White Paper
Gigabit Passive Optical Networks Passive Optical LAN Solutions (POLS) Theory, Design, and Installation Considerations
Sean McCloud, RCDD Senior Applications Engineer, Leviton Network Solutions Table of Contents
Abstract 3
Standards 3
Understanding Passive Optical LANs and GPON 4
GPON Components 5
System Overview 7
Installation Options 8
POLS Safety Issues 12
Testing 12
Troubleshooting 14
Conclusion 15
2 Abstract
Today’s diverse and ever-changing technology applications require options for the distribution of information in commercial, public, and governmental markets. Gigabit Passive Optical Networks (GPON) provide a solution that minimizes the physical footprint, increases distance and bandwidth, reduces latency, and improves physical and network security.
Other potential benefits include:
• Adherence to green and sustainability initiatives – LEED® and STEP
• Reduced costs for moves, adds, and changes
• Lower price per port on passive components
• Pre-terminated systems are easy to install and reduce labor and installation errors
Standards
The implementation of Passive Optical LAN Solutions was adopted by ANSI/TIA in August of 2012 under ANSI/TIA 568-C.0-2 General Cabling Addendum 2, General Updates.
Other applicable standards include:
• ANSI/TIA 526-7 Method A.1 Measurement of Optical Power Loss of Installed Single-mode Fiber Cable Plants
• ANSI/TIA 568-C.0 Generic Telecommunications Cabling for Customer Premises
• ANSI/TIA 568-C.1 Commercial Building Telecommunications Cabling Standard
• ANSI/TIA 568-C.2 Commercial Building Telecommunications Cabling Standard, Balanced Twisted-Pair Cabling Components
• ANSI/TIA 568-C.3 Optical Fiber Cabling Standard
• ANSI/TIA 569-C Commercial Building Standard for Telecommunications Pathways and Spaces
• ANSI/TIA 606-B Administration Standard for Commercial Telecommunications
• ANSI/TIA 607-A Commercial Building Grounding (Earthing) and Bonding
• ITU-T G.984 addresses PON systems (BPON, EPON, GPON)
• ITU/Telcordia GR-1209 CORE Generic Requirements for Passive Optical Components
• ITU/Telcordia GR-1221 CORE Fiber Optic reliability
3 Understanding Passive Optical LANs and GPON
Network Architecture While there are many applications for GPON, this paper will address Fiber-to-the-Desktop (FTTD) deployment often used in commercial, educational, and governmental office environments. The most commonly used POLS follow the ITU-T G.984 GPON Class B+ standard. In this application, GPON is distributed via single-mode, simplex optical fiber connectors, and passive optical splitter(s) typically using Angled Polish Connectors (APC) to provide precision terminations that minimize the impact of insertion and return loss. There are four major components to this GPON system: the Optical Line Terminal (OLT), the transport media (cabling and components), the fiber optic splitter, and the Optical Network Terminal (ONT). These components are identified in the following line diagram.
Source IP Data Voice Over Internet Protocol IP Video RF Video
Core Switch
OLT (Optical Line Terminal) Acts as the central aggregator OLT and is typically located in the data center or main equipment room
Upload 1550nm Tx (Video) 1.24Gbps 1310nm Rv Download 1490nm Tx 2.48Gbps 1550nm Tx (Video) Passive Optical Splitter 1x32 Passively splits the signal from Splitter the OLT over one fiber to as many as 32 fibers each connecting to an ONT
ONT (Optical Network Terminal)
ONT ONT ONT ONT ONT ONT ONT ONT ONT ONT ONT ONT Active device that converts the fiber optic signal and converges voice, data, and video signals as necessary to connected user devices
Building Automated Systems Video Data Device Device Device Device Device Device VoiP Wireless Security
4 GPON Components
Optical Line Terminal (OLT) The OLT is an active Ethernet aggregation device typically located in the Main Equipment Room or Data Center of a facility. An OLT converts the aggregated fiber optically transmitted signals to an electrical signals and presents them to a core Ethernet switch. The OLT replaces multiple layer 2 switches at distribution points (ERs, TRs, and TEs). Backbone cabling or horizontal cabling connects to the OLT distributing signal through optical splitters, which are connected to the Optical Network Terminal at each work area outlet.
Transport Media – Structured Cabling Systems GPON uses the passive, physical cabling infrastructure to transmit a signal. This includes copper and fiber optic patch cords, enclosures, adapter plates, connectors, splitters, backbone and horizontal cable faceplates, and pathway support materials. All transport media components should be factored into the channel loss budget when verifying the systems performance.
Passive Optical Splitter Part of the transport media, the splitter enables multiple devices to be serviced from a single inbound fiber. The passive optical splitter uses a series of silicon dioxide waveguides to split a fiber from one to two strands. The amount of outputs in the splitter determines the number of splits that occur. Approximately -3dB of loss occurs at each split, as shown here.
Silicon Dioxide Waveguides
> 3dB loss in 1310nm RV both directions at each 2x split 1490nm Tx
1x8 Splitter
For this 1x8 splitter example, a perfectly terminated and performing splitter would have a -9 dB loss per output.
Optical Network Terminal (ONT) The ONT is a device typically located near the work area outlet. The ONT provides conversion of GPON signals from optical to electrical for delivery to the end device. ONTs also provide AES encryption via a security key. The ONT typically has multiple Ethernet ports for connection to IP devices such as CPUs, phones, wireless access points, cameras, or other video components.
PON Equipment Vendor Options:
• Some ONTs support Power over Ethernet (WAPs, VoIP phones, etc.) IEEE802.3af, at
• Some ONTs support copper horizontal distances (100m)
• Redundancy for fiber facility and/or added equipment redundancy
• Remote powering and/or battery reserve at ONT
5 Link vs. Channel Attenuation (as defined by ANSI/TIA-568-C.0-2-2012) Link attenuation only includes cable, connectors, and splices (excludes active devices and splitters) Channel attenuation includes all passive components (cable, connectors, patch cords, splices, couplers, and splitters)
Transport media consists of:
1. Pre-terminated (recommended) or field terminated: • Multi-fiber backbone cable assemblies • Simplex backbone cable assemblies • Simplex horizontal cable assemblies
2. Fiber Optic Splitters (typically 1x16 or 1x32) • Can have redundant input capabilities (2x16 or 2x32)
3. Simplex fiber optic patch cords
4. Fiber optic connectors and couplers – Angled Polish Connector (APC) • Typically the SC/APC connector is used, but LC connector and UPC solutions are available
5. Copper patch cords (Category 6 or better recommended)
The ITU-T G.984 standard determines the minimum and maximum channel attenuation allowed over a maximum distance. ITU-T G.984 GPON Class B+ values are as follows:
Nominal Wavelength (nm), Wavelength Range {nm} 1270 1310 1490 1577 {1260-1280} {1260-1360} {1480-1500} {1575-1580} Application Upstream Downstream
Min. Channel Attenuation, dB 10 10 GPON Class B Max. Channel Attenuation, dB 25 25 (ITU-T G.984) Max. Supported Distance 20,000m (65,620 ft)
Min. Channel Attenuation, dB 13 13 GPON Class B+ Max. Channel Attenuation, dB 28 28 (ITU-T G.984) Max. Supported Distance 20,000m (65,620 ft)
Min. Channel Attenuation, dB 15 15 GPON Class C Max. Channel Attenuation, dB 30 30 (ITU-T G.984) Max. Supported Distance 20,000m (65,620 ft)
Min. Channel Attenuation, dB 17 17 GPON Class C+ Max. Channel Attenuation, dB 32 32 (ITU-T G.984) Max. Supported Distance 60,000m (196,850 ft)
Notes: The channel attenuation is the sum of all link attenuations and attenuation values for all passive components including splitters, couplers, and jumpers.
6 System Overview Using Leviton Components
Structured Media® and Zone enclosures: in-ceiling, wall-mount or below-floor consolidation points for plenum and non-plenum spaces to reduce the need for a TR SM drop cables complete connection from the passive splitter to the work area
Wireless Access Point (WAP) Splitter
ONT with copper or fiber patch cords makes the final connection to the user devices
Pre-terminated trunk cabling speeds deployment Opt-X fiber enclosures: in entrance facility or TR consolidation point for traditional distribution footprint
Secure and armored fiber patch cords available
QuickPort® wallplates and fiber connectors
7 Installation Options
Star/Hierarchical Star Topology
1. Follows traditional hierarchical star topology and uses common horizontal distribution methods from an Equipment Room (ER)/ localized Telecommunications Room (TR)
2. Uses existing TR located in a dedicated floor space on every floor
3. Requires longer horizontal cable runs and less backbone fiber
4. Allows interconnect or cross-connect methods at the ER/TR location
5. Allows easy access for IT personnel for any required maintenance, much of which is centralized away from office spaces
ISP Backbone from ER Optical Line Terminal Pre-terminated trunks or or field terminated fiber Aggregator Switch
ER/TR Inbound Fiber Field or pre-terminated fiber
Outbound Leg 1 of 32 Shown 1x32 Fiber Optic Adapter Plate Adapter PON Cassette
Fiber Optic Enclosure TR Horizontal Cabling to Workstation Field or pre-terminated fiber
Work Area Outlet Single-gang angled faceplate
Fiber Patch Cord
Optical Network Terminal (ONT)
Copper Patch Cord
Device Device
WAO
8 In this example of the traditional hierarchical star topology method, 1x32 splitters are located in the Telecommunications Room. Simplex, single-mode cables are installed from the Telecommunications Room to the Telecommunications Outlet.
STORAGE BREAK ROOM Legend OFFICE
Horizontal Cable Pathway
OFFICE RECEPTION (1) OS2 SM Fiber Port (UON)
(2) OS2 SM Fiber Ports (UON) OPEN OFFICE
AP AP AP OFFICE (1) GPON OS2 SM Port (AP)
WS WS WS WS WS WS
WS WS WS WS WS WS CONFERENCE ROOM
WS WS WS WS WS WS
OPEN OFFICE
CONFERENCE ROOM CONFERENCE WS WS WS WS WS WS ROOM
WS WS WS WS WS WS
AP AP
Fiber Optic Enclosure WS WS WS WS WS WS in the Telecommunications Room (Typical)
WS WS WS WS WS WS
WS WS WS WS WS WS
TRAINING ROOM
WS WS WS WS WS WS
AP COPY WS WS WS WS WS WS ROOM
AP TELECOM ROOM TELECOM ROOM
OFFICE RESTROOM
INP UT-1 INP UT-1 INP UT-1 1 1 1 1 1 1 1 1 1
INP UT-2 INP UT-2 INP UT-2 2 2 2 2 2 2 2 2 2 OFFICE RESTROOM 3 3 3 3 3 3 3 3 3 5 1 5 1 5 1 8 4 8 4 8 4 1 1 1 9 9 9 3 3 3 4 4 4 4 4 4 4 4 4 1 1 1 1 1 1 6 2 6 2 6 2 2 1 2 1 2 1 1 7 1 7 1 7
2 2 2 2 2 2 5 5 5 5 5 5 5 5 5 4 0 4 0 4 0 2 2 2 2 2 2 9 5 9 5 9 5 3 2 3 2 3 2
2 8 2 8 2 8 OFFICE OFFICE 6 6 6 6 6 6 6 6 6 OFFICE JANITORIAL
ELECTRICAL
9 Zone Distribution Topology
1. Allowed per ANSI/TIA standards. Requires additional design considerations from hierarchical star
2. Uses telecom enclosures located:
• Under raised floors;
• On or in wall;
• Mounted in an open ceiling space; or
• In or above a reflected ceiling
3. Requires longer backbone cabling and shorter horizontal fiber runs (less fiber cabling)
4. Uses enclosures which may be an added expense in existing environments or a lower-cost alternative in new environments (as opposed to needing a TR)
5. Allows interconnect or cross-connect at the enclosure location. Provides modularity and scalability
6. Allows easy access for IT personnel for any required maintenance, and minimizes the impact of moves, adds, and changes
Fiber Optic Enclosure
Optical Line Terminal or Aggregator Switch Fiber Optic Adapter Plate Fiber Optic Adapter Plate Fiber Optic Adapter Plate Fiber Optic Adapter Backbone Cabling from ER Main Equipment Room to Telecommunications Room 1RU enclosure serves up to 36 PON consolidation points Fiber Optic Adapter Plate
Fiber Optic Enclosure TR
Inbound Leg Horizontal fiber from TR 1x32 PON Splitter
Outbound Leg 1 of 32 Shown
Fiber Optic Adapter Plate Horizontal Cabling to Workstation Field or pre-terminated fiber Zone Enclosure CP
Work Area Outlet Single-gang angled faceplate
Device Fiber Patch Cord Optical Network Terminal (ONT)
Device
Copper Patch Cord WAO
10 In this example of the zone distribution topology method, simplex, single-mode cables are installed from the Telecommunications Room to the Zone Consolidation Point. 1x32 splitters are located at each consolidation point to allow for adequate redundancy and future expansion. Horizontal cables are installed from the feeding consolidation point to each telecommunications outlet.
STORAGE BREAK ROOM Legend OFFICE OFFICE GPON OS2 SM Consolidation Point (32-PORT UON)
Consolidation Point Zone Boundary RECEPTION
(1) OS2 SM Port (UON) OPEN OFFICE
Zone 6 Zone 1 (2) OS2 SM Ports (UON) AP Zone 11 AP OFFICE
WS WS WS WS WS WS AP (1) GPON OS2 SM Port (AP)
WS WS WS WS WS WS CONFERENCE ROOM
OPEN OFFICE
WS WS WS WS WS WS Connectivity in the Consolidation Point Enclosure Zone 12 Zone 7 Zone 2
CONFERENCE WS WS WS WS WS WS CONFERENCE ROOM ROOM
WS WS WS WS WS WS
AP AP Zone 8 Zone 13 Zone 3
WS WS WS WS WS WS
1
2
-
-
T T 1 4 9 12 17 20 25 28
U
U
6
5
4
3
2
1
6
5
4
3
2 1
P P 5 8 13 16 21 24 29 32
N
N
I
I
6
5
4
3
2 1
WS WS WS WS WS WS
WS WS WS WS WS WS TRAINING ROOM
Fiber Optic Enclosure Zone 14 Zone 9 Zone 4 in the Telecommunications Room (Typical)
WS WS WS WS WS WS AP
WS WS WS WS WS WS COPY ROOM
AP Zone 5 TELECOM ROOM Zone 15 Zone 10
OFFICE RESTROOMS
OFFICE RESTROOMS
OFFICE TELECOM ROOM OFFICE JANITORIAL OFFICE 1 2 3 4 5 6 1 2 3 4 5 6 ELECTRICAL
11 POLS Safety Issues
Working with, installing, and servicing fiber optic components requires special care, materials, and consideration. While LED and VCSEL laser sources operate at relatively low power levels, systems using fiber amplification (CATV and video links at 1550nm or Telco DWDM) can be damaging to the eyes. The correct and safe approach to take is to always verify the link is inactive and never look directly into the end of a fiber connector or port.
Testing
General Testing Guidelines POLS are tested the same way as traditionally installed fiber optic cabling. All cabling should be tested to ANSI or IEC standards, as applicable. It is essential to use reference-grade cords and proper inspection and cleaning practices for accurate and successful results.
For more information regarding testing methods and cleaning practices, visit Leviton’s series of Application Notes at: http://www.leviton.com/appnotes
Channel Optical Budget Channel Link Budget Sample Determining an attenuation budget prior to installation of 400ft (0.122km) Total Length the system is critical to verifying the system will function Total Loss Item Qty Loss (dB) properly as designed. The budget is calculated to factor (dB) Total Channel Link in the maximum loss allowed from each component of 0.122 -1 -0.122 Distance (km) the fiber channel. Total Fiber Splices 0 -0.3 0
• Required to determine a budget: Total Mated Fiber Pairs 7 -0.75 -5.25
Passive Fiber Splitter • Length of the cable used 1 -16.7 -16.7 (1x32)
• Properties of the cable used Total Estimated Channel Link Loss (dB) -22.072 • Type of fiber Actual Channel Link Attenuation • Physical topology of the cable plant Total Loss Item Qty Loss (dB) (dB) • Specifications of the equipment to be used Total Channel Link 0.122 -0.035 -0.00427 • Need for future changes or damage allowances Distance (km) Total Fiber Splices 0 -0.3 0 The chart to the right is an example of a Link Budget Total Mated Fiber Pairs 7 -0.32 -2.24 Calculation and the evaluation against actual loss data. Passive Fiber Splitter 1 -16.05 -16.05 (1x32) The maximum loss allowed for the channel per GPON Total Channel Link Loss (dB) -18.29427 Class B+ (ITU-T G.984) is -28dB.
Total Estimated Channel Link Loss (dB) 3.77773
Total Estimated Channel Link Loss (dB) 9.70573
Notes: 0.5dB/km loss allowance for outside plant fiber, 1.0dB/ km loss allowance for inside plant fiber, 0.3dB allowance for splices, 0.75dB allowance for mated pair connectors, splitter loss provided by manufacturer, includes the loss of all patch cords
12 Tier 1 Testing Tier 1 testing is required per ANSI/TIA and IEC standards. It is achieved by performing a visual inspection of the end face of all connectors, documenting the length via cable markings or testing apparatus, verifying polarity (if applicable), and using an optical power source and optical meter. The optical meter measures the end-to-end loss (attenuation in dB) of the link.
The recommended method is ANSI/TIA 526-7 method A.1, One Reference Jumper method. Testing needs to be performed unidirectionally or bi-directionally at the appropriate wavelengths (1490nm for the downstream and 1310 upstream). As most optical test sets operate at 1550, this wavelength is typically acceptable as a substitute for the 1490 wavelength as the difference in loss will be small. A PON power meter is capable of the specific wavelengths in use: 1310 upstream, 1490 downstream, and 1550nm (used for video BPON [Broadband PON] if applicable).
Tier 2 Testing Tier 2 testing is achieved by using an Optical Time Domain Reflectometer (OTDR). An OTDR sends pulses of light into an optical fiber and measures the strength of the power returned to the instrument as a function of time. The OTDR creates a graphical output (trace/picture) depicting the fiber link under test. The OTDR has the capability to measure the length of the fiber and estimate the loss between any two points along the fiber link.
Tier 2 testing is not required by ANSI/TIA standards and is not a substitute for Tier 1 certification. Tier 2 may be requested by the end user to provide added test detail and a historical benchmark for each individual link performance. OTDR testing is also valuable in determining cable attenuation and fault points during troubleshooting.
13 Troubleshooting
While there are often several components in the channel, troubleshooting a POLS system is relatively easy. The scenarios below address the probable fault points:
PON Troubleshooting Scenario 1: Simple PON - only one customer is affected When only one user cannot receive service, three potential faults are probable:
• Fault in the distribution fiber between the work area outlet and the closest splitter
• Fault in the ONT equipment
• Fault in the horizontal wiring
PON Troubleshooting Scenario 2: Multiple PON users affected from the same splitter When all customers connected to the same splitter cannot receive service, but others connected to the same OLT can, the cause may be because of one of the following:
• Fault at the splitter
• Fault in the fiber link between the OLT and splitter
PON Troubleshooting Scenario 3: All customers are affected (at the OLT level) Whether or not the PON is cascaded, all customers dependent on the same OLT may be affected. If all customers are affected, the cause may be from of the following:
• Fault at the splitter closest to the OLT
• Fault in the feeder fiber/cable of the fiber network
• Fault in the OLT equipment
14 Troubleshooting Schematic:
Device Device
SCENARIO 1: Copper Patch Cord • Fault in the horizontal fiber between the work Optical Network area outlet and Terminal (ONT) the splitter Fiber Patch Cord • Fault in the ONT equipment • Fault in the fiber Work Area Outlet connector or patch cords Faceplate, surface mount box, etc. • Fault in the copper patch cord to the device
Singlemode Fiber Qty: 1 to each Optical Network Terminal (ONT)
Horizontal Cabling
Telecommunications Room SCENARIO 2: or Consolidation Point Enclosure • Fault at the splitter Passive • Fault in the distribution Splitter fiber link between the TR OLT and splitter
ISP Backbone from ER Qty: 1 singlemode fiber SCENARIO 3: • Fault from the service provider or other active component prior Telecommunications Room to the circuit reaching the OLT Optical Line Terminal (OLT) • Fault in the distribution fiber link between the OLT and splitter • Fault in the feeder fiber/cable of the fiber network • Fault in the OLT equipment Circuit from Service Provider
Conclusion
POLS and GPON, while still a relatively new concept as a method for commercial structured FTTD cabling systems, are becoming more common due to flexibility, reduced physical footprint, improved physical and network security, and potential and realized cost savings. While not for every user or scenario, a carefully designed and properly commissioned POLS system will provide a scalable, bandwidth-rich and secure solution.
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