fiber Optics & Electronics
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Security
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Speed
Automatic Source Transfer < 8 Cycles < 150ms
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Build an asset
• Fiber has a 20 year + life• Any excess fiber can be leased or sold
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Multimode Fiber◦ Large Core most common 62.5um◦ Only good for < 4KM
Single Mode Fiber◦ ITU-T G.652-Zero Dispersion around 1310 nm\◦ Supports CWDM and DWDM and Standard Ethernet
Dispersion Compensated Fiber◦ ITU-T G.655-Zero Dispersion around 1550 nm ◦ Supports DWDM and Standard Ethernet @1550 nm◦ Support Long Spans 50 KM+
Fiber Optic Glass Types
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Loose Tube Fiber◦ Commonly used in lashed or under ground
deployments.◦ Has very little internal support.◦ Fiber loose in buffer tubes to allow for
temperature and moisture change.
Armored Fiber◦ Loose tube fiber with corrugated steel Armor◦ Must be grounded
Fiber Optic Types
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◦ADSS(All-Dielectric Self-Supporting) Support and span length engineered into fiber No grounding requirements Installed using Pulleys
Fiber Optic Types
Dead End with Slack
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ADSS Minimum Bend RadiusTo arrive at a working bend radius for cable installation, multiply 20 times (20 x) the cable outside diameter.
Cable Diameter = 0.46 in (11.8 mm)
Example:
20 x 0.46 in = 9.2 in (177 mm)
Minimum Working Bend Radius = 9.2 in (17.7 cm)
To find the minimum diameter requirement for pull wheels or rollers, simply double the minimum working bend radius:
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ADSS Tensions
• As temperature increases ADSS tension will also increase.
• This is opposite of ACSR (conductor)
• Incorrect tension can damage fiber over time
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ADSS Flat Drop Options
Single mode starts at $.25/foot
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Ribbon Fiber Efficient packaging of higher fiber counts Lightweight and easy to handle during installation Specialized Splicers to splice 12 Fiber
simultaneously
Fiber Optic Types
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Optical Ground Wire (OPGW)
◦ Fiber optics engineered into ground wire(Shield)
◦ Wire and Fiber must be Pre-engineered for access of fiber optics( No access mid span)
◦ Lower cost than underground
Fiber Optic Types
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Core Alignment SplicerFiber Optic Splicers
• Uses Servos and Camera to align core• Very precise low loss splice• Electrical Arc fuses Glass• Must be cleaved
V Groove Splicer• Less Precise • Lower cost to purchase and maintain • Must be cleaved
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Splice EnclosuresDome enclosures
• High Capacity enclosure• Customizable using grommets• Splice trays separate• Typically used for butt connections
Low Count enclosures• Compact Size• Low splice capacity• Inline or Butt splices
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Fiber Optics Attachment Methods
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Fiber Optics Attachment MethodsADSS
Dead Ends
• Used to make high angle turns• Must use for slack storage• Creates Shear points
Tangents• Supports fiber between dead
ends• Line angle limitation < 20
degrees• Some models can be used in
pulling short spans
1. Keeper2. Cushion Inserts (With or Without Grit)3. Captured Bolt and Washer (Captured with Grommet)4. Lock Nut5. Anchor Shackle with Eye-nut (Optional not shown)6. Structural Reinforcing Rods (optional, not shown)
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Lashed FiberFiber Optics Attachment Methods
• Fiber lashed to steel carrier• Must be grounded • Can not be installed in power space
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Fiber Optic ConnectorsSC (Subscriber Connector)
• Square connector• Push-Pull snap
LC (Lucent/little connector)• Small high density• Snap fit• Used on
Lasers(XFP/SFP)ST (Straight Tip)• Round• Twist lock• Common in Sub Stations
UPC (Ultra Physical Contact) polish style of fiber optic ferrules• Standard for most applications
APC (Angled Physical Contact)• Has Lower lightwave reflectance• Used in RF optical applications
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Fiber Optic Architecture
Passive• One Fiber 32 to 64 Customers• Requires optical Splitters• Bandwidth is Shared
Active • One Fiber One Customer• Bandwidth not shared• Requires high fiber counts
Non PoweredOptical splitter
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Sonet (Synchronous Optical Network) Based on older Time Division Multiplexing T1-T3 Technology Poor bandwidth Efficiency(Protection Path No bandwidth)
Limited bandwidth sizes Sub 50ms protection High Deployment cost
Fiber Technologies
Active Path Reserved path No activity
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Ethernet◦ Low Cost Deployment◦ Flexible bandwidth rates◦ Sub 50ms protection without stranding bandwidth◦ Mesh and Ring Topologies◦ Easily Scalable
Fiber Technologies
Active PathSecondary pathActive Path
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DWDM(Dense Wavelength division multiplexing)
DWDM• Multiplex up to 160 channels of bandwidth on 2 fibers• Capable of long distance communications• Wavelength sizes up to 100Gb• Can use a digital wrapper(OTN) to encapsulate many
types of data and maintain packet quality • Most systems do not have protection
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Standard Ethernet
Fiber TechnologiesDWDM
TX RCV
TXRCV
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Layer 2 (Facts)1. Switching determined by MAC address database2. If Packet Collision occurs, packet randomly retries
3. Packet Broadcast transverses all switches on domain4. Vlans provide segmentation of domain5. Vlans also allow for security and network traffic flow
management
Ethernet Network Design
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Network Design Layer 2(Hybrid)Example
A
BC
D
Layer 3 Router
Layer 2 Switch
Vlan 10 Sub AVlan 20 Sub BVlan 30 Sub CVlan 40 Sub D
Ethernet Ring BlockG. 803.2
IPs terminated on RouterVlan 10=192.168.10.1/27Vlan 20=192.168.20.1/27Vlan 30=192.168.30.1/27Vlan 40=192.168.40.1/27 29 usable IPs per Vlan
192.168.30.2/27
192.168.30.4/27
192.168.30.3/27
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Ethernet Protection 1. ITU G.8032 provides a method of ethernet protection
while preventing loops.
2. Master node blocks traffic on one interface of ethernet ring
3. Failover achieved in less than 50ms
4. Many derivatives of this technology that are proprietary(Nodes must be of same Manufacture and same Firmware)
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Layer 3 (Facts)
1. Network Control by routing IP address2. No problems controlling Broadcast domains3. Control Services and bandwidth based on IP subnets4. Ring and Mesh redundancy available 5. Traffic flooding and storming easy controlled6. Most Layer 3 devices support layer 2
Ethernet Network Design
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Network Design Layer 3
A
BC
D
Layer 3 Switch/Router
Ethernet Ring BlockG. 803.2
IPs terminated on RouterVlan 10=192.168.10.1/30Vlan 20=192.168.20.1/30Vlan 30=192.168.30.1/30Vlan 40=192.168.40.1/30 2 usable IPs per segment
192.168.50.2/27
192.168.50.4/27
192.168.50.3/27
Layer 2 Ring
Traffic controlled by static or Dynamic routing
MESH Topology
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MPLS packets transverse fiber node based on shortest path and label
MPLS allows transport of ATM, Sonet and Ethernet
VPLS (Virtual Private Lan Service) allow for layer 2 type connectivity with layer 3 controls
While running MPLS switch processor and QOS are easily controlled per vpls instance
Availability of complex traffic engineering
MPLSMulti-Protocol Label Switching
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MPLS
A
BC
D
Layer 3 Switch/Router
Ethernet Ring BlockG. 803.2
Layer 2 Ring
Traffic controlled by LabelsVPLS creates layer
2 connectivity
Fiber Cut
MPLS Restore
s Path
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Test EquipmentOTDRoptical time-domain reflectometer
• Used to test quality and length• Shows projected fiber loss• Find fiber optic breaks
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Test EquipmentOTDR Output
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Test EquipmentSingle-mode/Multimode Loss Test Kit• Measure true loss of fiber• Fiber identification• Certify Fiber for Sale/IRU
Optical Fiber Identifier• Fiber Identification• Power Meter and Direction
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Benefits of IEC-61850•Features no other SCADA protocol has had before... •Self-description and browsers •Structured data •Device models, not data points •Capability for access security •Fast peer-to-peer communications •Dramatic reduction of necessary wiring •Powerful reporting features •A wide choice of lower layers
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What is the Purpose of the Network ? What is the necessary capacity ? How critical is the DATA transport ? What types of DATA do I wish to transport ? What is the future plans for the Network ? Will We transport public DATA ? What security levels do I need ??
What to consider ??
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Questions ?
Thank YouBilly Wise