System for accessing a wavelength-division-multiplexed bidirectional optical fiber ring network

US 20020080443A1
Filed: 12/27/2000
Published: 06/27/2002
Est. Priority Date: 12/27/2000
Status: Active Grant

First Claim

Patent Images

1. A system for accessing a WDM bidirectional optical fiber ring network having a first network fiber for carrying WDM signals in a first direction and a second network fiber for carrying WDM signals in a second direction, each of the first and second network fibers for carrying up to W WDM signals each having a respective one of W distinct wavelengths, where W is a positive integer, the system comprising a network node coupled to a network access station having a transmitter and a receiver through transmitter access fiber means and receiver access fiber means, respectively, the transmitter for providing signals having respective ones of the W wavelengths, the receiver for receiving signals having respective ones of the W wavelengths, the network node intersecting the first and second network fibers and comprising a first and a second WADM each having a first input, a second input, a first output and a second outputs for each one of the W wavelengths, λ

, each of the first and second WADMs has a bar state, in which a signal having the wavelength λ

received at the first input of the WADM is provided to the first output of the WADM, and a signal having the wavelength λ

received at the second input of the WADM is provided at the second output of the WADM, for each one of the W wavelengths, λ

, each one of the first and second WADMs has a cross state, in which a signal having the wavelength λ

received at the first input of the WADM is provided at the second output of the WADM and a signal having the wavelength λ

received at the second input of the WADM is provided at the first output of the WADM, wherein the first input of the first WADM is coupled to the transmitter access fiber means;

the second input of the first WADM being coupled to receive signals on the first network fiber entering the network node;

the first output of the first WADM is coupled to the first input of the second WADM;

the second input of the first WADM is coupled to provide signals on the first network fiber leaving the network node;

the second input of the second WADM is coupled to receive signals on the second network fiber entering the network node;

the first output of the second WADM is coupled to the receiver access fiber means; and

the second output of the second WADM being coupled to provide signals on the second network fiber leaving the network node, and whereby if both the first and second WADMs are in the bar state for the wavelength λ

, a signal having the wavelength λ

on the first network fiber entering the network node passes through the network node unchanged to the first network fiber leaving the network node, and a signal having the wavelength λ

on the second network fiber entering the network node passes through the network node unchanged to the second network fiber leaving the network node;

if for the wavelength λ

the first WADM is in the cross state and the second WADM is in the bar state, a signal having the wavelength λ

on the first network fiber entering the network node is routed to the receiver of the network access station, and a signal having the wavelength λ

provided by the transmitter of the network access station is routed to the first network fiber leaving the network node, a signal having the wavelength λ

on the second network fiber entering the network node passing through the network node unchanged to the second network fiber leaving the network node; and

if for the wavelength λ

the first WADM is in the bar state and the second WADM is in the cross state, a signal having the wavelength λ

on the second network fiber entering the network node is routed to the receiver of the network access station, and a signal having the wavelength λ

provided by the transmitter of the network access station is routed to the second network optical fiber leaving the network node, a signal having the wavelength λ

on the first network fiber entering the network node passing through the network node unchanged to the first network fiber leaving the network node.

View all claims

1 Assignment

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

Disclosed is a system for accessing a wavelength-division-multiplexed (“WDM”), bidirectional optical fiber ring network having first and second network fibers for carrying WDM signals in opposite directions. The system comprises a network node intersecting the first and second fibers of the ring network. The network node is coupled to a network access station through a single pair of access fibers, the network access station having a single array of receiving elements and a single array of transmitting elements. The network node has two wavelength add drop multiplexers (“WADMs”) each having a first input, a second input, a first output and a second output, and being individually setable to a bar or cross state for each one of the wavelengths on the ring network. The first WADM has its first input coupled to one of the access fibers for carrying signals provided by the array of transmitting elements, its second input coupled to the first network fiber entering the network node, its first output coupled to the first input of the second WADM, and its second output coupled to the first network fiber leaving the network node. The second WADM has its first input coupled to the first output of the first WADM, its second input coupled to the second network fiber entering the network node, its first output coupled to the other access fiber providing signals to the array of receiving elements, and its second output coupled to the second network fiber leaving the network node. If for a given wavelength on the ring network, both the first and second WADMs are in the bar state, signals having the given wavelength pass through the network node in both directions undisturbed. If for a given wavelength on the ring network, the first WADM is in the bar state and the second WADM is in the cross state, a signal having the given wavelength on the first network fiber passes through the network node undisturbed. However, a signal having the given wavelength on the second network fiber is routed to the array of photodetectors so as to be dropped from the second network fiber, and a signal having the given wavelength provided by the array of transmitting elements is routed to the second network fiber leaving the network node. If for a given wavelength on the ring network the first WADM is in the cross state and the second WADM is in the bar state, a signal having the given wavelength on the first network fiber entering the network node is routed to the array of receiving elements, and a signal having the given wavelength provided by the array of transmitting elements is routed to the first network fiber leaving the network node. In the latter case, a signal having the given wavelength on the second network fiber entering the network node passes through the network node undisturbed to the second network fiber leaving the network node.

Citations

4 Claims

1. A system for accessing a WDM bidirectional optical fiber ring network having a first network fiber for carrying WDM signals in a first direction and a second network fiber for carrying WDM signals in a second direction, each of the first and second network fibers for carrying up to W WDM signals each having a respective one of W distinct wavelengths, where W is a positive integer, the system comprising a network node coupled to a network access station having a transmitter and a receiver through transmitter access fiber means and receiver access fiber means, respectively, the transmitter for providing signals having respective ones of the W wavelengths, the receiver for receiving signals having respective ones of the W wavelengths, the network node intersecting the first and second network fibers and comprising a first and a second WADM each having a first input, a second input, a first output and a second outputs for each one of the W wavelengths, λ
- , each of the first and second WADMs has a bar state, in which a signal having the wavelength λ
  
  received at the first input of the WADM is provided to the first output of the WADM, and a signal having the wavelength λ
  
  received at the second input of the WADM is provided at the second output of the WADM, for each one of the W wavelengths, λ
  
  , each one of the first and second WADMs has a cross state, in which a signal having the wavelength λ
  
  received at the first input of the WADM is provided at the second output of the WADM and a signal having the wavelength λ
  
  received at the second input of the WADM is provided at the first output of the WADM, wherein the first input of the first WADM is coupled to the transmitter access fiber means;
  
  the second input of the first WADM being coupled to receive signals on the first network fiber entering the network node;
  
  the first output of the first WADM is coupled to the first input of the second WADM;
  
  the second input of the first WADM is coupled to provide signals on the first network fiber leaving the network node;
  
  the second input of the second WADM is coupled to receive signals on the second network fiber entering the network node;
  
  the first output of the second WADM is coupled to the receiver access fiber means; and
  
  the second output of the second WADM being coupled to provide signals on the second network fiber leaving the network node, and whereby if both the first and second WADMs are in the bar state for the wavelength λ
  
  , a signal having the wavelength λ
  
  on the first network fiber entering the network node passes through the network node unchanged to the first network fiber leaving the network node, and a signal having the wavelength λ
  
  on the second network fiber entering the network node passes through the network node unchanged to the second network fiber leaving the network node;
  
  if for the wavelength λ
  
  the first WADM is in the cross state and the second WADM is in the bar state, a signal having the wavelength λ
  
  on the first network fiber entering the network node is routed to the receiver of the network access station, and a signal having the wavelength λ
  
  provided by the transmitter of the network access station is routed to the first network fiber leaving the network node, a signal having the wavelength λ
  
  on the second network fiber entering the network node passing through the network node unchanged to the second network fiber leaving the network node; and
  
  if for the wavelength λ
  
  the first WADM is in the bar state and the second WADM is in the cross state, a signal having the wavelength λ
  
  on the second network fiber entering the network node is routed to the receiver of the network access station, and a signal having the wavelength λ
  
  provided by the transmitter of the network access station is routed to the second network optical fiber leaving the network node, a signal having the wavelength λ
  
  on the first network fiber entering the network node passing through the network node unchanged to the first network fiber leaving the network node.
- View Dependent Claims (2, 3, 4)
- - 2. The system of claim 1, wherein the transmitter of the network access station comprises a transmitting element array for providing signals having respective ones of the W wavelengths;
    - the transmitter access fiber means comprises a transmitter access fiber coupled to the transmitting element array for providing to the network node signals having respective ones of the W wavelength provided by the transmitting element array;
      
      the receiver of the network access station comprises a receiving element array for receiving signals having respective ones of the W wavelengths; and
      
      the receiver access fiber means comprises a receiver access fiber for providing WDM signals having respective ones of the W wavelengths to the receiving element array, wherein each one of the first and second WADMs comprises a multiwavelength switch having a first input serving as first input of the respective WADM, a second input serving as the second input of the respective WADM, a first output serving as the first output of the respective WADM and a second output serving as the second output of the respective WADM, and wherein for each one of the W wavelengths, λ
      
      , the multiwavelength switch having a bar state, in which a signal having the wavelength λ
      
      received by the first input of the switch is provided at the first output of the switch, and a signal having the wavelength λ
      
      received by the second input of the switch is provided at the second output of the switch; and
      
      for each one of the W wavelengths, λ
      
      , the multiwavelength switch has a cross state, in which a signal having the wavelength λ
      
      received by the first input of the switch is provided at the second output of the switch and a signal having the wavelength λ
      
      received by the second input of the switch is provided at the first output of the switch.
  - 3. The system of claim 1, wherein the transmitter of the network access station comprises a transmitting element array for providing signals having respective ones of the W wavelengths, and the transmitter access fiber means comprises a transmitter access fiber coupled to the transmitting element array for providing to the network node WDM signals having respective ones of the wavelengths provided by the transmitting element array;
    - and the receiver of the network access station comprises a receiving element array for receiving signals having respective ones of the W wavelengths, and the receiver access fiber means comprises a receiver access fiber for providing to the receiving element array WDM signals having respective ones of the W wavelengths, wherein the first WADM comprises;
      
      a first wavelength division demultiplexer having an input coupled to receive WDM signals on the first network fiber entering the network node and having W single-wavelength outputs each corresponding to a respective one of the W wavelengths, individual ones of the W single-wavelength outputs each providing a demultiplexed one of the WDM signals on the first network fiber entering the network node having a wavelength corresponding to the output providing the demutiplexed signal, the input of the first wavelength division demultiplexer being the second input of the first WADM;
      
      a first group of W switches, each corresponding to a respective one of the W wavelengths and having a first input, a second input, a first output and a second output, each one of the switches of the first group having a bar state, in which a signal received by the first input of the switch is provided at the first output of the switch and a signal received by the second input of the switch is provided by the second output of the switch, each one of the switches of the first group having a cross state, in which a signal received by the first input of the switch is provided at the second output of the switch and a signal received by the second input of the switch is provided at the first output of the switch, the second output of each one of the switches of the first group being coupled to receive a respective one of the W outputs of the first demultiplexer corresponding to the same wavelength as the switch coupled thereto;
      
      a first wavelength division multiplexer having W single-wavelength inputs each corresponding to a respective one of the W wavelengths and being coupled to the second output of a respective one of the first group of switches corresponding to the same wavelength as the first multiplexer input coupled thereto, and having an output coupled to the first network fiber leaving the network node, the first wavelength division multiplexer multiplexing signals provided by the second outputs of respective ones of the first group of switches to provide at the output thereof corresponding WDM signals to be carried on the first network optical fiber leaving the network node, the output of the first wavelength division multiplexer being the second output of the first WADM; and
      
      a transmitter wavelength division demultiplexer having an input coupled to the transmitter access fiber to receive WDM signals provided by the transmitting element array of the network access station and having W outputs each corresponding to a respective one of the W wavelengths for providing a demultiplexed one of the signals provided by the transmitting element array having a wavelength corresponding to the output providing the demultiplexed signal, each one of the outputs of the transmitter wavelength division demultiplexer being provided to the first input of a respective one of the first group of switches corresponding to the same wavelength as the output coupled thereto, the input of the transmitter wavelength demultiplexer being the first input of the first WADM, wherein the second WADM comprises;
      
      a second wavelength division demultiplexer having an input coupled to receive WDM signals on the second network optical fiber entering the network node and having W single wavelength outputs each corresponding to a respective one of the W wavelengths, individual ones of the W single-wavelength outputs each providing a demultiplexed one of the signals carried on the second network fiber entering the network node having a wavelength corresponding to the output providing the demultiplexed signal, the input of the second wavelength division demultiplexer being the second input of the second WADM;
      
      a second group of W switches each corresponding to a respective one of the W wavelengths and having a first input, a second input, a first output and a second output, each one of the second group of switches having a bar state, in which a signal received by the first input of the switch is provided at the first output of the switch and a signal received by the second input of the switch is provided at the second output of the switch, each one of the second group of switches having a cross state, in which a signal received by the first input of the switch is provided at the second output of the switch and a signal received by the second input of the switch is provided at the first output of the switch, the second input of each one of the second group of switches being coupled to receive a respective one of the outputs of the second wavelength division demultiplexer corresponding to the same wavelength as the switch coupled thereto, the first input of each one of the second group of switches being coupled to receive the first output of a respective one of the first group of switches of the first WADM corresponding to the same wavelength, the first outputs of the first group of switches being collectively the first output of the first WADM, and the first inputs of the second group of switches being collectively the first input of the second WADM;
      
      a second wavelength division multiplexer having W single-wavelength inputs each corresponding to a respective one of the W wavelengths and being coupled to the second output of a respective one of the second group of switches corresponding to the same wavelength as the second multiplexer input coupled thereto, and having an output coupled to the second network fiber leaving the network node, the second wavelength division multiplexer for multiplexing signals provided at respective ones of the second outputs of the second group of switches to provide at the output thereof corresponding WDM signals on the second network optical fiber leaving the network node, the output of the second wavelength division multiplexer being the second output of the second WADM; and
      
      a receiver wavelength division multiplexer having W single-wavelength inputs each corresponding to a respective one of the W wavelengths and being coupled to receive the first output of a respective one of the second group of switches corresponding to the same wavelength as the receiver multiplexer input coupled thereto, and having an output coupled to the receiver access fiber, the receiver wavelength division multiplexer multplexing signals provided at individual ones of the first outputs of the second group of switches to provide corresponding WDM signals on the receiver access fiber, the output of the receiver wavelength division multiplexer being the first output of the second WADM, and whereby for each one of the first group of switches corresponding to a respective one of the W wavelengths, λ
      
      , and an individual one of the second group of switches corresponding to the same wavelength λ
      
      both being in the bar state, a signal having the wavelength λ
      
      on the first network fiber entering the network node passes through the network node unchanged to the first network fiber leaving the network node, and a signal having the wavelength λ
      
      on the second network fiber entering the network node passes through the network node unchanged to the second network fiber leaving the network node;
      
      for each one of the first group of switches corresponding to a respective one of the W wavelengths, λ
      
      , being in the cross state and an individual one of the second group of switches corresponding to the same wavelength λ
      
      being in the bar state, a signal having one the wavelengths A on the first network fiber entering the network node is routed to the receiving element array of the network access station, and a signal having the wavelength λ
      
      provided by the transmitting element array of the network access station is routed to the first network fiber leaving the network node, a signal having the wavelength λ
      
      on the second network fiber entering the network node passing through the network node unchanged to the second network fiber leaving the network node; and
      
      for each one of the first group of switches corresponding to a different one of the W wavelengths, λ
      
      , being in the bar state and an individual one of the second group of switches corresponding to the same wavelength λ
      
      being in the cross state, a signal having the wavelength λ
      
      on the second network fiber entering the network node is routed to the receiving element array of the network access station, and a signal having the wavelength λ
      
      provided by the transmitting element array of the network access station is routed to the second network fiber leaving the network node, a signal having the wavelength λ
      
      on the first network fiber entering the network node passing through the network node unchanged to the first network fiber leaving the network node.
  - 4. The system of claim 1, wherein the transmitter of the network access station comprises W individual transmitting elements each for providing signals having a respective one of the W wavelengths;
    - the transmitter access fiber means comprises W individual transmitter access fibers each corresponding to a respective one of the W wavelengths and being coupled to an individual one of the transmitting elements for providing signals having the corresponding wavelength to the network node;
      
      the receiver of the network access station comprises W individual receiving elements each for receiving signals having a respective one of the W wavelengths; and
      
      the receiver access fiber means comprises W individual receiver fibers each corresponding to a respective one of the W wavelengths and being coupled to a receiving element for receiving signals having the corresponding wavelength, wherein the first WADM of the network node comprises;
      
      a first wavelength division demultiplexer having an input coupled to receive WDM signals on the first network optical fiber entering the network node and W single-wavelength outputs each corresponding to a respective one of the W wavelengths, individual ones of the outputs of the first wavelength division demultiplexer each providing a demultiplexed one of the WDM signals on the first network optical fiber entering the network node having a wavelength corresponding to the output providing the demultiplexed signal, the input of the first wavelength division demultiplexer being the second input of the first WADM;
      
      a first group of switches each one corresponding to a respective one of the W wavelengths and having a first input, a second input, a first output and a second output, each one of the first group of switches having a bar state, in which a signal received by the first input of the switch is provided at the first output of the switch and a signal received by the second input of the switch is provided at the second output of the switch, each one of the first group of switches having a cross state, in which a signal received by the first input of the switch is provided at the second output of the switch and a signal received by the second input of the switch is provided at the first output of the switch, the first input of each one of the first group of switches being coupled to a respective one of the W transmitter access fibers corresponding to the same wavelength as the switch being coupled thereto, the second input of each one of the first group of switches being coupled to a respective one of the W outputs of the first wavelength division demultiplexer corresponding to the same wavelength as the switch being coupled thereto, the first input of each one of the first group of switches being coupled to a respective one of the W transmitter access fibers corresponding to the same wavelength as the switch being coupled thereto, the first inputs of the first group of switches being collectively the first input of the first WADM; and
      
      a first wavelength division multiplexer having W single-wavelength inputs each corresponding to a respective one of the W wavelengths and being coupled to the second output of an individual one of the first group of switches corresponding to the same wavelength, and having an output coupled to the first network fiber leaving the network node, the first wavelength division multiplexer multiplexing single-wavelength signals provided at the second outputs of individual ones of the first group of switches to provide corresponding WDM signals on the first network optical fiber leaving the network node, the output of the first wavelength division multiplexer being the second output of the first WADM, wherein the second WADM of the network node comprises;
      
      a second wavelength division demultiplexer having an input coupled to receive WDM signals on the second network optical fiber entering the network node and having W outputs each corresponding to a respective one of the W wavelengths, individual ones of the W outputs of the second wavelength division demultiplexer each providing a demultiplexed one of the WDM signals on the second fiber entering the network node having a wavelength corresponding to the output providing the demultiplexed signal, the input of the second wavelength division demultiplexer being the second input of the second WADM;
      
      a second group of switches each corresponding to a respective one of the W wavelengths and having a first input, a second input, a first output and a second output, each one of the second group of switches having a bar state in which a signal received by the first input of the switch is provided at the first output of the switch and a signal received by the second input of the switch is provided at the second output of the switch, each one of the second group of switches having a cross state in which a signal received by the first input of the switch is provided at the second output of the switch and a signal received by the second input of the switch is provided at the first output of the switch, the first input of each one of the second group of switches being coupled to the first output of a respective one of the first group of switches in the first WADM corresponding to the same wavelength, the second input of each one of the second group of switches being coupled to a respective one of the W outputs of the second wavelength division demultiplexer corresponding to the same wavelength as the switch being coupled thereto, the first output of each one of the second group of switches being coupled to a respective one of the W receiver access fibers corresponding to same wavelength as the switch being coupled thereto, the first outputs of the first group of switches of the first WADM being collectively the first output of the first WADM, the first inputs of the second group of switches being collectively the first input of the second WADM, the first outputs of the second group of switches being collectively the first output of the second WADM; and
      
      a second wavelength division multiplexer having W inputs each corresponding to a respective one of the W wavelengths and being coupled to the second output of a respective one of the second group of switches corresponding to the same wavelength as the second multiplexer input coupled thereto, and having an output coupled to the second network fiber leaving the network node, the second wavelength division multiplexer multiplexing single- wavelength signals provided by the second outputs of respective ones the second group of switches to provide corresponding WDM signals on the second network optical fiber leaving the network node,and whereby for each one of the first group of switches corresponding to a respective one of the W wavelengths, λ
      
      , and an individual one of the second group of switches corresponding to the same wavelength λ
      
      both being in the bar state, a signal having the wavelength λ
      
      on the first network fiber entering the network node passes through the network node unchanged to the first network fiber leaving the network node and a signal having the wavelength λ
      
      on the second network fiber entering the network node passes through the network node unchanged to the second network fiber leaving the network node;
      
      for each one of the first group of switches corresponding to a respective one of the W wavelengths, λ
      
      , being in the cross state and an individual one of the second group of switches corresponding to the same wavelength λ
      
      being in the bar state, a signal having the wavelength λ
      
      on the first network fiber entering the network node is routed to a respective one of the receiving elements for receiving signals having the wavelength λ
      
      , and a signal having the wavelength λ
      
      provided by a respective one of the transmitting elements for providing signals of wavelength λ
      
      is routed to the first network fiber leaving the network node, a signal having the wavelength λ
      
      on the second network fiber entering the network node passing through the network node unchanged to the second network fiber leaving the network node; and
      
      for each one of the first group of switches corresponding to a respective one of the W wavelengths, λ
      
      , being in the bar state and an individual one of the second group of switches corresponding to the same wavelength λ
      
      being in the cross state, a signal having the wavelength λ
      
      on the second network fiber entering the network node is routed to a respective one of the receiving elements for receiving signals having the wavelength λ
      
      , and a signal having the wavelength λ
      
      provided by a respective one of the transmitting elements for providing signals having the wavelength λ
      
      is routed to the second network fiber leaving the network node, a signal having the wavelength λ
      
      on the first network fiber entering the network node passing through the network node unchanged to the first network fiber leaving the network node.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Trustees Of Columbia University In The City Of New York (Columbia University)
Original Assignee
Trustees Of Columbia University In The City Of New York (Columbia University)
Inventors
Stern, Thomas E.

Granted Patent

US 6,895,186 B2
Time in Patent Office

Days
Field of Search
US Class Current

398/82
CPC Class Codes

H04J 14/0201   Add-and-drop multiplexing

H04J 14/0227   Operation, administration, ...

H04J 14/0241   Wavelength allocation for c...

H04J 14/0283   WDM ring architectures

H04J 14/0295   Shared protection at the op...

System for accessing a wavelength-division-multiplexed bidirectional optical fiber ring network

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

Citations

4 Claims

Specification

Solutions

Use Cases

Quick Links

System for accessing a wavelength-division-multiplexed bidirectional optical fiber ring network

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

Citations

4 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links