JP3570968B2 - Router device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a router device, and more particularly, to a router device capable of achieving power saving of the entire device.
[0002]
[Prior art]
In communication on a communication network such as the Internet or a LAN (local area network), a router device is often used. FIG. 8 is a block diagram showing an example of the configuration of such a router device.
[0003]
In the example illustrated in FIG. 8, the terminal devices 821 to 82n are connected to exchanges 841 to 84n via a router 800. Although not shown, each of the exchanges 841 to 84n can be connected to a communication network such as a LAN (local area network) and a WAN (wide area network).
[0004]
The terminal device 821 exchanges information with the main control unit 810 via the terminal-side module 831. Similarly, the terminal devices 822 to 82n exchange information with the main control unit 810 via the terminal-side modules 832 to 83n. On the other hand, the exchanges 841 to 84n exchange information with the main control unit 810 via the WAN modules 851 to 85n, respectively. Here, it is assumed that power is always supplied to the main control unit 810, the terminal-side modules 831 to 83n, and the WAN-side modules 851 to 85n. This power is, for example, It is supplied from the device power supply.
[0005]
The main control unit 810 controls the entire router 800, and includes, for example, a CPU (Central Processing Unit). The main control 810 outputs link information to the WAN modules 851 to 85n as necessary, and selects and establishes an information transmission path between the terminal devices 821 to 82n and the exchanges 841 to 84n. For example, when establishing an information transmission path between the terminal device 821 and the exchange 841, it outputs a link establishment instruction to the WAN module 851 connected to the exchange 841.
[0006]
Specifically, the main control unit 810 refers to the routing protocol data included in the data exchanged between the terminal devices 821 to 82n, and performs a communication between the terminal devices 821 to 82n and the exchanges 841 to 84n. Select and establish an information transmission path. The routing protocol data includes, for example, a link source address, a link destination address, and transmission / reception data actually exchanged. When the route between the terminal device 821 and the exchange 841 is selected as the information transmission path, the address of the terminal device 821 is stored in the link source address, and the address of the exchange 841 is stored in the link destination address. .
[0007]
[Problems to be solved by the invention]
However, in the router device described above, when the device power of the router device is turned on, power is always supplied to the main control unit 810, the terminal-side modules 831 to 83n, and the WAN-side modules 851 to 85n. That is, even when the power is not turned on to the terminal devices 821 to 82n, and when no information is exchanged between the terminal devices 821 to 82n and the exchanges 841 to 84n, etc. Is powered.
[0008]
For this reason, the power consumption of the entire router device is increased, and there is a case where waste is caused in the operation cost. In addition, an increase in power consumption may cause the whole or a part of the device to generate heat, which may cause problems such as shortening of product life and reduction of safety.
[0009]
SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and has as its object to provide a router device capable of reducing the power consumption of the entire device.
[0010]
[Means for Solving the Problems]
Power supply control means for controlling power supplied to each unit in the apparatus according to an access state between a port on the terminal side and a port on the network side is provided.
[0011]
The power supply control means performs first power supply means for controlling power supply to an interface unit corresponding to each port on the main control unit and the terminal side, and performs power supply control to an interface unit corresponding to each port on the network side A second power supply unit, the first power supply unit performs power supply control based on a detection result of a specific signal exchanged at each port on the terminal side, the second power supply unit The power supply control is performed by monitoring an access request to each port on the network side.
[0012]
The first power supply means, when the detection of the signal indicating the link establishment state is not performed within a predetermined time, stops the power supply to the interface unit corresponding to the undetected port, the second power supply means Stops the power supply to the interface unit corresponding to the port for which no access request has been made within a certain period of time. Therefore, it is possible to stop the power supply to the interface units corresponding to the terminals and the ports on the network side, which are not required for the exchange of information, and it is possible to reduce the power consumption of the entire apparatus.
[0013]
The data exchanged between the port on the terminal side and the port on the network side include the link source address indicating the address of the device connected to the port on the terminal side and the address of the device connected to the port on the network side. The second power supply means grasps the access request to the port on the network side by referring to the link destination address.
[0014]
If the first power supply unit does not detect a signal indicating the link establishment state from all the ports on the terminal side within a predetermined time, the first power supply unit stops supplying power to the main control unit and the interface unit corresponding to each port on the terminal side. . Therefore, in such a case, power supply to the main control unit and the interface unit corresponding to a port that is not required for exchanging information can be stopped, so that the power consumption of the entire apparatus can be further reduced. .
[0015]
The second power supply means is supplied with power from the first power supply means, and the first power supply means does not detect a signal indicating a link established state within a predetermined time from all ports on the terminal side. The power supply to the second power supply means is stopped. Therefore, in such a case, since power is consumed only in the first power supply means, the power consumption of the entire apparatus can be further reduced. In addition, since the power supply to the second power supply means is controlled by the first power supply means, a single power supply system can be provided, which is convenient in terms of circuit design.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an explanatory diagram showing an example of a communication system using a router device according to the present invention.
[0017]
In the communication system illustrated in FIG. 1, the terminal devices 11 to 1n are connected to the exchange 200 via the router device 100. The exchange 200 is connected to a WAN (Wide Area Network) 300. The terminal devices 11 to 1n are terminal devices connectable to a communication network such as a WAN, and are, for example, personal computers. Although FIG. 1 illustrates an example in which the exchange 200 is connected to the WAN 300, the exchange 200 may be connected to a communication network such as a LAN (local area network) or the Internet.
[0018]
FIG. 2 is a block diagram showing the internal configuration of the router device 100. Here, the first power supply unit described in the claims corresponds to the link pulse detection circuits 121 to 12n and the power supply control unit 170, and the second power supply unit includes the switch circuit 202 and the WAN-side module. This corresponds to the control circuit 203. The interface units corresponding to the ports on the terminal side correspond to the terminal-side modules 111 to 11n, and the interface units corresponding to the ports on the network side correspond to the WAN-side module 201.
[0019]
The terminal device 11 exchanges information with the main control unit 130 via the terminal-side module 111. Similarly, the terminal devices 12 to 1n exchange information with the main control unit 130 via the terminal-side modules 112 to 11n, respectively. On the other hand, the exchange 200 exchanges information with the main control unit 130 via the WAN-side module 201. Necessary information is exchanged between the main control unit 130 and the WAN-side module control circuit 203. Here, power is supplied to the terminal-side modules 111 to 11n and the main control unit 130 via the power supply control unit 170.
[0020]
Power is supplied to the WAN-side module 201 under the control of the switch circuit 202. The switch circuit 202 supplies power to the WAN-side module 201 according to an instruction from the WAN-side module control circuit 203. Here, power is supplied to the WAN-side module control circuit 203 and the switch circuit 202 via the power supply control unit 170.
[0021]
The link pulse detection circuit 121 monitors the exchange of information between the terminal device 11 and the terminal-side module 111 and notifies the power control unit 170 of necessary information. The link pulse detection circuits 122 to 12n also notify the power control unit 170 of necessary information in a similar procedure. Here, it is assumed that power is always supplied to the link pulse detection circuits 121 to 12n from the device power supply or the like while the device power is turned on.
[0022]
The power control unit 170 controls power supply to the main control unit 130, the terminal modules 111 to 11n, the switch circuit 202, and the WAN module control circuit 203. For example, the power supply control unit 170 is supplied with power from a device power supply or the like, and responds to a notification from the link pulse detection circuits 121 to 12n according to the main control unit 130, the WAN-side module control circuit 203, the switch circuit 202, and the terminal-side module. Power is supplied to 111 to 11n.
[0023]
Here, the main control unit 130 controls the entire apparatus, for example, a CPU (central processing unit), a storage medium for storing data, an I / O (input / output device) having an interface function with an external device, and the like. It consists of. Each of the terminal-side modules 111 to 11n has an interface function with an information terminal device such as a personal computer, and is configured by, for example, an interface card (INF card) corresponding to the 10BASE-T standard. The WAN-side module 201 has an interface function with a communication network such as a WAN, and is configured by, for example, an INF card that conforms to standards such as ATM25 and I430.
[0024]
Next, the operation will be described. Here, a case where information is exchanged only between terminal device 11 and exchange 200 will be described as an example. The same applies to the operation of exchanging information between the terminal devices 12 to 1n and the exchange 200.
[0025]
During access, predetermined data is exchanged between the terminal devices 11 to 1n and the router device 100. At this time, the exchange of information between the terminal devices 11 to 1n and the router device 100 is performed with a predetermined signal. Hereinafter, this predetermined signal is referred to as a link pulse.
[0026]
The link pulse detection circuits 121 to 12n detect link pulses exchanged between the terminal devices 11 to 1n and the router device 100, respectively, and output the detection results to the power control unit 170. In the present embodiment, since link pulses are exchanged only between the terminal device 11 and the router device 100, the link pulse detection circuit 121 notifies the power control unit 170 of the link pulse detection, The link pulse detection circuits 122 to 12n notify the power supply control unit 170 that link pulses are not detected.
[0027]
Here, the operation of the link pulse detection circuits 121 to 12n will be described. FIG. 3 is a flowchart for explaining the operation of the link pulse detection circuits 121 to 12n.
[0028]
The link pulse detection circuit 121 determines whether a link pulse exchanged between the terminal device 11 and the router device 100 has been detected (step S301). When a link pulse is detected (step S301), the power control unit 170 is notified of the link pulse detection (step S303). If no link pulse has been detected (step S301), it is determined whether a link pulse has not been detected within a predetermined time (step S302). When the detection is performed within the fixed time (step S302), next, step S303 is executed. If there is no detection within a predetermined time (step S302), the power control unit 170 is notified that the link pulse is not detected (step S304).
[0029]
In the present embodiment, the link pulse detection circuit 121 notifies the power supply control unit 170 that the link pulse has been detected. On the other hand, the link pulse detection circuits 122 to 12n perform the same operation as the link pulse detection circuit 121, but cannot detect the link pulse, and thus notify the power supply control unit 170 that the link pulse has not been detected. I do.
[0030]
Then, the power supply control unit 170 controls the power supply to the terminal-side modules 111 to 11n based on the notification results from the link pulse detection circuits 121 to 12n. At this time, when information is exchanged (accessed) in any one of the terminal devices 11 to 1n, the power control unit 170 includes the main control unit 130, the switch circuit 202, and the WAN-side module control circuit 203. To supply power. In the present embodiment, power is supplied to the main control unit 130, the WAN-side module control circuit 203, the switch circuit 202, and the terminal-side module 111.
[0031]
The link pulse detection circuits 121 to 12n repeatedly execute the operation of step S301 to step 303 or step S301 to step S304. Therefore, when any of the terminal devices 11 to 1n starts exchanging information, the corresponding terminal-side module is quickly supplied with power.
[0032]
The main control unit 130 stores address information of a terminal device or the like connected to the router device 100 in a storage medium such as an internal memory in advance. In the present embodiment, the addresses of the terminal devices 11 to 1n and the exchange 200 are stored. It is also assumed that data (link pulse) exchanged between the terminal devices 11 to 1n and the router device 100 includes routing protocol data. The routing protocol data is data used for establishing an information transmission path, and includes, for example, a link destination address, a link source address, and transmission / reception data with which information is actually exchanged as shown in FIG. FIG. 4 is an explanatory diagram illustrating an example of the routing protocol data.
[0033]
Next, the operation of the main control unit 130 will be described. FIG. 5 is a flowchart for explaining the operation of the main control unit 130.
[0034]
The main control unit 130 receives routing protocol data exchanged between the terminal-side modules 111 to 11n and the router device 100 (step S501). Then, the address of the terminal device or the like stored in advance is compared with the link destination address and the link source address included in the routing protocol data, and the address of the terminal device as the link source and the address of the exchange as the link destination are transmitted to the router device 100. It is determined whether it matches the connected one (step S502).
[0035]
If they match (step S502), the access request is notified to the WAN-side module control circuit 203 (step S503). If they do not match (step S501), the access request is not notified (step S504). In the present embodiment, the link destination address stores the address of the exchange 200, and the link source address stores the address of the terminal device 11, so that the main control unit 130 Notify access request.
[0036]
FIG. 6 is a flowchart for explaining the operation of the WAN-side module control circuit 203.
[0037]
The WAN-side module control circuit 203 determines whether there is an access request from the main control unit 130 (Step S601). If there is an access request (step S601), the switch circuit 202 is notified that power is to be supplied to the WAN-side module 201 (step S602), and the self-provided timer is turned on (step S603). The reason why the timer is turned on is to secure the setup time of the WAN-side module 201 after the power is turned on. Then, after a lapse of a predetermined time, the WAN-side module control circuit 203 notifies the main control unit 130 of an access permission (step S604).
[0038]
If there is no access request (step S601), the WAN-side module control circuit 203 determines whether there is an access request within a predetermined time (step S605). If there is an access request within a predetermined time, the switch circuit 202 is notified that power is to be supplied to the WAN module 201 (step S606). If there is no access request within a certain time, the switch circuit 202 is notified that power supply to the WAN-side module 201 is to be stopped (step S607), and an access denial notification is sent to the main control unit 130. Performed (Step S608). The main control unit that has received the access non-permission notification notifies the WAN-side module 201 that the access is not permitted.
[0039]
In the present embodiment, the WAN-side module control circuit 203 notifies the switch circuit 202 that power is to be supplied to the WAN-side module 201. Then, the switch circuit 202 supplies power to the WAN-side module 201. The main control unit 130 notifies the WAN-side module 201 of information necessary for linking in response to the access permission notification from the WAN-side module control circuit 203. Then, the main control unit 130 transmits information from the exchange 200 obtained via the WAN-side module 201 to the terminal device 11 via the terminal-side module 111. Further, the main control unit 130 transmits information from the terminal device 11 obtained via the terminal-side module 111 to the exchange 200 via the WAN-side module 201. Accordingly, information can be exchanged between the terminal device 11 and the exchange 200. That is, an information transmission path between the terminal device 11 and the exchange 200 is established.
[0040]
Note that the WAN-side module control circuit 203 repeatedly executes the operations of steps S601 to S604, steps S601 to 606, or steps S601 to S608. Therefore, the WAN-side module control circuit 203 can appropriately instruct the switch circuit 202 to supply power to the WAN-side module 201 in accordance with the access status between the terminal devices 11 to 1n and the exchange 200.
[0041]
Next, when an information transmission path is established between the terminal device 11 and the exchange 200, but the access between the terminal device 11 and the exchange 200 has not been performed for a predetermined time or more, or the terminal devices 11 to 1n are turned off due to power cutoff or the like. The operation when it is not operating will be described. The same applies to the operation between the terminal devices 12 to 1n and the exchange 200.
[0042]
Since there is no access from the terminal devices 11 to 1n, the main control unit 130 cannot receive the routing protocol data exchanged between the terminal devices 11 to 1n and the router device 100. Therefore, the main control unit 130 does not notify the WAN-side module control circuit 203 of the access request. Accordingly, the WAN-side module control circuit 203 notifies the switch circuit 202 that power supply to the WAN-side module 201 is to be stopped (Steps S605 to S607). As a result, power is not supplied to the WAN-side module 201.
[0043]
On the other hand, since the link pulse detection circuits 121 to 12n cannot detect the link pulse exchanged between the terminal devices 11 to 1n and the router device 100, the link control circuit 170 informs the power control unit 170 that link pulse is not detected. A notification is sent to the user (steps S302 to S304).
[0044]
Then, the power control unit 170 stops supplying power to the terminal-side modules 111 to 11n. In addition, since information is not exchanged in all of the terminal devices 11 to 1n, power supply to the main control unit 130, the switch circuit 202, and the WAN-side module control circuit 203 is also stopped.
[0045]
As described above, according to the present embodiment, the link pulse detection circuits 121 to 12n transmit the detection result of the link pulse exchanged between the terminal devices 11 to 1n and the router device 100 to the power control unit 170. The power control unit 170 controls power supply to the terminal-side modules 111 to 11n, the main control unit 130, the switch circuit 202, and the WAN-side module control circuit 203 according to the result. Further, the WAN-side module control circuit 203 grasps an access state to the exchange 200 and controls power supply to the WAN-side module 201 through the switch circuit 202. Therefore, power can be supplied only to the parts necessary for the operation in the router device 100, so that the power consumption of the entire device can be reduced.
[0046]
For example, when any one or more of the terminal devices 11 to 1n is accessed, the terminal-side module corresponding to the accessed terminal device, the main control unit 130, the WAN-side module control circuit 203, the switch circuit 202, and the WAN Power can be supplied to the side module 201. If there is a terminal device that has not been accessed for a certain period of time even when the link between the exchange 200 and the terminal devices 11 to 1n is established, the power supply to the terminal-side module corresponding to the terminal device is stopped. can do. Further, in a state where access has not been performed for all terminal devices for a certain period of time, power supply to the terminal-side modules 111 to 11n, the main control unit 130, the switch circuit 202, the WAN-side module control circuit 203, and the WAN-side module 201 is stopped. be able to.
[0047]
In the above embodiment, the configuration in which one WAN-side module 201 is included in the router device 100 has been described. However, a plurality of WAN-side modules may be included in the router device 100. FIG. 7 is a block diagram showing a configuration of another embodiment according to the present invention.
[0048]
The router shown in FIG. 7 has a configuration in which WAN modules 211 to 2n1, switch circuits 212 to 2n2, and WAN-side module control circuits 213 to 2n3 are added to the router shown in FIG. The exchanges 210 to 2n0 are connected to the router device 100. Here, the WAN-side modules 211 to 2n1, the switch circuits 212 to 2n2, and the WAN-side module control circuits 213 to 2n3 are assumed to correspond to the exchanges 210 to 2n0, respectively.
[0049]
The main control unit 130 sends to the WAN-side module control circuits 203 to 2n3 in accordance with the routing protocol data exchanged between the terminal devices 11 to 11n and the exchanges 200 to 2n0, similarly to the operation in the above embodiment. The required access request is notified. The WAN-side module control circuits 203 to 2n3 permit power supply to the corresponding WAN-side module through the switch circuit when there is an access request to the switch corresponding to itself. That is, when there is no access request to the exchange corresponding to the self, the power supply to the corresponding WAN-side module is stopped by the same procedure. The operation in the power supply control performed by the WAN-side module control circuits 203 to 2n3 is the same as the operation in the previous embodiment.
[0050]
As described above, in the present embodiment, power is supplied only to the WAN-side module corresponding to the switch for which an access request has been made. Therefore, even when a plurality of exchanges are connected to the router device 100, the power consumption of the entire device can be reduced.
[0051]
【The invention's effect】
According to the present invention, the power supply control means detects the signal indicating the link state exchanged at each port on the terminal side and responds to the access request for each port on the network side in response to the access request to each port on the network side The power supply to the corresponding user interface unit and main control unit is controlled. Therefore, it is possible to stop power supply to the interface unit which is not necessary for exchanging information between the terminal side port and the network side port. When information is not exchanged in all of the ports on the terminal side, power supply to the main control unit and all the interface units can be stopped. Thus, power consumption of the entire apparatus can be reduced.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an example of a communication system using a router device according to the present invention.
FIG. 2 is a block diagram showing an internal configuration of the router device 100.
FIG. 3 is a flowchart illustrating the operation of link pulse detection circuits 121 to 12n.
FIG. 4 is an explanatory diagram showing an example of routing protocol data.
FIG. 5 is a flowchart for explaining an operation of a main control unit 130;
FIG. 6 is a flowchart for explaining the operation of the WAN-side module control circuit 203;
FIG. 7 is a block diagram showing a configuration of another embodiment according to the present invention.
FIG. 8 is a block diagram showing one configuration of a conventional router device.
[Explanation of symbols]
11-1n terminal device
100 router device
200 exchange
300 WAN
111-11n Terminal module
121-12n link pulse detection circuit
130 Main control unit
170 Power control unit
201 WAN side module
202 switch circuit
203 WAN side module control circuit

Claims (5)

A plurality of input / output ports are provided on the terminal side and the network side, and an interface unit corresponding to each port on the terminal side and the network side and a main control unit for controlling the entire apparatus are provided. In a router device that selects an information transmission route arbitrarily between
Depending on the state of access to and from the terminal side of the port and the network side ports, provided with a power supply control means for controlling the power supplied to each part of the apparatus,
The power supply control unit includes a first power supply unit that performs power supply control on an interface unit corresponding to each port on the terminal and the main control unit, and a power supply on an interface unit corresponding to each port on the network side. And second power supply means for performing supply control,
The first power supply unit performs power supply control based on a detection result of a specific signal exchanged at each port on the terminal side,
The router device, wherein the second power supply means controls power supply by monitoring an access request to each port on the network side . First power supply means, when the detection signal indicating link establishment status has not been made within a predetermined time, stops the power supply to the interface unit corresponding to that is not the port is the detection,
The second power supply means stops power supply to an interface corresponding to a port for which an access request has not been made within a predetermined time.
The router device according to claim 1 . The data exchanged between the port on the terminal side and the port on the network side include the link source address indicating the address of the device connected to the port on the terminal side and the address of the device connected to the port on the network side. Link destination address shown,
The second power supply unit grasps an access request to the port on the network side by referring to the link destination address.
The router device according to claim 1 or 2 . If the first power supply unit does not detect a signal indicating the link establishment state from all the ports on the terminal side within a predetermined time, the first power supply unit stops supplying power to the main control unit and the interface unit corresponding to each port on the terminal side.
The router device according to any one of claims 1 to 3 . The second power supply means is supplied with power from the first power supply means,
The first power supply unit stops supplying power to the second power supply unit unless a signal indicating a link establishment state is detected from all ports on the terminal side within a predetermined time.
The router device according to any one of claims 1 to 4 .

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