58.7.9 Transmitter and dispersion penalty (TDP) measurement ▶
58.7.9.1 Reference transmitter requirements
58.7.9.2 Channel requirements
58.7.9.3 Reference receiver requirements
58.7.9.4 Test procedure
58.7.9.5 Approximate measures of TDP (informative)
58.7.10 Receiver sensitivity measurements
58.7.11 Stressed receiver conformance test ▶
58.7.11.1 Stressed receiver conformance test block diagram
58.7.11.2 Stressed receiver conformance test signal characteristics and calibration
58.7.11.3 Stressed receiver conformance test procedure
58.7.11.4 Sinusoidal jitter for receiver conformance test
58.7.12 Jitter measurements (informative)
58.8 Environmental, safety and labeling ▶
58.8.1 General safety
58.8.2 Laser safety
58.8.3 Installation
58.8.4 Environment
58.8.5 PMD labeling requirements
58.9 Characteristics of the fiber optic cabling ▶
58.9.1 Fiber optic cabling model
58.9.2 Optical fiber and cable
58.9.3 Optical fiber connection
58.9.4 Medium Dependent Interface (MDI)
58.10 Protocol Implementation Conformance Statement (PICS) proforma for Clause 58, Physical Medium Dependent (PMD) sublayer and medium, type 100BASE-LX10 (Long Wavelength) and 100BASE-BX10 (BiDirectional Long Wave length) ▶
58.10.1 Introduction
58.10.2 Identification ▶
58.10.2.1 Implementation identification
58.10.2.2 Protocol summary
58.10.2.3 Major capabilities/options
58.10.3 PICS proforma tables for Physical Medium Dependent (PMD) sublayer and medium, type 100BASE-LX10 and 100BASE-BX10 ▶
58.10.3.1 PMD functional specifications
58.10.3.2 PMD to MDI optical specifications for 100BASE-LX10
58.10.3.3 PMD to MDI optical specifications for 100BASE-BX10-D
58.10.3.4 PMD to MDI optical specifications for 100BASE-BX10-U
58.10.3.5 Optical measurement requirements
58.10.3.6 Environmental specifications
58.10.3.7 Characteristics of the fiber optic cabling and MDI
59. Physical Medium Dependent (PMD) sublayer and medium, type 1000BASE-LX10 (Long Wavelength) and 1000BASE-BX10 (BiDirectional Long Wavelength) ▶
59.1 Overview ▶
59.1.1 Goals and objectives
59.1.2 Positioning of 1000BASE-LX10 and 1000BASE-BX10 PMDs within the IEEE 802.3 architecture
59.1.3 Terminology and conventions
59.1.4 Physical Medium Dependent (PMD) sublayer service interface
59.1.5 Delay constraints ▶
59.1.5.1 PMD_UNITDATA.request
59.1.5.2 PMD_UNITDATA.indicate
59.1.5.3 PMD_SIGNAL.indicate
59.2 PMD functional specifications ▶
59.2.1 PMD block diagram
59.2.2 PMD transmit function
59.2.3 PMD receive function
59.2.4 PMD signal detect function
59.3 PMD to MDI optical specifications for 1000BASE-LX10 ▶
59.3.1 Transmitter optical specifications
59.3.2 Receiver optical specifications
59.4 PMD to MDI optical specifications for 1000BASE-BX10-D and 1000BASE-BX10- U ▶
59.4.1 Transmit optical specifications
59.4.2 Receiver optical specifications
59.5 Illustrative 1000BASE-LX10 and 1000BASE-BX10 channels and penalties (informative)
59.6 Jitter specifications
59.7 Optical measurement requirements ▶
59.7.1 Test patterns
59.7.2 Wavelength and spectral width measurements
59.7.3 Optical power measurements
59.7.4 Extinction ratio measurements
59.7.5 OMA measurements (informative)
59.7.6 OMA relationship to extinction ratio and power measurements (informative)
59.7.13 Deterministic or high probability jitter measurement (informative)
59.7.14 Stressed receiver conformance test
59.7.15 Measurement of the receiver 3 dB electrical upper cutoff frequency
59.8 Environmental, safety and labeling specifications ▶
59.8.1 General Safety
59.8.2 Laser safety
59.8.3 Installation
59.8.4 Environment
59.8.5 PMD labelling requirements
59.9 Characteristics of the fiber optic cabling ▶
59.9.1 Fiber optic cabling model
59.9.2 Optical fiber and cable
59.9.3 Optical fiber connection
59.9.4 Medium Dependent Interface (MDI)
59.9.5 Single-mode fiber offset-launch mode-conditioning patch cord for MMF operation of 1000BASE-LX10
59.10 Protocol Implementation Conformance Statement (PICS) proforma for Clause 59, Physical Medium Dependent (PMD) sublayer and medium, type 1000BASE-LX10 (Long Wavelength) and 1000BASE-BX10 (BiDirectional Long Wavelength) ▶
59.10.1 Introduction
59.10.2 Identification ▶
59.10.2.1 Implementation identification
59.10.2.2 Protocol summary
59.10.3 Major capabilities/options ▶
59.10.3.1 PMD functional specifications
59.10.3.2 PMD to MDI optical specifications for 1000BASE-LX10
59.10.3.3 PMD to MDI optical specifications for 1000BASE-BX10-D
59.10.3.4 PMD to MDI optical specifications for 1000BASE-BX10-U
59.10.3.5 Optical Measurement Requirements
59.10.3.6 Environmental, safety and labeling specifications
59.10.3.7 Characteristics of the fiber optic cabling
60.10 Protocol Implementation Conformance Statement (PICS) proforma for Clause 60, Physical Medium Dependent (PMD) sublayer and medium, type 1000BASE- PX10 and 1000BASE-PX20 (long wavelength passive optical networks) ▶
60.10.1 Introduction
60.10.2 Identification ▶
60.10.2.1 Implementation identification
60.10.2.2 Protocol Summary
60.10.3 Major capabilities/options
60.10.4 PICS proforma tables for Physical Medium Dependent (PMD) sublayer and medium, type 1000BASE-PX10 and 1000BASE-PX20 (long wavelength passive optical networks) ▶
60.10.4.1 PMD functional specifications
60.10.4.2 PMD to MDI optical specifications for 1000BASE-PX10-D
60.10.4.3 PMD to MDI optical specifications for 1000BASE-PX10-U
60.10.4.4 PMD to MDI optical specifications for 1000BASE-PX20-D
60.10.4.5 PMD to MDI optical specifications for 1000BASE-PX20-U
60.10.4.6 Optical measurement requirements
60.10.4.7 Characteristics of the fiber optic cabling and MDI
60.10.4.8 Environmental specifications
61. Physical Coding Sublayer (PCS), Transmission Convergence (TC) sub layer, and common specifications, type 10PASS-TS and type 2BASE-TL ▶
61.1 Overview ▶
61.1.1 Scope
61.1.2 Objectives
61.1.3 Relation of 2BASE-TL and 10PASS-TS to other standards
61.1.4 Summary ▶
61.1.4.1 Summary of Physical Coding Sublayer (PCS) specification ▶
61.1.4.1.1 Implementation of Media Independent Interface
61.1.4.1.2 Summary of MAC-PHY Rate Matching specification
61.1.4.1.3 Summary of PME Aggregation specification
61.1.4.1.4 Overview of management
61.1.4.2 Summary of TC specification
61.1.4.3 Summary of handshaking and PHY control specification
61.1.5 Application of 2BASE-TL, 10PASS-TS ▶
61.1.5.1 Compatibility considerations
61.1.5.2 Incorporating the 2BASE-TL, 10PASS-TS PHY into a DTE
61.1.5.3 Application and examples of PME Aggregation ▶
61.10 Protocol Implementation Conformance Statement (PICS) proforma for Clause 61, Physical Coding Sublayer (PCS), Transmission Convergence (TC) sub layer, and common specifications type 10PASS-TS, 2BASE-TL ▶
61.10.1 Introduction
61.10.2 Identification ▶
61.10.2.1 Implementation identification
61.10.2.2 Protocol summary
61.10.3 Major capabilities/options
61.10.4 PICS proforma tables for the Physical Coding Sublayer (PCS), Transmission Con vergence (TC) sublayer, and common specifications type 10PASS-TS, 2BASE-TL ▶
61.10.4.1 MAC-PHY Rate Matching
61.10.4.2 64/65-octet Encapsulation
61.10.4.3 PME Aggregation
61.10.4.4 Handshaking
62. Physical Medium Attachment (PMA) and Physical Medium Dependent (PMD), type 10PASS-TS ▶
62.1 Overview ▶
62.1.1 Scope
62.1.2 Objectives
62.1.3 Relation of 10PASS-TS to other standards
62.1.4 Summary of Physical Medium Attachment (PMA) specification ▶
62.1.4.1 a(b)-interface
62.1.4.2 The I-interface ▶
62.1.4.2.1 The I Data Flow
62.1.4.2.2 The I Synchronization Flow
62.2 PMA functional specifications ▶
62.2.1 PMA functional diagram
62.2.2 PMA functional specifications
62.2.3 General exceptions
62.2.4 Specific requirements and exceptions ▶
62.2.4.1 Replacement of 9.3.1, MS-TC functional diagram /A>
62.2.4.2 Changes to 9.3.3, orward error correction /A>
62.2.4.3 Changes to 9.3.5, raming /A>
62.3 PMD functional specifications ▶
62.3.1 PMD Overview
62.3.2 PMD functional specifications
62.3.3 General exceptions
62.3.4 Specific requirements and exceptions ▶
62.3.4.1 Replacement of 8.2.1, ulti-carrier Modulation /A>
62.3.4.2 Changes to 8.2.2, yclic extension /A>
62.3.4.3 Changes to 8.2.3, ynchronization /A>
62.3.4.4 Replacement of 8.2.4, ower back-off in the upstream direction /A>
62.3.4.5 Changes to 8.2.5, onstellation encoder /A>
62.3.4.6 Changes to 8.2.8, -interface characteristics /A>
62.3.4.7 Changes to section 10, perations and maintenance /A>
62.3.4.8 Changes to 11.1, DSL Link State and Timing Diagram /A>
62.3.4.9 Changes to section 18 (Annex 4), andshake procedure for VDSL /A> ▶
62.3.4.9.1 Replacement of 18.1, ntroduction /A>
62.3.4.9.2 Replacement of 18.2, escription of signals /A>
62.3.4.9.3 Replacement of 18.3, essage coding format /A>
62.3.4.9.4 Replacement of 18.4.1. andshake - 10PASS-TS-O /A>
62.3.4.9.5 Replacement of 18.4.2, andshake - 10PASS-TS-R /A>
62.3.5 Transmission medium interface characteristics ▶
62.3.5.1 Transmit signal characteristics ▶
62.3.5.1.1 Wide-band power
62.3.5.1.2 Power spectral density (PSD)
62.3.5.1.3 Egress control
62.3.5.2 Termination impedance
62.3.5.3 Return loss
62.3.5.4 Output signal balance
62.4 Protocol Implementation Conformance Statement (PICS) proforma for Clause 62, Physical Medium Attachment (PMA) and Physical Medium Dependent (PMD), type 10PASS-TS ▶
62.4.1 Introduction
62.4.2 Identification ▶
62.4.2.1 Implementation identification
62.4.2.2 Protocol summary
62.4.3 Major capabilities/options
62.4.4 PICS proforma tables for the Physical Medium Attachment (PMA) and Physical Medium Dependent (PMD), type 10PASS-TS ▶
62.4.4.1 MCM-VDSL based PMA
62.4.4.2 MCM-VDSL based PMD
63. Physical Medium Attachment (PMA) and Physical Medium Dependent (PMD), type 2BASE-TL ▶
63.1 2BASE-TL Overview ▶
63.1.1 Scope
63.1.2 Objectives
63.1.3 Relation of 2BASE-TL to other standards
63.1.4 Summary of Physical Medium Attachment (PMA) specification ▶
63.1.4.1 a(b)-interface
63.1.4.2 The I-interface ▶
63.1.4.2.1 The I Data Flow
63.1.4.2.2 The I Synchronization Flow
63.1.4.3 Operation Channel (OC)
63.1.5 Summary of Physical Medium Dependent (PMD) specification
63.2 2BASE-TL PMA functional specifications ▶
63.2.1 General exceptions
63.2.2 Specific requirements and exceptions ▶
63.2.2.1 Changes to 7.1, ata Mode Operation /A>
63.2.2.2 Changes to section 9, anagement /A>
63.2.2.3 Relation between the 2BASE-TL registers and the SHDSL management functions
63.3 2BASE-TL PMD functional specifications ▶
63.3.1 General exceptions
63.3.2 Specific requirements and exceptions ▶
63.3.2.1 Replacement of section 5, ransport Capacity /A>
63.3.2.2 Changes to section 6, MD Layer Functional Characteristics /A>
63.3.2.3 Changes to section 10, lock Architecture /A>
63.3.2.4 Changes to Annex A, egional Requirements - Region 1 /A> ▶
63.3.2.4.1 General Changes
63.3.2.4.2 Additional requirement: wetting current
63.3.2.5 Changes to Annex B, egional Requirements - Region 2 /A> ▶
63.3.2.5.1 General Changes
63.3.2.5.2 Additional requirement: wetting current
63.3.2.6 Changes to Annex C, egional Requirements - Region 3 /A>
63.4 Protocol Implementation Conformance Statement (PICS) proforma for Clause 63, Physical Medium Attachment (PMA) and Physical Medium Dependent (PMD), type 2BASE-TL ▶
63.4.1 Introduction
63.4.2 Identification ▶
63.4.2.1 Implementation identification
63.4.2.2 Protocol summary
63.4.3 Major capabilities/options
63.4.4 PICS proforma tables for the Physical Medium Attachment (PMA) and Physical Medium Dependent (PMD) sublayers, type 2BASE-TL ▶
63.4.4.1 SHDSL based PMA
63.4.4.2 SHDSL based PMD
64. Multi-point MAC Control ▶
64.1 Overview ▶
64.1.1 Goals and objectives
64.1.2 Position of Multi-point MAC Control within the IEEE 802.3 hierarchy
64.1.3 Functional block diagram
64.1.4 Service interfaces
64.1.5 State diagram conventions
64.2 Multi-point MAC Control operation ▶
64.2.1 Principles of Multi-point MAC Control ▶
64.2.1.1 Ranging and Timing Process
64.2.2 Multi-point transmission control, Control Parser, and Control Multiplexer ▶
64.2.2.1 Constants
64.2.2.2 Counters
64.2.2.3 Variables
64.2.2.4 Functions
64.2.2.5 Timers
64.2.2.6 Messages
64.2.2.7 State Diagrams
64.3 Multi-Point Control Protocol (MPCP) ▶
64.3.1 Principles of Multi-Point Control Protocol
64.3.2 Compatibility considerations ▶
64.3.2.1 PAUSE operation
64.3.2.2 Optional Shared LAN Emulation
64.3.2.3 Multicast and single copy broadcast support
64.3.2.4 Delay requirements
64.3.3 Discovery Processing ▶
64.3.3.1 Constants
64.3.3.2 Variables
64.3.3.3 Functions
64.3.3.4 Timers
64.3.3.5 Messages
64.3.3.6 State Diagram
64.3.4 Report Processing ▶
64.3.4.1 Constants
64.3.4.2 Variables
64.3.4.3 Functions
64.3.4.4 Timers
64.3.4.5 Messages
64.3.4.6 State Diagram
64.3.5 Gate Processing ▶
64.3.5.1 Constants
64.3.5.2 Variables
64.3.5.3 Functions
64.3.5.4 Timers
64.3.5.5 Messages
64.3.5.6 State Diagrams
64.3.6 MPCPDU structure and encoding ▶
64.3.6.1 GATE description
64.3.6.2 REPORT description
64.3.6.3 REGISTER_REQ description
64.3.6.4 REGISTER description
64.3.6.5 REGISTER_ACK description
64.4 Protocol Implementation Conformance Statement (PICS) proforma for Clause 64, Multi-point MAC Control ▶
64.4.1 Introduction
64.4.2 Identification ▶
64.4.2.1 Implementation identification
64.4.2.2 Protocol summary
64.4.3 Major capabilities/options
64.4.4 PICS proforma tables for Multi-point MAC Control ▶
64.4.4.1 Compatibility Considerations
64.4.4.2 Multi-point MAC Control
64.4.4.3 State Machines
64.4.4.4 MPCP
65. Extensions of the Reconciliation Sublayer (RS) and Physical Coding Sublayer (PCS) / Physical Media Attachment (PMA) for 1000BASE-X for Multi-Point Links and Forward Error Correction ▶
65.1 Extensions of the Reconciliation Sublayer (RS) for Point to Point Emulation ▶
65.1.1 Overview
65.1.2 Principle of operation
65.1.3 Functional specifications ▶
65.1.3.1 Variables
65.1.3.2 Transmit ▶
65.1.3.2.1 SLD
65.1.3.2.2 LLID
65.1.3.2.3 CRC-8
65.1.3.3 Receive function ▶
b) use the location of the SLD field to locate the CRC8 field and verify that the received value matches the CRC calculated using the received data;
65.1.3.3.1 SLD
65.1.3.3.2 LLID ▶
a) the received mode bit is ignored
a) if the received mode bit is 0 and the received logical_link_id value matches the logical_link_id vari able then the comparison is considered a match;
65.1.3.3.3 CRC-8
65.2 Extensions of the physical coding sublayer for data detection and forward error correction ▶
65.2.1 Overview
65.2.2 Burst-mode operation ▶
65.2.2.1 Principle of operation
65.2.2.2 Detailed functions and state diagrams ▶
65.2.2.2.1 Variables
65.2.2.2.2 Functions
65.2.2.2.3 Messages
65.2.2.2.4 Counters
65.2.2.3 State Diagrams
65.2.3 Forward error correction ▶
65.2.3.1 FEC code
65.2.3.2 FEC frame format ▶
65.2.3.2.1 Placing parity octets
65.2.3.2.2 Shortened last block
65.2.3.2.3 Special frame markers
65.2.3.3 FEC sublayer operation ▶
65.2.3.3.1 Principles of operation
65.2.3.3.2 Functional block diagram
65.2.3.3.3 Transmission
65.2.3.3.4 Reception
65.2.3.4 Detailed functions and state diagrams ▶
65.2.3.4.1 State variables
65.2.3.4.2 Notation Conventions
65.2.3.4.3 Constants
65.2.3.4.4 Variables
65.2.3.4.5 Functions
65.2.3.4.6 Counters
65.2.3.4.7 Messages
65.2.3.5 State diagrams ▶
65.2.3.5.1 Transmit state diagram
65.2.3.5.2 Receive synchronization state diagram
65.2.3.5.3 Receive state diagram
65.2.3.6 Error monitoring capability ▶
65.2.3.6.1 buffer_head_coding_violation_counter
65.2.3.6.2 FEC_corrected_blocks_counter
65.2.3.6.3 FEC_uncorrected_Blocks_counter
65.3 Extensions to PMA for 1000BASE-PX ▶
65.3.1 Extensions for 1000BASE-PX-U ▶
65.3.1.1 Physical Medium Attachment (PMA) sublayer interfaces
65.3.1.2 Loop-timing specifications for ONUs
65.3.2 Extensions for 1000BASE-PX-D ▶
65.3.2.1 CDR lock timing measurement ▶
65.3.2.1.1 Definitions
65.3.2.1.2 Test specification
65.3.3 Delay variation requirements
65.4 Protocol Implementation Conformance Statement (PICS) proforma for Clause 65, Extensions of the Reconciliation Sublayer (RS) and Physical Coding Sublayer (PCS) / Physical Media Attachment (PMA) for 1000BASE-X for Multi-Point Links and For... ▶
65.4.1 Introduction
65.4.2 Identification ▶
65.4.2.1 Implementation identification
65.4.2.2 Protocol summary
65.4.3 Major capabilities/options
65.4.4 PICS proforma tables for Extensions of Reconciliation Sublayer (RS) and Physical Coding Sublayer (PCS) / Physical Media Attachment (PMA) for 1000BASE-X for Multi-Point Links and Forward Error Correction. ▶
65.4.4.1 Operating modes of OLT MACs
65.4.4.2 ONU and OLT variables
65.4.4.3 Preamble mapping and replacement
65.4.4.4 Data detection
65.4.4.5 FEC requirements
65.4.4.6 FEC state machines
65.4.4.7 PMA
65.4.4.8 Delay variation
66. Extensions of the 10 Gb/s Reconciliation Sublayer (RS), 100BASE-X PHY, and 1000BASE-X PHY for unidirectional transport ▶
66.1 Modifications to the physical coding sublayer (PCS) and physical medium attachment (PMA) sublayer, type 100BASE-X ▶
66.1.1 Overview
66.1.2 Functional specifications ▶
66.1.2.1 Variables
66.1.2.2 Transmit state diagram
66.1.2.3 Far-end fault generate
66.2 Modifications to the physical coding sublayer (PCS) and physical medium attachment (PMA) sublayer, type 1000BASE-X ▶
66.2.1 Overview
66.2.2 Functional specifications ▶
66.2.2.1 Variables
66.2.2.2 Transmit
66.2.2.3 Transmit state diagram
66.3 Modifications to the reconciliation sublayer (RS) for 10 Gb/s operation ▶
66.3.1 Overview
66.3.2 Functional specifications ▶
66.3.2.1 Link fault signaling
66.3.2.2 Variables
66.3.2.3 State Diagram ▶
a) link_fault = OK The RS shall send MAC frames as requested through the PLS service interface. In the absence of MAC frames, the RS shall generate Idle control characters.
b) link_fault = Local Fault If unidirectional_enable=FALSE, tThe RS shall continuously generate Remote Fault Sequence ordered_sets. If unidirectional_enable=TRUE, the RS shall send MAC frames as requested through the PLS ser vice interface. A...
c) link_fault = Remote Fault If unidirectional_enable=FALSE, tThe RS shall continuously generate Idle control characters. If unidirectional_enable=TRUE, the RS shall send MAC frames as requested through the PLS ser vice interface. In the abse...
66.4 Protocol Implementation Conformance Statement (PICS) proforma for Clause 66, Extensions of the 10 Gb/s Reconciliation Sublayer (RS), 100BASE-X PHY, and 1000BASE-X PHY for unidirectional transport ▶
66.4.1 Introduction
66.4.2 Identification ▶
66.4.2.1 Implementation identification
66.4.2.2 Protocol summary
66.4.3 Major capabilities/options
66.4.4 PICS proforma tables for Extensions of the 10 Gb/s Reconciliation Sublayer (RS), 100BASE-X PHY, and 1000BASE-X PHY for unidirectional transport ▶
66.4.4.1 Maintaining compatibility with 802.1 protocols
66.4.4.2 Extensions of the 100BASE-X PHY
66.4.4.3 Extensions of the 1000BASE-X PHY
66.4.4.4 Extensions of the 10 Gb/s RS
67. System considerations for Ethernet subscriber access networks ▶
67.1 Overview
67.2 Discussion and examples of EFM P2MP topologies ▶
67.2.1 Trade off between link span and split ratio
67.2.2 Single splitter topology
67.2.3 Tree-and-branch topology
67.2.4 Interoperability between certain 1000BASE-PX10 and 1000BASE-PX20
67.3 Hybrid Media topologies
67.4 Topology limitations
67.5 Deployment restrictions for subscriber access copper
67.6 Operations, Administration, and Maintenance ▶
