POWER SAVING CONTROL METHOD AND NODE DEVICE IN OPTICAL COMMUNICATION NETWORK

US 20130279918A1
Filed: 12/05/2011
Published: 10/24/2013
Est. Priority Date: 12/06/2010
Status: Abandoned Application

First Claim

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1. A node device in an optical communication network system, comprising:

a plurality of optical transceivers on which a plurality of standby modes can be selectively set, wherein the standby modes include a first standby mode in which a startup period is shorter than an allowable interruption period in the optical communication system and a first amount of power is consumed during standby, and a second standby mode in which the startup period is longer than the allowable interruption period and a second amount of power that is smaller than the first amount of power is consumed during standby; and

a power consumption controller which, based on usage states of the plurality of optical transceivers and a predetermined number of optical transceivers that should stand by in the first standby mode, dynamically allocates the plurality of standby modes to the plurality of optical transceiver means so that a total amount of power consumption of the node device will be smaller.

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Abstract

A node device and a power saving method in an optical communication network system that can achieve both of a reduction in startup period and a reduction in power consumption. A node device (110) includes: a plurality of optical transceivers (111) on which a plurality of standby modes can be selectively set, the standby modes including a first standby mode in which the startup period is shorter than an allowable interruption period in the optical communication system and a first amount of power is consumed during standby, and a second standby mode in which the startup period is longer than the allowable interruption period and a second amount of power that is smaller than the first amount of power is consumed during standby; and a power consumption control section (112) which, based on usage states of the plurality of optical transceivers and a predetermined number of optical transceivers that should stand by in the first standby mode, dynamically allocates the plurality of standby modes to the plurality of optical transceivers so that a total amount of power consumption will be smaller.

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21 Claims

1. A node device in an optical communication network system, comprising:
- a plurality of optical transceivers on which a plurality of standby modes can be selectively set, wherein the standby modes include a first standby mode in which a startup period is shorter than an allowable interruption period in the optical communication system and a first amount of power is consumed during standby, and a second standby mode in which the startup period is longer than the allowable interruption period and a second amount of power that is smaller than the first amount of power is consumed during standby; and
  
  a power consumption controller which, based on usage states of the plurality of optical transceivers and a predetermined number of optical transceivers that should stand by in the first standby mode, dynamically allocates the plurality of standby modes to the plurality of optical transceiver means so that a total amount of power consumption of the node device will be smaller.
- View Dependent Claims (2, 3, 4, 5, 6, 7)
- - 2. The node device according to claim 1, wherein the predetermined number of optical transceivers that should stand by in the first standby mode is set based on any of a number of directions connected to the node device, a total number of paths set in the directions, and a change in the total number of paths set in the directions.
  - 3. The node device according to claim 1, wherein when newly starting up an optical transceiver, the power consumption controller selects and starts up an optical transceiver standing by in the first standby mode among the plurality of optical transceivers.
  - 4. The node device according to claim 1, wherein when a number of optical transceivers standing by in the first standby mode is not the predetermined number, the power consumption controller changes a standby mode of an optical transceiver standing by in the first standby mode or in the second standby mode so that the number of optical transceivers standing by in the first standby mode will be the predetermined number.
  - 5. The node device according to claim 1, wherein the first standby mode comprises a backup mode for allowing an optical transceiver to stand by as a backup for another running optical transceiver.
  - 6. The node device according to claim 5, wherein the plurality of standby modes include a third standby mode in which the startup period is longer than that of the backup mode and shorter than the allowable interruption period, and for power consumption during standby, a third amount of power that is smaller than the first amount of power and larger than the second amount of power is consumed.
  - 7. The node device according to claim 1, further comprising a plurality of direction selectors which are connected to the plurality of optical transceivers and collectively and selectively transmit/receive a plurality of optical signals to/from different directions on a network side,wherein each of the plurality of direction selectors can be set in a plurality of direction selection standby modes including a fourth standby mode in which the startup period is shorter than the allowable interruption period in the optical communication system and a fourth amount of power is consumed during standby, and a fifth standby mode in which the startup period is longer than the allowable interruption period and a fifth amount of power that is smaller than the fourth amount of power is consumed during standby, andthe power consumption controller dynamically allocates the plurality of direction selection standby modes to the plurality of direction selectors so that a number of direction selectors in the fifth standby mode will be increased while the number of optical transceiver in the first standby mode is maintained.

8. A power saving control method for a node device in an optical communication network system, the node device including a plurality of optical transceivers on which a plurality of standby modes can be selectively set, the method comprising:
- making available a first standby mode in which a startup period is shorter than an allowable interruption period in the optical communication system and a first amount of power is consumed during standby, and a second standby mode in which the startup period is longer than the allowable interruption period and a second amount of power that is smaller than the first amount of power is consumed during standby; and
  
  based on usage states of the plurality of optical transceivers and a predetermined number of optical transceivers that should stand by in the first standby mode, dynamically allocating the plurality of standby modes to the plurality of optical transceivers so that a total amount of power consumption of the node device will be smaller.
- View Dependent Claims (11, 12, 13, 14, 15, 16)
- - 11. The power saving control method according to claim 8, wherein the predetermined number of optical transceivers that should stand by in the first standby mode is set based on any of a number of directions connected to the node device, a total number of paths set in the directions, and a change in the total number of paths set in the directions.
  - 12. The power saving control method according to claim 8, wherein when newly starting up an optical transceiver, an optical transceiver standing by in the first standby mode among the plurality of optical transceivers is selected and started up.
  - 13. The power saving control method according to claim 8, wherein when a number of optical transceivers standing by in the first standby mode is not the predetermined number, a standby mode of an optical transceiver standing by in the first standby mode or in the second standby mode is changed so that the number of optical transceivers standing by in the first standby mode will be the predetermined number.
  - 14. The power saving control method according to claim 8, wherein the first standby mode comprises a backup mode for allowing a first optical transceiver to stand by as a backup for another running optical transceiver.
  - 15. The power saving control method according to claim 14, wherein the plurality of standby modes include a third standby mode in which the startup period is longer than that of the backup mode and shorter than the allowable interruption period, and for power consumption during standby, a third amount of power that is smaller than the first amount of power and larger than the second amount of power is consumed.
  - 16. The power saving control method according to claim 8, whereinthe node device further comprises a plurality of direction selectors which are connected to the plurality of optical transceivers and collectively and selectively transmit/receive a plurality of optical signals to/from different directions on a network side,wherein each of the plurality of direction selectors can be set in a plurality of direction selection standby modes including a fourth standby mode in which the startup period is shorter than the allowable interruption period in the optical communication system and a fourth amount of power is consumed during standby, and a fifth standby mode in which the startup period is longer than the allowable interruption period and a fifth amount of power that is smaller than the fourth amount of power is consumed during standby, andthe plurality of direction selection standby modes are dynamically allocated to the plurality of direction selectors so that a number of direction selectors in the fifth standby mode will be increased while the number of optical transceiver in the first standby mode is maintained.

9. An optical communication network system in which a plurality of node devices are connected through a plurality of optical fiber lines,wherein each of the node devices includes a plurality of optical transceivers on which a plurality of standby modes can be selectively set, the standby modes including a first standby mode in which a startup period is shorter than an allowable interruption period in the optical communication system and a first amount of power is consumed during standby, and a second standby mode in which the startup period is longer than the allowable interruption period and a second amount of power that is smaller than the first amount of power is consumed during standby,the system comprising:
- a network controller which sets a predetermined number of optical transceivers that should stand by in the first standby mode for each of the node devices and controls communication performed by the node devices; and
  
  a power consumption controller which, based on usage states of the plurality of optical transceivers and the predetermined number of optical transceivers that should stand by in the first standby mode, dynamically allocates the plurality of standby modes to the plurality of optical transceivers so that a total amount of power consumption of a relevant node device will be smaller.
- View Dependent Claims (17, 18, 19, 20, 21)
- - 17. The optical communication network system according to claim 9, wherein the predetermined number of optical transceivers that should stand by in the first standby mode is set based on any of a number of directions connected to the node device, a total number of paths set in the directions, and a change in the total number of paths set in the directions.
  - 18. The optical communication network system according to claim 9, wherein when newly starting up an optical transceiver, the power consumption controller selects and starts up an optical transceiver standing by in the first standby mode among the plurality of optical transceivers.
  - 19. The optical communication network system according to claim 9, wherein when a number of optical transceivers standing by in the first standby mode is not the predetermined number, the power consumption controller changes a standby mode of an optical transceiver standing by in the first standby mode or in the second standby mode so that the number of optical transceivers standing by in the first standby mode will be the predetermined number.
  - 20. The optical communication network system according to claim 9, wherein the first standby mode comprises a backup mode for allowing an optical transceiver to stand by as a backup for another running optical transceiver.
  - 21. The optical communication network system according to claim 19, wherein the plurality of standby modes include a third standby mode in which the startup period is longer than that of the backup mode and shorter than the allowable interruption period, and for power consumption during standby, a third amount of power that is smaller than the first amount of power and larger than the second amount of power is consumed.

10. (canceled)

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Current Assignee
NEC Corporation
Original Assignee
NEC Corporation
Inventors
Mizutani, Kenji, Sakauchi, Masahiro

Application Number

US13/991,970
Publication Number

US 20130279918A1
Time in Patent Office

Days
Field of Search
US Class Current

398/135
CPC Class Codes

H04B 10/27   Arrangements for networking

H04J 14/0227   Operation, administration, ...

H04J 14/0278   WDM optical network archite...

H04L 12/12   Arrangements for remote con...

Y02D 30/50   in wire-line communication ...

POWER SAVING CONTROL METHOD AND NODE DEVICE IN OPTICAL COMMUNICATION NETWORK

First Claim

1 Assignment

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Abstract

17 Citations

21 Claims

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POWER SAVING CONTROL METHOD AND NODE DEVICE IN OPTICAL COMMUNICATION NETWORK

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

17 Citations

21 Claims

Specification

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Solutions

Use Cases

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