JP2008172852A - Communication device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication device for activating/deactivating power supply modules in response to a circuit constitution within an apparatus and a communication state, and suppressing a power consumption. <P>SOLUTION: A control circuit 30 of the communication device 100 includes an apparatus load managing module 38, an apparatus load information section 37, and a power supply managing section 36. The power consumption is obtained from the number of printed boards 20, 30, 40 mounted in the communication device 100, and the number of active ports in a communication circuit 40. The optimal number of the power supply modules 10 are operated. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a communication device such as a router and a switch, and relates to a communication device that operates / stops a power supply module according to a circuit configuration and a communication state in the apparatus.

  In communication equipment such as routers and switches, power supply modules for the maximum power when all circuits are mounted are often mounted. Depending on the device configuration of the mounted circuit, more than necessary power supply modules are mounted and the power capacity May become extra.

The power supply module changes in conversion efficiency characteristics according to the load status of the apparatus. For example, when the conversion efficiency characteristic of the power supply module is in the range of 30% (1A) to 90% (15A), the conversion efficiency is 90% and the conversion efficiency is good at the maximum load (15A) of the device. Is 1 A, the conversion efficiency is extremely deteriorated to 30%. In conventional power supply control in which a plurality of power supply modules are mounted and operated in parallel, the required power consumption may be extremely less than the maximum power supply capacity of the installed power supply module depending on the actual device configuration and operation state. However, even in this case, all the power supply modules are equally operated in parallel with a low device load (1A). For example, even when three power supply modules are mounted and power can be supplied by one power supply module, power supply capacity is evenly distributed to the three power supply modules and power is supplied to the circuit side. In this case, the load on the device of each power supply module is low, the conversion efficiency is poor as described above, and sometimes 30%.
Since communication devices such as routers and switches do not enter a sleep state, use in a state where conversion efficiency is low is also contrary to energy saving.

  As conversion efficiency in the power supply module deteriorates, the loss of the power supply module increases and power consumption increases. In addition, by constantly operating all power supply modules with a low device load, the life of the power supply modules has been shortened.

  In order to solve the above-described problems, the present invention reduces the number of power supply modules that operate according to the number of switching circuits, control circuits, and communication circuits in the apparatus and the number of communication port active states (link-up states) of the communication circuits. Optimizing and improving the efficiency of the power supply module to reduce device power consumption.

  According to the present invention, power consumption of a communication device can be suppressed.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to FIGS. Note that the same reference numerals are assigned to the same parts, and description thereof is not repeated. Here, FIG. 1 is a hardware block diagram of the communication device. FIG. 2 is a hardware block diagram of a control circuit of the communication device. FIG. 3 is a diagram for explaining a circuit mounting table. FIG. 4 is a diagram for explaining the power supply module mounting table. FIG. 5 is a diagram for explaining the port state table. FIG. 6 is a diagram for explaining the power supply module operation number table. FIG. 7 is a processing flow diagram of the communication device.

  In FIG. 1, a communication device 100 includes a plurality of power supply modules 10, a plurality of communication circuits 40, a redundantly configured switching circuit 20, a redundantly configured control circuit 30, and a bus 60 that connects them. Is done. The power supply modules 10-1 to 10-4 are connected to an external power supply, perform voltage conversion inside, and supply power to the apparatus. The switching circuit 20-1 and the switching circuit 20-2 switch communication data of each communication circuit 40. The control circuit 30-1 and the control circuit 30-2 are configured by a CPU, a memory, an internal communication interface, and the like, and control the entire apparatus. Further, the control circuit 30-1 includes a power supply control unit 35 that controls the power supply module 10. Specifically, the power supply control unit 35 controls the operation and stop of the four power supply modules including the power supply modules 10-1 to 10-4. The communication circuit 40 accommodates communication ports 50-1 to 50-48 for exchanging communication data.

  In FIG. 2, the control circuit 30 includes a power supply control unit 35 and an apparatus load management module unit 38. The power supply control unit 35 includes a power supply module management unit 36 and a device load information unit. The device load management module unit 38 actually performs communication data exchange among the number of mounted control circuits 30, the number of mounted switching circuits 20, the number of mounted communication circuits 40, and the communication port 50 accommodated in the communication circuit 40. The port status (link up status), the number of ports, etc. are periodically monitored, and this information is stored in the device load information section 37. The power supply module management unit 36 controls the operation and stop of the mounted power supply module according to the information in the device load information unit 37.

  In FIG. 3, a circuit mounting table 110 is a table for recording information on a printed circuit board connected to the bus 60-2. The circuit mounting table 110 includes a slot 111, a circuit 112, power consumption 113, and a state 114. The circuit mounting table 110 records the circuit name of the printed board inserted into the slot, the design power consumption, and the presence / absence of the printed board detected by the slot 60-2 in the slot number record. The control circuit 1 of the circuit 112 is the control circuit 30-1, and the other is the same. The hexadecimal value of the power consumption 113 is a value that the circuit mounting table 110 actually has. The state 114 “1” means that the printed circuit board is mounted, and “0” means that it is not mounted. The presence or absence of mounting is determined by the presence or absence of sensing pins provided on the printed circuit board. The circuit mounting table 110 is a table that the device load information unit 37 has.

  In FIG. 4, the power supply module table 120 is a table for recording information of the power supply module 10 connected to the bus 60-1. The power module table 120 includes a slot 121, a power module 122, a supplied power 123, a state 124, a control 125, and a total operation time 126. The power supply module table 120 includes a power supply module number (corresponding to 1 of the power supply module 10-1) to be inserted into the slot in the slot number record, supply power, whether or not the power supply module detected by the slot 60-1 is installed, The control (operation / stop) of the module management unit 36 and the total operation time are recorded. The state 124 “1” means that the power supply module is mounted, and “0” means that it is not mounted. The presence or absence of mounting is determined by the presence or absence of sensing pins provided on the power supply module substrate. In the control 125, “1” means that the power supply module is operating, and “0” means that it is not operating. The power supply module table 120 is a table that the power supply module management unit 36 has. In the state of FIG. 4, four power supply modules are mounted, but only the power supply modules 10-1 and 10-2 are operating.

  In FIG. 5, a port state table 130-1 is a table for managing information on the port of the communication circuit 40-1. The port status table 130-1 includes a port number 131-1 and a status 132-1. The port status table 130-1 is a table that records whether the port is active or inactive in the status 132-1 of the port number record. In the state 132-1, “1” means active (link up), and “0” means inactive (link down). The port state table 130-1 is a table that the device load management module unit 38 has. In the state of FIG. 5, since the ports 1 to 24 are active and the ports 25 to 48 are inactive, the power consumption of the communication circuit 40-1 is 75 W, which is half of 150 W recorded in the record of the slot 5 of FIG. .

  In FIG. 6, the power module operating number table 140 describes the number of power modules to be operated based on the power consumption of each circuit of the communication device 100. The power supply module operation number table 140 includes a power consumption category 141 and an operation power supply module 142. The power module operating number table 140 is a table held by the power module management unit 36. The power supply module management unit 36 refers to the power supply module operation number table 140 based on the device load information (power consumption information) from the device load information unit 37 and determines the number of operating power supply modules 10.

  The operation of the control circuit 30 will be described with reference to FIG. When the power of the communication device is turned on, the control circuit 30 monitors the power interruption (S11). If YES, the control circuit 30 ends. If NO, the module 38 detects the number of power supply modules mounted and the number of printed circuit boards between the device loads (S12). The module 38 also checks the link-up number of the communication port between the device loads (S13). The power supply module management unit 36 calculates power consumption and determines the number of power supply modules to be operated (S14). It is determined whether there is a change in the number of power supply modules to be operated (S15). If NO, the process returns to step 11. If YES in step 15, the power supply module management unit 36 stops or operates the power supply module (S16), and returns to step 11.

  When stopping the power supply module in step 16, the power supply module table 120 is referred to and the module having the longest operating time is stopped during operation. Similarly, when operating the power supply module in step 16, the power supply module table 120 is referred to, and the module with the shortest total operation time is operated while stopped. That is, when the number of operating units is increased to 3 from the state of the power module table 120 shown in FIG. 4 (2 operating units), the power source module 4 is selected as an operation target, and conversely, when the operating unit number is reduced to 1. The power supply module 1 is selected as a stop target. By operating in this way, variation in the number of operating hours of the power supply module can be suppressed and the life of the entire power supply module can be extended.

  Further, when there is little change in the number of operating power supply modules, the regularly operated modules may be replaced. At this time, the power supply module having the shortest operation time during operation is operated, and then the power supply having the longest operation time during operation is stopped.

  As an actual control method, at least one control circuit 30 for periodically monitoring the number of mounted circuits and the number of active states (link-up states) of communication ports accommodated in the communication circuit is mounted. As for the number of active states (link up state) of the communication port 50 of the communication circuit 40, the control circuit 30 determines whether the communication port 50-1 to the communication port 50-48 of the communication circuit 40 is active (link up state). A state (0 (inactive), 1 (active)) signal is sent to the switching circuit 20 to start communication exchange using only the active (link-up) communication port. Note that this monitoring is always performed, and in particular, a change in the active state (link up state) of the communication port of the communication circuit is instantly dealt with.

  Specifically, FIG. 1 in which two switching circuits, two control circuits, eight communication circuits, 48 communication port numbers of communication circuits, and four power supply modules are mounted will be described. The power consumption of the switching circuit 20 is 500 W, the power consumption of the control circuit 30 is 50 W, and the rated power consumption of the communication circuit 40 is 150 W. Each power supply module 10 can supply 500 W. When the number of mounted circuits during operation is one switching circuit (500 W), one control circuit (50 W), four communication circuits (150 W × 4 = 600 W), and all 48 communication ports are active (link up state) Becomes a total of 1150 W as a device, and three power supply modules are in operation.

  In this way, the power control method according to the present embodiment is characterized by monitoring the number of active states (link-up states) of communication ports in the communication circuit in addition to the number of circuits mounted on the device. By grasping the power consumption value in the control circuit 30 and moving only the power supply module required for the device according to the number of circuit mounted and the communication state (link up state) of the communication port mounted in the communication circuit, It is intended to improve power supply efficiency and suppress device power consumption, and to improve the life of power supply modules that are not used.

  According to the above-described embodiment, the number of operating power supply modules is optimized according to the number of switching circuits, control circuits, communication circuits in the apparatus, and the number of communication port active states (link-up states) of the communication circuits. Thus, it is possible to improve the efficiency of the power supply module that operates in the above-described manner and suppress the power consumption of the apparatus. In addition, by optimizing the number of operating power supply modules according to the number of switching circuits, control circuits, communication circuits in the device, and the number of communicable ports in the communication circuit active state (link-up state) It is possible to improve the service life of the power supply module.

It is a hardware block diagram of a communication apparatus. It is a hardware block diagram of the control circuit of a communication apparatus. It is a figure explaining a circuit mounting table. It is a figure explaining a power supply module mounting table. It is a figure explaining a port state table. It is a figure explaining a power module operating number table. It is a processing flow figure of a communication apparatus.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Power supply module, 20 ... Switching circuit, 30 ... Control circuit, 35 ... Power supply control part, 36 ... Power supply module management part, 37 ... Apparatus load information part, 38 ... Apparatus load management module part, 40 ... Communication circuit, 50 ... Communication port, 60 ... bus, 100 ... communication equipment, 110 ... circuit mounting table, 120 ... power supply module table, 130 ... port state table, 140 ... power supply module operation number table.

Claims (5)

In a communication device that returns data received at the first port of the communication circuit by the switching circuit and transmits the data from the second port of the communication circuit.
Operation of the power supply module that supplies power to the switching circuit, the control circuit, and the communication circuit according to the number of the switching circuit, the control circuit, and the communication circuit that are mounted, and the number of port active states of the communication circuit A communication device characterized by controlling the number. The communication device according to claim 1,
The control circuit holds a relationship between a position where a printed board is mounted, power consumption of the printed board, and information on whether or not the printed board is mounted. The communication device according to claim 1,
The communication circuit, wherein the control circuit holds information indicating whether each port of the mounted communication circuit is active or inactive. The communication device according to claim 1,
The control circuit holds a relationship between a position where a power supply module is mounted, a relationship between power supplied to the power supply module, and information on whether or not the power supply module is mounted. The communication device according to claim 4,
The communication device, wherein the control circuit further holds total operation time information of the power supply module.

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