JP2009277057A - Network equipment and method for controlling power of network equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the power consumption of a network device (image processor) which receives a packet to be transmitted through a network. <P>SOLUTION: An image processor includes a timer IC 107 for receiving a packet from a host 500 through a network. Power supply to the communication control part (Ethernet (R) transceiver 102 and ASIC 103) of an image processor is controlled by this timer IC 107. The power supply is intermittently paused by repeatedly OFF/ON controlling the power by the timer IC 107. Thus, the power consumption of the image processor can be reduced. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a network device used by connecting to a network capable of suppressing power consumption and a power control method in the network device.

In recent years, in network devices, for example, image processing apparatuses used by connecting to a network, it is required to suppress power consumption in order to reduce power costs. In particular, standby power consumed during standby when the image processing apparatus is not operating is useless, and it is required to suppress power consumption as much as possible.
Therefore, in the image processing apparatus, for example, a power saving mode in which the power supply of each functional unit including a printing unit that prints and outputs an image is employed to suppress power consumption during standby. .

In general, in an image processing apparatus connected to a host apparatus (hereinafter simply referred to as a host) that is an external apparatus via a communication medium such as a commercial network, a signal (packet) containing processing information and the like from the host that requests processing. The standby power supply is set to ON so that information can be exchanged with the host at any time even in the power saving mode.
That is, in order to be able to exchange information with the host even in the power saving mode, the image processing apparatus can be put on standby without stopping the power supply of the CPU (Central Processing Unit) that controls each of the above functional units. Yes.

  On the other hand, in the energy saving mode, the power supply to the CPU is stopped, and using an ASIC (Application Specific IC), it is determined whether or not to restart the power supply to the CPU based on the received packet, and the power is supplied as necessary. An image processing apparatus that can perform supply is known (see Patent Document 1).

  In other words, the ASIC of this image processing apparatus executes processing alone if the content of the received packet is simple processing information such as an inquiry about the status of the apparatus, and when it is complicated processing information such as a print request, The main CPU of the apparatus is turned on and responds to the packet as an image processing apparatus. That is, since the operating device in the power saving mode is only the ASIC, the power consumption can be reduced.

However, even in this image processing apparatus, since power must be continuously supplied to the ASIC in the power saving mode, unnecessary power is consumed accordingly.
In addition, it is known that the use of a power source having a large capacity despite a light load is generally inefficient due to energy loss, but the ASIC has a light load. The power consumption in the power saving mode of the image processing apparatus is small. Nevertheless, there is also a problem that power efficiency is not good because power is supplied from a power source having a large capacity.

  On the other hand, in order to reduce the power consumption in the power saving mode, in the MFP (Multi Function Printer) equipped with multiple functions such as fax, copy, printer, etc. There is also known an image processing apparatus that can be selected from either supply from a host PC (see Patent Document 2).

This image processing apparatus can solve the problem of power supply efficiency in Patent Document 1. However, on the host PC side, the power consumption increases as power is supplied to the image processing apparatus. Therefore, the power consumption of the entire image processing system including the host PC is not reduced.
JP 2005-94679 A JP-A-2005-278110

  An object of the present invention has been made in view of the above-described conventional problems, and can reduce power consumption of an image processing apparatus, and can respond to a packet when it is not known when it is received. It is to be.

The invention of claim 1 is a network device connected to an external device via a network, and a communication control unit that performs communication with the external device, and power that is supplied to the communication control unit is repeatedly turned on / off. And an electric power control means.
According to a second aspect of the present invention, in the network device according to the first aspect, the network device includes a control unit that controls the operation of the network device, and shifts to a power saving mode when a transmission signal from the external device is not received for a predetermined period. Means are provided.
According to a third aspect of the present invention, in the network device according to the first or second aspect, of the power OFF / ON control period of the power control means, the OFF period is determined from the signal transmission from the external device. It is characterized in that it is set shorter than the transmission interval until retransmission.
According to a fourth aspect of the present invention, in the network device according to any one of the first to third aspects, the power control means stops the power OFF / ON control based on reception of a transmission signal from an external device. The power supplied to the communication control unit is turned on.
According to a fifth aspect of the present invention, in the network device according to any one of the first to third aspects, the ON period of power supplied to the communication control unit is a response based on reception of a transmission signal from an external device of the processing means. It is characterized by being set longer than the period required for processing.
According to a sixth aspect of the present invention, in the network device according to the fourth or fifth aspect, when the transmission signal transmitted from the external device is not received for a predetermined period, the power control means turns off the power. / ON control is resumed.
According to a seventh aspect of the present invention, in the network device according to the first aspect, the power control means is either a timer IC, a control means for controlling the operation of the network equipment, or an ASIC constituting a communication control unit. It is characterized by that.
The invention according to claim 8 is the network device according to claim 2, further comprising means for turning off the power of the control means when shifting to the power saving mode.
The invention of claim 9 is a network device connected to an external device via a network, a communication control unit for communicating with the external device, a control means for controlling the operation of the network device, and the communication control And power control means for repeatedly performing OFF / ON control of power supply to the control means.
The invention according to claim 10 is a power control method for a network device connected to an external device via a network, wherein the power supplied to a communication control unit that performs communication with the external device is repeatedly OFF / ON controlled. A control step.
The invention of claim 11 is the network device power control method according to claim 10, further comprising a step of shifting to a power saving mode when a transmission signal from the external device is not received for a predetermined period. To do.

  According to the present invention, power consumption can be reduced, and when a transmission signal is received from an external device via a network, an accurate response can be made.

The image processing apparatus of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a block diagram schematically showing the configuration of an image processing apparatus according to an embodiment of a network device of the present invention.
The image processing apparatus includes a controller 100 that controls the image processing apparatus, an engine 300 that is connected to the controller 100 and that prints and outputs image data, a power key 401 that is operated by a user to perform a button operation, and is not illustrated. In the reading unit for reading a document, a document set detection unit 402 for detecting that the document is set, and in the reading unit, a pressure plate opening / closing detection unit 403 for detecting opening / closing of the platen on the document table, power to the controller 100 and the engine 300 are supplied. It consists of a PSU (Power Supply Unit) 200 to be supplied, a main power switch 210 which is a switch of AC power supply of the PSU 200, and a plurality of hosts (HOST) 500 connected to the controller 100 via a network.
Here, the engine 300 is, for example, a conventional laser printer engine that generates an electrostatic latent image on a photosensitive drum, attaches toner, and transfers the image onto paper.

In the above configuration, when the image processing apparatus is on standby without operating for a predetermined time, the controller 100 transmits an engine power OFF control signal to the PSU 200 to turn off the engine power, that is, shift to the power saving mode. .
In the power saving mode, for example, in the image processing apparatus shown in FIG. 1, the power of the engine 300 or the like is OFF, but the controller 100 opens / closes the pressure plate of the power key 401, the document set detection unit 402, and the reading unit. The trigger signal from the detection unit 403 can be received, the packet signal from the host 500 can be received, and the engine power OFF / ON (which means OFF or ON, hereinafter the same) control signal from the controller 100 can be received. A state where the engine power of the PSU 200 can be turned on.

For example, when receiving a print command from the host 500, the controller 100 issues a command to turn on the engine power to the PSU 200 and sends the received image data to the engine 300. The engine 300 prints out based on the received image data.
The above configuration is common to each embodiment described below except for the internal configuration of the controller 100.

(First embodiment)
Next, an image processing apparatus according to the first embodiment of the present invention will be described.
FIG. 2 is a block diagram illustrating a configuration of the controller 100 of the image processing apparatus according to the first embodiment.
A controller 100 of the image processing apparatus includes a CPU 101 that is a control unit that performs processing of image data received from a host 500 via a network, and an Ethernet (registered trademark) transceiver (Ethernet) that is a transceiver that transmits and receives packets. (Registered trademark) Transceiver) 102, ASIC 103 for controlling the Ethernet (registered trademark) transceiver 102, power source A 104 for supplying power to the CPU 101, power source B 105 for supplying power to the ASIC 103, power to the Ethernet (registered trademark) transceiver 102 The power supply C106 to be supplied, and the output of the power supply B105 and the power supply C106 at a predetermined timing (here, the timing refers to the timing of switching each power supply from OFF to ON and from ON to OFF). A timer IC (Integrated Circuit) 107 that repeatedly controls the voltage OFF / ON, a power source D108 that supplies power to the timer IC 107, a storage device (not shown), and a memory are included.

  The host 500 is connected to the controller 100 via a network that is a communication medium, and requests printing, image storage, status notification, and the like. Here, as a communication medium, USB, wireless LAN (Local Area Network), Bluetooth (registered trademark) which is a standard of wireless communication using the 2.4 GHz band, and a standard of a parallel interface used for connecting a printer or the like. IEEE1284, IEEE 1394, which is a next-generation high-speed SCSI (Small Computer System Interface) standard, or the like can be used.

Here, the ASIC 103 and the Ethernet (registered trademark) transceiver 102 constitute a communication control unit for exchanging signals with the host 500 via the communication medium of the image processing apparatus.
The ASIC 103 includes a network controller that controls transmission / reception timing, transmission output, and the like in the Ethernet (registered trademark) transceiver 102, an I / F unit with the CPU 101, and the like, and controls communication for performing image processing and the like.

The timer IC 107 operates in response to an enable signal from the CPU 101, and asserts / negates an enable signal for the power supply B105 and the power supply C106 at a predetermined timing. That is, the timer IC 107 repeatedly performs OFF / ON control on the output voltages of the power supply B105 and the power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 at a predetermined timing.
This is because the power supply of the control unit of the communication means such as the conventional network is always ON, and the power is consumed by switching the power supply of the communication control unit repeatedly OFF / ON at a predetermined timing. This is a configuration adopted to suppress the power consumption.

Next, control of the power supply in the power saving mode of the image processing apparatus will be described.
In the present embodiment, the power source A 104 and the power source D 108 always supply power to the CPU 101 and the timer IC 107, respectively.
The timer IC 107 of the controller 100 repeats assertion / negation of the output voltages of the power supply B105 and the power supply C106 at a predetermined timing, and repeatedly performs OFF / ON control of the power of the ASIC 103 and the Ethernet (registered trademark) transceiver 102 at a predetermined timing. .

Therefore, when the power supply B105 and the power supply C106 are OFF under the control of the timer IC 107, even if the host 500 transmits a packet, which is a transmission signal, to the controller 100 of the image processing apparatus, the controller 100 Since power is not supplied to the transceiver 102 and the ASIC 103, the packet cannot be received.
The host 500 retransmits the packet to the controller 100 when the transmitted packet is not received, that is, when a response signal to the packet is not obtained from the controller 100 within a predetermined time after transmission.
In this case, as described above, the timer IC 107 controls the power supply B105 and the power supply C106 at a predetermined timing and repeats assertion / negation of the output voltage. Therefore, the output voltages of the power supply B105 and the power supply C106 are asserted. When turned ON, the controller 100 can receive the retransmitted packet. When receiving a packet from the host 500 in the power saving mode, the CPU 101 turns on the engine power supply of the PSU 200 by an engine power supply OFF / ON control signal.

  As described above, since the image processing apparatus repeatedly performs OFF / ON control of the output voltage of the power supply of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 at a predetermined timing, standby power can be reduced by the OFF period. .

(Second Embodiment)
In the image processing apparatus according to the second embodiment, when the timer IC 107 controls the power supply B105 and the power supply C106, the period during which these power supplies are turned off can be adjusted. The second embodiment is the same as the first embodiment except that the period can be adjusted. Hereinafter, the adjustment of the OFF period will be described.

FIG. 3 is a diagram showing the relationship between the OFF / ON control of the power source (Ethernet® transceiver 102 and power source B 105 and power source C 106 of the ASIC 103) of the communication control unit and the timing at which a packet is received from the host 500. .
As described above, the timer IC 107 performs OFF / ON control of the power source B 105 and the power source C 106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 at a predetermined timing. The OFF period is T1, the period during which the controller 100 cannot receive a packet (unreceivable period) is T3, and the packet retransmission period (interval) of the host 500 is T2.
Here, the packet unreceivable period T3 is the period of time T1 during which the power supply B105 and the power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 are turned off, as shown in the figure. This is a period including a time T4 required for resetting and initialization.
The image processing apparatus always reduces the retransmitted packet of the host 500 by shortening the unreceivable period T3 from the retransmission period T2 (that is, the period from the first packet transmission to the next packet transmission). In order to be able to receive, the useless time required for retransmission is shortened.

(Third embodiment)
In the image processing apparatuses according to the first and second embodiments, even after the image data transmitted from the host 500 via the network is once received, the power supply B105 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 is received. When the power supply C106 is repeatedly turned OFF / ON at a predetermined timing, the power supply B105 and the power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 may be turned OFF before returning the packet response signal. In such a case, since a response signal for packet reception cannot be transmitted, the host 500 retransmits the packet data. Accordingly, retransmission of packet data increases and the data transfer rate decreases.
Therefore, in the image processing apparatus according to the third embodiment, when image data is received, the Ethernet (registered trademark) transceiver 102 by the timer IC 107 and the power source B 105 and the power source C 106 of the ASIC 103 are repeatedly turned OFF / OFF at a predetermined timing. The control to turn on is stopped.
Note that the configuration of the controller 100 of the image processing apparatus is the same as that of the first embodiment.

FIG. 4 is a flowchart showing a processing procedure of the CPU 101 when a packet is received from the host 500 in the image processing apparatus.
When the CPU 101 receives a packet from the host 500 via the Ethernet (registered trademark) transceiver 102 and the ASIC 103 (S101; YES), the CPU 101 transmits the response signal of the packet before transmitting the packet to the Ethernet (registered trademark) transceiver 102 and the ASIC 103. The process of turning off the power supply B105 and the power supply C106 is stopped (S102), and the CPU 101 starts the process based on the received packet (S103). That is, after receiving the packet, the CPU 101 negates the enable signal to the timer IC 107, so that the power supplies B105 and C106 that supply power to the ASIC 103 and the Ethernet (registered trademark) transceiver 102 are always turned on. .
As described above, when the CPU 101 receives a packet, by stopping the control to repeatedly turn OFF / ON the power supply B105 and the power supply C106, it is possible to receive image data without lowering the data transfer rate.

(Fourth embodiment)
In the image processing apparatus shown in the third embodiment, when the period during which the power supply B105 and the power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 are ON is short, the CPU 101 performs the Ethernet (registered trademark) transceiver 102 and the ASIC 103. The process of turning off the power supply B105 and the power supply C106 is not completed (that is, the power supply B105 and the power supply C106 are turned off before that), and therefore the power supply of the Ethernet transceiver 102 and the ASIC 103 is not supplied. However, the image processing apparatus according to the fourth embodiment adjusts the power-on period, and turns off the Ethernet (registered trademark) transceiver 102, B105 of the ASIC 103, and the power supply C106. Processing And to be able to stop.

The timing of packet reception and power supply control performed by the controller 100 of the image processing apparatus will be described.
The configuration of the controller 100 of the image processing apparatus is the same as that of the first embodiment.
FIG. 5 is a diagram showing packet reception timing when the ON period is adjusted to be long when the power supply (Ethernet® transceiver 102 and power supply B105 and power supply C106 of the ASIC 103) of the communication control unit is OFF / ON. is there.

  In this image processing apparatus, the power supply B105 and power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 are turned OFF / ON at a predetermined timing. The ON period is T5, and the period required for packet processing is T6. Let T7 be the period during which a packet can be received.

Here, in the period T6 necessary for packet processing, the processing of the packet reception step S101 in the flowchart shown in FIG. 4 and the processing of stopping the power of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 is stopped S102. This is a period (time) necessary for the CPU 101 to execute.
The image processing apparatus sets a period T7 in which a packet can be received to be sufficiently longer than a period T6 necessary to process the packet. After receiving the packet from the host 500, the CPU 101 causes the Ethernet (registered trademark) transceiver 102 to receive the packet. Since the process of repeatedly turning OFF / ON the power supply of the ASIC 103 at a predetermined timing can be stopped, the process according to the received packet is possible.

(Fifth embodiment)
In the image processing apparatuses according to the third and fourth embodiments, after stopping the process of turning off the power supply B105 and the power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 when a packet is received, the packet is received. It is turned on as it is without receiving. Therefore, although the power for that is wasted, the image processing apparatus of the fifth embodiment restarts the process of repeatedly turning off / on the power supply B105 and the power supply C106 when the packet is not received for a predetermined period. ing.

The configuration of the controller 100 of the image processing apparatus is the same as that of the first embodiment.
FIG. 6 is a diagram for explaining stop and restart of OFF / ON control repeatedly performed in the communication control unit (Ethernet (registered trademark) transceiver 102 and ASIC 103).
Similar to the control shown in FIG. 4, when receiving a packet, the CPU 101 stops the control for turning off the power supply B 105 and the power supply C 106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 at a predetermined timing.

If the predetermined period is T8 and a packet is not received after T8, the CPU 101 turns off again the power supply B105 and the power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 to the timer IC 107 at a predetermined timing. Control to turn on / off is started.
The period T8 until the process of repeatedly turning OFF / ON the power supply B105 and power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 at a predetermined timing may be a fixed value, but is arbitrarily determined by the user. It is also possible to set different values depending on the difference in conditions such as nighttime and daytime.

  As described above, when a packet is not received even after a predetermined period of time, the image processing apparatus repeatedly turns off the power supply B105 and the power supply C106 of the Ethernet (registered trademark) transceiver 102 and the ASIC 103 at a predetermined timing. By turning it on, power can be reduced by the amount when it is turned off.

(Sixth embodiment)
In the image processing apparatuses according to the first to fifth embodiments, since the power of the CPU 101 is always ON, the power is consumed accordingly. However, the ASIC 103 of the image processing apparatus according to the sixth embodiment In the power saving mode, the CPU 101 is always turned off.

FIG. 7 is a block diagram illustrating a configuration of the controller 100 in the image processing apparatus according to the sixth embodiment.
In the image processing apparatus, unlike the configuration shown in FIG. 1, the ASIC 103 controls the timer IC 107 and performs control to repeatedly turn off / on the power of the CPU 101 in the power saving mode.

In the image processing apparatus according to the present embodiment, the ASIC 103 receives a packet transmitted from the master 500 via the network, via the Ethernet (registered trademark) transceiver 102, as in the determination process of the CPU 101 illustrated in FIG. Then, the output voltages of the power supply B105 and the power supply C106 are always turned on.
Thereafter, the ASIC 103 asserts an enable signal of the power source A 104 that supplies power to the CPU 101 and turns on the power of the CPU 101.

Since the CPU 101 performs packet response processing after the power source A 104 is turned on, the ASIC 103 does not need to be able to respond to all packets, and there is a possibility of receiving during the period when the power source of the CPU 101 is off. It is only necessary to respond to a certain packet.
Further, it is desirable that the CPU 101 supports a STR (Suspend to RAM) that stores a state before the power is turned off in a memory (not shown), reads the state after returning, and quickly returns.
In this way, the image processing apparatus always turns off the power of the CPU 101 when it does not receive a packet from the master 500 in the power saving mode, so that power consumption can be reduced accordingly.

(Seventh embodiment)
In the image processing apparatus according to the seventh embodiment, the timer IC 107 repeatedly performs OFF / ON control of the power of the CPU 101 at a predetermined timing.
FIG. 8 is a block diagram illustrating a configuration of the controller 100 in the image processing apparatus according to the seventh embodiment.
In this image processing apparatus, unlike the configurations shown in FIGS. 1 and 7, the timer IC 107 repeatedly turns off the power supply B105 and the power supply C106 of the ASIC 103 and the Ethernet (registered trademark) transceiver 102 in the power saving mode. At the same time when the power is turned on, the power of the CPU 101 is turned off / on at the same time.
That is, the timer IC 107 simultaneously controls the enable signals of the power supply A104, power supply B105, and power supply C106.
In addition, as in the sixth embodiment, the CPU 101 desirably supports STR.
As described above, since the image processing apparatus repeatedly performs the OFF / ON control of the power source of the CPU 101 at a predetermined timing, the power can be reduced by the amount when the power is off.

(Eighth embodiment)
In order for the CPU 101 to process a packet received from the host 500, the CPU 101 needs to be turned on. Therefore, in the image processing apparatus according to the eighth embodiment, a timer which is a power control unit for repeatedly turning OFF / ON the Ethernet (registered trademark) transceiver 102 and the B105 and the power supply C106 of the ASIC 103 is provided to the CPU 101 whose power is always on. Is provided.

FIG. 9 is a block diagram illustrating the controller 100 in the image processing apparatus according to the eighth embodiment.
In this image processing apparatus, unlike the configurations shown in FIGS. 1, 7, and 8, the CPU 101 includes a timer 101a, which itself constitutes a power control unit. In the power saving mode, the CPU 101 asserts / negates enable signals of the power supply B105 and power supply C106 at a predetermined timing based on the timer 101a, so that the power supply B105 and power supply C106 of the Ethernet (registered trademark) transceiver 102 are obtained. Are repeatedly turned OFF / ON at a predetermined timing.
The timing for repeated OFF / ON control of the power supply (OFF / ON timing) can be changed by register setting of the CPU 101.

(Ninth embodiment)
FIG. 10 is a block diagram illustrating a configuration of the controller 100 of the image processing apparatus according to the ninth embodiment.
The configuration of the controller 100 of the image processing apparatus includes a power source E109 that provides a timer 103a in the ASIC 103 and supplies power to the timer 103a, instead of the timer IC 107 of the controller 100 in the image processing apparatus shown in FIG.

That is, the ASIC 103 also constitutes a power supply control means of the present invention.
Accordingly, the ASIC 103 according to the ninth embodiment is supplied with power from the power source in which the timer 103 a is independent and is always ON. Therefore, the power supply B 105 and the power source C 106 that supply power to the ASIC 103 and the Ethernet (registered trademark) transceiver 102 are provided. By controlling the enable signal, the output voltage can be repeatedly turned OFF / ON.

(Tenth embodiment)
As in the ninth embodiment, the ASIC 103 of the controller 100 of the image processing apparatus according to the tenth embodiment incorporates the function of the timer IC 107 into the ASIC 10 as a timer 103a.
FIG. 11 is a block diagram illustrating a configuration of the controller 100 of the image processing apparatus according to the tenth embodiment.
The configuration of the controller 100 of the image processing apparatus includes a power source E109 that provides a timer 103a in the ASIC 103 and supplies power to the timer 103a, instead of the timer IC 107 of the controller 100 in the image processing apparatus shown in FIG.

(Eleventh embodiment)
The ASIC 103 of the controller 100 of the image processing apparatus according to the eleventh embodiment is obtained by incorporating a timer 103a into the ASIC 103 as in the ninth and tenth embodiments.
FIG. 12 is a block diagram illustrating a configuration of the controller 100 of the image processing apparatus according to the eleventh embodiment.
The configuration of the controller 100 of the present image processing apparatus includes a power source E109 that provides a timer 103a in the ASIC 103 and supplies power to the timer 103a instead of the timer IC 107 of the controller 100 in the image processing apparatus shown in FIG.

1 is a block diagram schematically showing a configuration of an image processing apparatus which is an embodiment of a network device of the present invention. FIG. It is a block diagram which shows the structure of the controller of the image processing apparatus of 1st Embodiment. It is a figure which shows the relationship between the OFF / ON control of the power supply of a communication control part, and the timing at which the packet from a host is received. It is the flowchart which showed the procedure of the process of CPU when a packet is received from a host. It is a figure which shows the reception timing of the packet when the ON period is adjusted long at the time of power OFF / ON control of the communication control unit. It is a figure for demonstrating the stop and restart of OFF / ON control performed repeatedly in a communication control part. It is a block diagram which shows the structure of the controller of the image processing apparatus of 6th Embodiment. It is a block diagram which shows the structure of the controller of the image processing apparatus of 7th Embodiment. It is a block diagram which shows the structure of the controller of the image processing apparatus of 8th Embodiment. It is a block diagram which shows the structure of the controller of the image processing apparatus of 9th Embodiment. It is a block diagram which shows the structure of the controller of the image processing apparatus of 10th Embodiment. It is a block diagram which shows the structure of the controller of the image processing apparatus of 11th Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Controller, 101 ... CPU, 102 ... Ethernet (trademark) transceiver, 103 ... ASIC, 104 ... Power source A, 105 ... Power source B, 106 ... Power source C 107 ... Timer IC 108 ... Power supply D 109 ... Power supply E 200 ... PSU 210 ... Main power switch 300 ... Engine 401 ... Power key 402 ... Document set detection unit, 403... Pressure plate open / close detection unit, 500.

Claims (11)

A network device connected to an external device via a network,
A communication control unit for communicating with the external device;
A network device comprising: a power control unit that repeatedly performs OFF / ON control of power supplied to the communication control unit. The network device according to claim 1,
Comprising control means for controlling the operation of the network equipment;
A network device comprising means for shifting to a power saving mode when a transmission signal from the external device is not received for a predetermined period. The network device according to claim 1 or 2,
The network device, wherein an OFF period of the power OFF / ON control period of the power control unit is set shorter than a transmission interval from signal transmission from the external device to retransmission of the signal. The network device according to any one of claims 1 to 3,
The network device, wherein the power control means stops the power OFF / ON control based on reception of a transmission signal from an external device, and turns on the power supplied to the communication control unit. The network device according to any one of claims 1 to 3,
A network device, wherein an ON period of power supplied to the communication control unit is set longer than a period required for response processing based on reception of a transmission signal from an external device of the processing means. In the network device according to claim 4 or 5,
The network device, wherein the power control means resumes the power OFF / ON control when a transmission signal transmitted from the external device is not received for a predetermined period. The network device according to claim 1,
The network device characterized in that the power control means is either a timer IC, a control means for controlling the operation of the network equipment, or an ASIC constituting a communication control section. The network device according to claim 2,
A network device comprising means for turning off the power of the control means when shifting to a power saving mode. A network device connected to an external device via a network,
A communication control unit for communicating with the external device;
Control means for controlling the operation of the network device;
A network device comprising: a power control unit that repeatedly performs OFF / ON control of power supply to the communication control unit and the control unit. A power control method for a network device connected to an external device via a network,
A power control step of repeatedly OFF / ON controlling power supplied to a communication control unit that performs communication with the external device;
A power control method for a network device, comprising: The power control method for a network device according to claim 10,
A power control method for a network device, comprising: a step of shifting to a power saving mode when a transmission signal from the external device is not received for a predetermined period.

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