JP5082673B2 - Image forming apparatus and program - Google Patents

Description

  The present invention relates to a communication control device, a program, and an image forming apparatus.

In a general office or the like, one or a plurality of terminal devices and one or a plurality of image forming devices (for example, printers) are connected in a network environment, and one or a plurality of terminal devices are connected to one or a plurality of image forming devices. A system that can be used in a shared or selective manner. In such a system, a signal is frequently transmitted from a communication line to a connected image forming apparatus or the like. Therefore, even if the received signal is a signal that does not need to be processed by the image forming apparatus, the CPU in the image forming apparatus is activated every time the signal is received. As a result, wasteful power consumption occurs in an image forming apparatus or the like connected to the network.
As a technique for suppressing the generation of such wasteful power consumption, for example, Patent Document 1 includes a sub CPU that consumes less power than the main CPU. In the energy saving mode, only the sub CPU is energized, and the network or facsimile interface is used. A technique for issuing a return trigger from a sub CPU to a main CPU in response to data reception is described.

JP 2004-5029 A

Here, in the field of information communication, new protocols are frequently created by improving and expanding protocols. In a device connected to a network, it is generally difficult to assume in advance prohibition of capturing, for example, a packet composed of such a newly created protocol. For this reason, there is a problem that the number of packets that are taken in each time a new protocol is created increases, thereby reducing the energy saving effect.
An object of the present invention is to reduce power consumption in a device connected to a network.

The invention according to claim 1 is a communication control unit that controls reception of a packet transmitted from a communication line , and an image that forms an image based on image data included in the packet received by the communication control unit. And a control unit that controls the operation of the image forming unit, wherein the communication control unit receives the packet from the communication line, and the packet received by the packet receiving unit. A first determination unit that determines whether or not to capture the packet based on predetermined data included in the data, a data area of the packet including the predetermined data used in the first determination unit, and the predetermined Based on data included in any of the data areas of the packet not including the data of the packet, all or part of the packet determined to be captured by the first determination unit A second determination unit that determines whether or not to capture the packet, and the first determination unit captures the packet by satisfying a condition for permitting the capture of the packet set for the predetermined data. When the determination is made, the start of power supply to the control unit is instructed, and the packet that does not satisfy either of the conditions for permitting the capturing of the packet set for the predetermined data and the condition for rejecting the capturing is captured. The second determination unit makes a determination and does not instruct the start of power supply to the control unit, and the second determination unit uses either the condition for permitting the capture or the condition for rejecting the capture by the first determination unit. Instructing the start of power supply to the control unit when it is determined to capture the packet that is determined not to satisfy The image forming apparatus according to symptoms.

According to a second aspect of the present invention, the communication control unit stores the packet determined by the first determination unit as not satisfying either the condition for permitting the capture or the condition for rejecting the capture. 2. The apparatus according to claim 1, further comprising a third storage unit, wherein the second determination unit acquires the packet from the third storage unit, and determines whether or not to acquire the acquired packet. The image forming apparatus described .
According to a third aspect of the present invention, when the communication control unit captures the first storage unit that stores the packet determined to be captured by the first determination unit and the second determination unit. The image forming apparatus according to claim 1, further comprising a second storage unit that stores the determined packet .
According to a fourth aspect of the present invention, the second determination unit includes a packet of the packet that is determined to be taken in by the first determination unit as a determination target for data included in the entire data area constituting the packet. The image forming apparatus according to claim 1, wherein whether or not all or a part of the image is captured is determined.
According to a fifth aspect of the present invention, in the image forming apparatus according to the first aspect, the first determination unit is configured by hardware.

According to a sixth aspect of the present invention, there is provided a communication control unit that controls reception of a packet transmitted from a communication line , and an image that forms an image based on image data included in the packet received by the communication control unit. A program that operates in the communication control unit in an image forming apparatus having a forming unit and a control unit that controls the operation of the image forming unit, the computer receiving a packet from a communication line, A function for determining whether or not to capture the packet based on predetermined data included in the packet, and the packet including the predetermined data for all or part of the packet determined to be captured based on the predetermined data Based on the data contained in either the data area of the packet or the data area of the packet not containing the predetermined data Whether functions and to realize the determining, the function of performing the determination based on the predetermined data captures the packets by satisfying allowing uptake of the packet to be set for the predetermined data If it is determined, the instruction to start the power supply to the control unit is taken, and the packet that does not satisfy either of the conditions for permitting the capture of the packet set for the predetermined data and the condition for rejecting the capture is captured. And the data included in either the data area of the packet including the predetermined data or the data area of the packet not including the predetermined data without instructing the start of power supply to the control unit The function of performing the determination based on the condition is that the condition for permitting the capture and the rejection of the capture If it is determined that capturing for that packet is determined not to satisfy any of the conditions is a program, characterized in that an instruction to start power supply to the control unit.

The invention according to claim 7 does not include a function of storing the packet determined to be captured based on the predetermined data in a storage unit, a data area of the packet including the predetermined data, and the predetermined data. The program according to claim 6 , further realizing a function of storing, in a storage unit, the packet determined to be captured based on data included in any of the data areas of the packet.

According to the first aspect of the present invention, power consumption in the image forming apparatus connected to the network can be reduced as compared with the case where the present invention is not adopted.
According to the second aspect of the present invention, compared to the case where the present invention is not adopted , it is possible to suppress packet loss that was not conventionally assumed to be received via a communication line.
According to claim 3 of the present invention , it is possible to suppress packet loss compared to a case where the present invention is not adopted.
According to claim 4 of the present invention, it is possible to determine whether or not to take in a packet configured with a new protocol.
According to the fifth aspect of the present invention, a large number of packets transmitted from the communication line can be processed at a higher speed than when the present invention is not adopted.

According to the sixth aspect of the present invention, it is possible to reduce the power consumption in the device connected to the network as compared with the case where the present invention is not adopted.
According to claim 7 of the present invention, packet loss can be suppressed compared to a case where the present invention is not adopted.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 1 is a schematic configuration diagram illustrating an example of a communication system to which an image forming apparatus according to the present embodiment is connected. In the communication system shown in FIG. 1, for example, client devices 2A to 2C (hereinafter, simply referred to as “client device 2”) installed in a user's work space (for example, a desk) or the like, and client devices 2A to 2C Image forming apparatuses 3A to 3C (hereinafter also simply referred to as “image forming apparatus 3”) that form images on a medium (paper) such as recording paper based on the image data generated in It is connected so as to be capable of bidirectional communication via a network 1 such as a LAN (Local Area Network), a WAN (Wide Area Network), or the Internet. The communication line may include a telephone line or a satellite communication line (for example, a spatial transmission line in digital satellite broadcasting). Normally, a plurality of client apparatuses 2 and a plurality of image forming apparatuses 3 can be connected to the network 1, but in the configuration shown in FIG. 1, as an example, three client apparatuses 2A to 2C and A case is shown in which three printers 3A to 3C are connected.

As the client device 2 connected to the network 1, for example, a personal computer (PC) is used, and image data including documents, figures, photographs, and the like is created and stored. Then, when printing the created image data or the stored image data, the client apparatus 2 converts the image data into a print job that is a print command for any of the image forming apparatuses 3A to 3C and outputs the print job. The data constituting the print job (print job data) is attribute data which is information for setting various printing functions and specifying any of the image forming apparatuses 3A to 3C for performing printing in addition to the image data. It is comprised including.
The print job output from the client apparatus 2 is transmitted to any of the image forming apparatuses 3A to 2C via the network 1.

  Next, the configuration of the image forming apparatus 3 will be described. FIG. 2 is a block diagram illustrating the configuration of the image forming apparatus 3 according to the present embodiment. As shown in FIG. 2, the image forming apparatus 3 includes a control unit 10 that controls the operation of the entire image forming apparatus 3 according to a predetermined processing program, and a communication control unit 20 that controls communication with the network 1. I have. Also, an image processing unit 30 that performs analysis of a print job transmitted from the client apparatus 2 via the network 1 and performs various processes on image data included in the print job, and operations when various processes are performed in the image processing unit 30 An image processing storage unit 31 used as a storage memory and an image output unit 32 that forms an image on a sheet based on image data that has been subjected to various processes by the image processing unit 30 are provided. Here, as the image output unit 32, for example, an electrophotographic image forming engine is used. In addition, the image processing unit 30 and the image output unit 32, and other functional units as necessary, function as an image forming unit.

Here, the communication control unit 20 and the image processing unit 30 are connected to the external bus 41. The control unit 10 is connected to the external bus 41 via the bus bridge 60. Thereby, the control part 10, the communication control part 20, and the image process part 30 are connected so that transmission / reception of a signal is mutually possible.
Further, the image forming apparatus 3 includes a power supply unit 50 that converts, for example, 100 V power supplied from a commercial power source into a predetermined voltage (for example, 24 V, 12 V, and 5 V). Electric power of a predetermined voltage is supplied.

  As shown in FIG. 2, the control unit 10 includes a CPU (Central Processing Unit) 101 that performs arithmetic processing when controlling the entire image forming apparatus 3, and a RAM (Random Access Memory) that is used as a working memory of the CPU 101. 102, a ROM (Read Only Memory) 103 in which processing programs executed by the CPU 101 are stored. These are connected to each other via an internal bus 42 connected to the bus bridge 60.

Subsequently, the communication control unit 20 is an example of a communication control device, and includes a first filter unit 21, a first communication buffer unit 22, an intermediate buffer unit 23, a second filter unit 24, and a second communication buffer unit 25. ing.
The first filter unit 21 is an example of a first determination unit, is a first-stage packet filter that first processes a packet transmitted from the network 1, and is configured by hardware. When the first filter unit 21 receives a packet that matches (acquires a capture permission condition) that matches a pre-specified (registered) capture permission condition (a condition for permitting packet capture), the first filter unit 21 The data is taken in and sent to the first communication buffer unit 22. Further, when the image forming apparatus 3 is set in an energy saving mode to be described later, a return interrupt signal Sig_1 as a signal for instructing start of power supply to the control unit 10 (CPU 101) is generated, and the control unit 10 to the CPU 101.
On the other hand, when the first filter unit 21 receives a packet that satisfies a capture rejection condition (a condition for rejecting the capture of a packet) that is specified (registered) in advance (a condition that satisfies the capture rejection condition), the first filter unit 21 Discard.
The first filter unit 21 sends the received packet to the intermediate buffer unit 23 when receiving a packet that does not match (does not satisfy) either the capture permission condition or the capture rejection condition specified (registered) in advance. At the same time, the second filter unit 24 is notified that the first filter unit 21 is passed and taken into the intermediate buffer unit 23.

The first communication buffer unit 22 is an example of a first storage unit, and stores a packet that matches the capture permission condition received by the first filter unit 21.
The intermediate buffer unit 23 is an example of a third storage unit, and stores a packet that does not match either the capture permission condition or the capture rejection condition received by the first filter unit 21.

The 2nd filter part 24 is an example of a 2nd determination part, Comprising: It is a 2nd stage packet filter arrange | positioned in the back | latter stage of the 1st filter part 21, and a capture permission condition and a capture refusal condition are set programmable It is configured to be possible. Then, when receiving a packet from the first filter unit 21 that does not match either the capture permission condition or the capture refusal condition and receiving the notification that the packet is passed through the first filter unit 21 and captured in the intermediate buffer unit 23, A determination process is performed to determine whether or not the packet stored in the intermediate buffer unit 23 is a packet that needs to be processed by the image forming apparatus 3.
That is, the second filter unit 24 acquires a packet stored in the intermediate buffer unit 23 from the intermediate buffer unit 23 and determines whether the acquired packet is a packet that needs to be processed by the image forming apparatus 3. If it is determined that the packet requires processing, the acquired packet is sent to the second communication buffer unit 25. At the same time, the packet determined to be necessary for processing is deleted from the intermediate buffer unit 23. Further, when the image forming apparatus 3 is set in an energy saving mode to be described later, a return interrupt signal Sig_2 as a signal for instructing the start of power supply to the control unit 10 (CPU 101) is generated, and the control unit 10 to the CPU 101.
On the other hand, when the second filter unit 24 determines that the packet acquired from the intermediate buffer unit 23 is a packet that does not need to be processed in the image forming apparatus 3, the second filter unit 24 determines a packet that is determined not to be processed. Delete from the intermediate buffer unit 23.
The second communication buffer unit 25 is an example of a second storage unit, and stores packets determined to be processed by the image forming apparatus 3 in the second filter unit 24.

Subsequently, each function of the first filter unit 21 and the second filter unit 24 will be described in detail.
First, FIG. 3 is a diagram showing an example of a data structure of a packet received from the network 1. As shown in FIG. 3, a packet (also referred to as a “frame”) received from the network 1 includes, for example, a preamble, an SFD (Start Frame Delimiter), a MAC (Medium Access Control) header, an IP (Internet Protocol) header, It is composed of a TCP (Transmission Control Protocol) header, a data field, PAD, and FCS (Frame Check Sequence). An area composed of an IP header, a TCP header, a data field, and a PAD is referred to as a “MAC frame”.

The preamble is data for synchronization, and the SFD is data indicating that the head of the MAC frame immediately follows.
The MAC header includes a destination MAC address, a source MAC address, and a type. The destination MAC address is an address indicating a destination to which the MAC frame is delivered. The transmission source MAC address is its own MAC address, and normally a unique number burned into the ROM in the image forming apparatus 3 is assigned. The type is information data (protocol type) indicating an upper layer protocol stored in the data field.
The IP header is composed of a data string including a source IP address, a destination IP address, a packet length, and the like. The TCP header is composed of a data string including a transmission source port number, a destination port number, a sequence number, a response confirmation number, and the like.
Application data is stored in the data field in the range of 46 to 1500 bytes. For example, image data or the like is stored. The PAD is a bit string for reducing the length of the MAC frame to a minimum of 64 bytes. The FCS is a bit string for checking whether the MAC frame is broken.

By the way, with respect to a packet that is assumed to be received via the network 1, it is determined to some extent whether or not the packet requires processing by examining data existing at a predetermined position of the packet. The accuracy can be determined. Therefore, the first filter unit 21 designates (registers) a capture permission condition and a capture rejection condition for data in a predetermined area in the packet illustrated in FIG. As a result, the first filter unit 21 selects a packet that is assumed to be received from among the packets received from the network 1 in accordance with the registered capture permission condition and capture rejection condition for the data in the predetermined region. Uniquely determine whether to capture or not to capture.
In that case, in the first filter unit 21, an application function for executing a process of capturing or not capturing a packet according to a capture permission condition and a capture rejection condition regarding data in a predetermined area in the packet is configured by hardware. For this reason, in the first filter unit 21 that is directly connected to the network 1 and needs to process a large number of packets transmitted from the network 1, processing for determining whether or not to capture the packet is performed at high speed.

Here, in the first filter unit 21, as data in a predetermined area in which the capture permission condition and the capture rejection condition are registered in the packet, for example, the destination MAC address, the source MAC address, the protocol type of the MAC header The source IP address and destination IP address of the IP header, the processing port number of the source computer of the TCP header, etc. are used.
FIG. 4 is a diagram illustrating an example of a packet capture permission condition and a capture rejection condition registered in the first filter unit 21. FIG. 4 shows a case where a transmission source IP address and a destination IP address, a protocol type, a transmission source port number, and a destination port number are used as an example of data that is subject to the acquisition permission condition and the acquisition rejection condition. The first filter unit 21 uniquely determines whether or not to capture a packet received from the network 1 according to, for example, pre-registered capture permission conditions and capture rejection conditions as shown in FIG. Judgment.
As described above, the first filter unit 21 registers the capture permission condition and the capture rejection condition for the data in the predetermined region in the packet illustrated in FIG. 3.

  On the other hand, in the second filter unit 24, the capture permission condition and the capture are performed on data existing in a wider area than the data that is the registration target of the capture permission condition and the capture refusal condition in the first filter unit 21. Denial conditions are set. That is, in the second filter unit 24, the data included in the entire region or a partial region of the packet including the data that is the registration target of the capture permission condition and the capture refusal condition in the first filter unit 21, or the first Data included in the entire region or a partial region of the packet excluding data that is the registration target of the acquisition permission condition and the acquisition rejection condition by the filter unit 21 is the setting target of the acquisition permission condition and the acquisition rejection condition.

That is, in the first filter unit 21, a packet that does not match either the capture permission condition or the capture rejection condition is not supposed to be received via the network 1, for example, a new one by improving or extending the protocol or the like. In some cases, the packet is composed of various protocols, or is caused by a change in the network environment.
Therefore, the second filter unit 24 performs further detailed data analysis on the packet that does not match both the acquisition permission condition and the acquisition rejection condition in the first filter unit 21, and determines whether the acquisition is permitted or rejected. For this purpose, the second filter unit 24 inputs a capture permission condition and a capture rejection condition regarding data in an arbitrary area in the packet, for example, from an operation input panel (not shown) of the image forming apparatus 3 or via the network 1. For example, it is configured so that it can be set as needed by remote input from the client device 2 or the like. As a result, the second filter unit 24 can flexibly respond to such a change even when the appearance of a new protocol packet or a change in the network environment occurs due to an improvement or extension of the protocol, for example. , Whether to receive a packet received from the network 1 or not is adaptively determined.

  Here, FIG. 5 is a block diagram showing an internal configuration of the communication control unit 20. As shown in FIG. 5, the communication control unit 20 includes a microcode processor 201 that performs arithmetic processing according to a predetermined processing program, a RAM 202 that is used as a working memory for the microcode processor 201, and a control unit. 10, an interface unit 205 that controls input / output of signals to / from the image processing unit 30 and the like, and a network interface unit 206 that executes processing for capturing or not capturing a packet in accordance with pre-registered capture permission conditions and capture rejection conditions. Yes. The microcode processor 201, the RAM 202, and the network interface unit 206 are connected to each other by an internal bus 207.

The network interface unit 206 in FIG. 5 constitutes the first filter unit 21. The first communication buffer unit 22, the intermediate buffer unit 23, and the second communication buffer unit 25 are configured by allocating respective areas in the RAM 202. Note that the first communication buffer unit 22, the intermediate buffer unit 23, and the second communication buffer unit 25 may be configured by separate RAMs 202, respectively.
On the other hand, the microcode processor 201 in FIG. 5 constitutes the second filter unit 24.

In the communication control unit 20 of the present embodiment, the first filter unit 21 that is directly connected to the network 1 and needs to process a large number of packets transmitted from the network 1 is configured by hardware, so that the packets are processed. Perform high-speed processing with or without capturing. On the other hand, in the microcode processor 201 constituting the second filter unit 24, whether or not the capture permission condition or the capture rejection condition is met by the microcode stored in the RAM (not shown) in the microcode processor 201 is determined. The image forming apparatus 3 determines whether or not the packet requires processing.
As a result, when the image forming apparatus 3 is set in an energy saving mode to be described later, the frequency at which the CPU 101 of the control unit 10 is unnecessarily activated by a packet that does not need to be processed is reduced. Power consumption is reduced.

Next, the operation mode set in each image forming apparatus 3 of the present embodiment will be described. Each image forming apparatus 3 is configured to set “image forming operation mode”, “low power mode”, and “energy saving mode” as operation modes in order to enhance the power saving effect.
The image forming operation mode is an operation mode in which a state capable of responding to on-demand with respect to input of image data or the like is set. In the image forming operation mode, power is supplied from the power supply unit 50 to all functional units in the image forming apparatus 3.
The low power mode is an operation mode that is set when, for example, there is no input of image data or the like during the first period. In the low power mode, power supply from the power supply unit 50 to at least an image forming engine (for example, a functional unit that performs an image forming operation including a fixing device) of the image output unit 32 is stopped. On the other hand, power supply to functional units other than the image forming engine of the image output unit 32 such as the control unit 10 and the communication control unit 20 is continued.
The energy saving mode is an operation mode that is set when there is no input of image data or the like during the second period that is set longer than the first period. In the energy saving mode, only power supply from the power supply unit 50 to the communication control unit 20 is continued, and power supply to other functional units including the CPU 101 of the control unit 10 is stopped.

  Here, FIG. 6 is a diagram for explaining an operation mode set in the image forming apparatus 3 of the present embodiment. As shown in FIG. 6, the image forming apparatus 3 has an image forming operation mode that consumes a large amount of power necessary to maintain the image forming operation, and a power consumption lower than that of the image forming operation mode, but for a relatively short time. The low power mode that returns to the image forming operation mode and the energy saving mode that consumes a relatively small amount of power and takes a relatively long time to return to the image forming operation mode are appropriately selected according to the time until image data is input. Is set. Thereby, the power saving effect in the image forming apparatus 3 is enhanced.

In a general network environment, packets are frequently transmitted, and many broadcast packets (packets sent simultaneously to all nodes) are also transmitted. For this reason, the CPU of the conventional control unit is turned on every time a packet including a packet unnecessary for itself is received and returns from the energy saving mode. Then, once the CPU returns, it cannot shift to the energy saving mode for a while, and in some cases, shifts to the image forming operation mode. As a result, even if an energy saving mode, which is an ultra-low power consumption mode in which the CPU is also turned off, is provided, the power saving effect in the image forming apparatus 3 cannot often be obtained sufficiently. In that case, it is generally known to use a function such as ArpFilter to remove unnecessary packets and set the CPU not to return. However, the current network environment is in a situation where a packet composed of a new protocol appears due to, for example, protocol improvement or expansion, and what kind of packet is removed varies depending on the network environment, so ArpFilter In many cases, it cannot function effectively.
In addition, when the energy saving mode is set, since the CPU is OFF, packets cannot be received on demand. Therefore, a request is made to transmit the missed packet again. However, there are applications that do not retransmit a packet, and in this case, there is a problem that a packet is lost.

Therefore, in the communication control unit 20 of the present embodiment, the first filter unit 21 that is directly connected to the network 1 and needs to process a large number of packets is configured by hardware, and the pre-registered capture permission condition and According to the capture rejection condition, a process of capturing a packet that is assumed to be received via the network 1 or a process that does not capture the packet is uniquely and uniformly processed at a high speed. In addition, in the second filter unit 24, the acquisition permission condition and the acquisition refusal condition corresponding to a packet made of a new protocol created by improving or expanding the protocol, a change in the network environment, or the like are flexible and adaptive. Set at any time. As a result, the second filter unit 24 performs a process of determining whether or not to capture a packet that has not been assumed in the past, and passes only a packet that needs to be processed by the image forming apparatus 3 to be captured. It is configured as follows.
In this case, since the second filter unit 24 processes the packet that has been once screened by the first filter unit 21, the number of packets that need to be processed by the second filter unit 24 is reduced. It is done. Therefore, the microcode processor 201 that performs software processing whose processing speed is slower than that of the first filter unit 21 having a hardware configuration can be sufficiently handled.

Next, FIG. 7 illustrates an example of a procedure of processing regarding whether or not to capture a packet executed in the communication control unit 20 when the image forming apparatus 3 of the present embodiment is set to the energy saving mode. It is the shown flowchart.
As shown in FIG. 7, when a packet is received by the communication control unit 20 (S101), the received packet is sent to the first filter unit 21. Therefore, the first filter unit 21 also functions as a packet receiving unit. The first filter unit 21 that has acquired the packet determines whether or not the packet (unnecessary packet) matches the capture rejection condition specified (registered) in advance (S102). If it is determined in step 102 that the packet is an unnecessary packet, the first filter unit 21 discards the received packet (S103).

If it is determined in step 102 that the packet is not an unnecessary packet, that is, if it does not match the capture rejection condition, it is determined whether or not the packet (necessary packet) matches the capture permission condition specified (registered) in advance (S104). .
If it is determined in step 104 that the packet is a necessary packet, the first filter unit 21 captures the received packet (necessary packet) and sends it to the first communication buffer unit 22. The first communication buffer unit 22 stores the transmitted necessary packet (S105).
Further, the first filter unit 21 generates a return interrupt signal Sig_1 and transmits it to the CPU 101 of the control unit 10 (S106).
The CPU 101 that has received the return interrupt signal Sig_1 returns from the energy saving mode (S107). After returning from the energy saving mode, the CPU 101 confirms that it has returned by receiving the return interrupt signal Sig_1, and processes the packet (necessary packet) stored in the first communication buffer unit 22 (S108). For example, if the necessary packet is a print job from the client device 2, the CPU 101 sends the packet stored in the first communication buffer unit 22 to the image processing unit 30 and is subjected to predetermined image processing. The image output unit 32 performs print processing based on the data.

On the other hand, if it is determined in step 104 that the packet is not a necessary packet, the first filter unit 21 determines that the received packet is a packet that does not match either the capture permission condition or the capture rejection condition specified (registered) in advance. Then, the second filter unit 24 is notified that the first filter unit 21 has passed through the first filter unit 21 (S109).
Further, the first filter unit 21 sends the received packet to the intermediate buffer unit 23. The intermediate buffer unit 23 stores the transmitted packet (S110). That is, the first filter unit 21 determines that a packet that does not match either the capture permission condition or the capture rejection condition specified (registered) in advance is passed and captured, and stores it in the intermediate buffer unit 23.

  Subsequently, the second filter unit 24 acquires a packet stored in the intermediate buffer unit 23 from the intermediate buffer unit 23, and whether or not the acquired packet is a packet that needs to be processed in the image forming apparatus 3 (necessary packet). Is determined (S111). This determination is made, for example, in response to a change made to a packet made of a new protocol created by improving or expanding the protocol stored from the CPU 101 of the control unit 10 before the transition to the energy saving mode, or a change in the network environment. This is a process for determining whether or not to capture a packet that has not been assumed in the past based on the capture permission condition and the capture rejection condition.

If it is determined in step 111 that the packet is a necessary packet, the second filter unit 24 sends the packet (necessary packet) acquired from the intermediate buffer unit 23 to the second communication buffer unit 25. The second communication buffer unit 25 stores the transmitted necessary packet (S112). At the same time, the packet determined to be necessary for processing is deleted from the intermediate buffer unit 23.
Further, the second filter unit 24 generates a return interrupt signal Sig_2 and transmits it to the CPU 101 of the control unit 10 (S113).
Then, the CPU 101 that has received the return interrupt signal Sig_2 returns from the energy saving mode (S107). After returning from the energy saving mode, the CPU 101 confirms that it has returned by receiving the return interrupt signal Sig_2, and processes the packet (necessary packet) stored in the second communication buffer unit 25 (S108). For example, if the necessary packet is a print job from the client device 2, the CPU 101 sends the packet stored in the second communication buffer unit 25 to the image processing unit 30 and is subjected to predetermined image processing. The image output unit 32 performs print processing based on the data.

On the other hand, if it is determined in step 111 that the packet is not necessary, the second filter unit 24 deletes the packet determined not to be processed from the intermediate buffer unit 23 and discards the packet (S114).
In this way, when the image forming apparatus 3 is set in the energy saving mode, the frequency of the CPU 101 of the control unit 10 being unnecessarily activated by a packet that does not need to be processed is reduced, and the power consumption in the CPU 101 is reduced. Is reduced.
In the second filter unit 24 of the present embodiment, the image forming apparatus 3 processes a packet that does not match either the capture permission condition or the capture rejection condition specified (registered) in advance by the first filter unit 21. It is determined whether or not the packet is necessary. That is, it was determined whether or not some of the packets taken through the first filter unit 21 are necessary. In addition to such processing, only the capture rejection condition is registered in the first filter unit 21, and all the packets captured through the first filter unit 21 because they do not correspond to the capture rejection condition are imaged. The forming apparatus 3 may be configured to determine whether the packet needs processing.

As described above, in the communication control unit 20 of the image forming apparatus 3 according to the present embodiment, the first filter unit 21 captures or does not capture a packet that is presumed to be received via the network 1. Are processed uniquely and uniformly. In addition, the second filter unit 24 uses the image forming apparatus 3 on the basis of a capture permission condition and a capture rejection condition corresponding to a packet including a new protocol created by improving or expanding the protocol, a change in the network environment, or the like. Only the packets that require processing are passed through and captured. As a result, the CPU 101 of the control unit 10 in the state in which the energy saving mode is set is activated only when necessary, so that the frequency with which the CPU 101 returns from the energy saving mode is reduced, and the power consumption of the CPU 101 and thus the image forming apparatus 3 are reduced. The power consumption can be reduced.
In addition, by temporarily storing in the intermediate buffer unit 23 packets that do not match either the capture permission condition or the capture refusal condition in the first filter unit 21, occurrence of packet loss is suppressed.

1 is a schematic configuration diagram illustrating an example of a communication system to which an image forming apparatus according to an exemplary embodiment is connected. 1 is a block diagram illustrating a configuration of an image forming apparatus. It is the figure which showed an example of the data structure of the packet received from a network. It is the figure which showed an example of the acquisition permission conditions and acquisition rejection conditions of the packet registered in a 1st filter part. It is a block diagram which shows the internal structure of a communication control part. It is a figure explaining the operation mode set with an image forming apparatus. 6 is a flowchart illustrating an example of a processing procedure regarding whether or not to capture a packet executed in a communication control unit when the image forming apparatus is set in an energy saving mode.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Network, 2 (2A-2C) ... Client apparatus, 3 (3A-3C) ... Image forming apparatus, 10 ... Control part, 20 ... Communication control part, 21 ... 1st filter part, 22 ... 1st communication buffer part , 23 ... Intermediate buffer unit, 24 ... Second filter unit, 25 ... Second communication buffer unit, 30 ... Image processing unit, 31 ... Image processing storage unit, 32 ... Image output unit, 60 ... Bus bridge, 101 ... CPU (Central Processing Unit), 102, 202 ... RAM (Random Access Memory), 103 ... ROM (Read Only Memory), 201 ... Microcode Processor (Microcode Processor: second filter unit), 206 ... Network interface unit (first filter) Part)

Claims (7)

A communication control unit that controls reception of packets transmitted from the communication line;
An image forming unit that forms an image based on image data included in the packet received by the communication control unit;
A control unit for controlling the operation of the image forming unit,
The communication control unit
A packet receiver for receiving the packet from the communication line;
A first determination unit that determines whether to capture the packet based on predetermined data included in the packet received by the packet reception unit;
Based on the data included in either the data area of the packet including the predetermined data used by the first determination unit or the data area of the packet not including the predetermined data, the first determination A second determination unit that determines whether or not to capture all or part of the packet determined to be captured by the unit ,
When the first determination unit determines to capture the packet by satisfying a condition for permitting the capture of the packet set with respect to the predetermined data, the first determination unit instructs to start power supply to the control unit. , It is determined that the packet that does not satisfy either of the conditions for permitting the capture of the packet set for the predetermined data and the condition for rejecting the capture is captured, and does not instruct the start of power supply to the control unit ,
When the second determination unit determines that the first determination unit captures the packet that is determined not to satisfy both the condition for permitting the capture and the condition for rejecting the capture, the control unit An image forming apparatus instructing start of power supply to a unit. The communication control unit further includes a third storage unit that stores the packet that is determined not to satisfy both the condition for permitting the capture and the condition for rejecting the capture by the first determination unit,
The second determination section, the third acquires the packet from the storage unit, the image forming apparatus according to claim 1, wherein the determining whether taking the acquired the packet. The communication control unit stores a first storage unit that stores the packet that is determined to be captured by the first determination unit, and a first storage unit that stores the packet that is determined to be captured by the second determination unit. the image forming apparatus according to claim 1, wherein, further comprising a second storage unit. Whether the second determination unit captures all or a part of the packet determined to be captured by the first determination unit as a determination target for data included in the entire data area constituting the packet. The image forming apparatus according to claim 1, further comprising: The image forming apparatus according to claim 1, wherein the first determination unit is configured by hardware. A communication control unit that controls reception of a packet transmitted from a communication line; an image forming unit that forms an image based on image data included in the packet received by the communication control unit; and A program that operates in the communication control unit in the image forming apparatus having a control unit that controls the operation,
On the computer,
A function for receiving packets from a communication line;
A function of determining whether to capture the packet based on predetermined data included in the received packet;
Data included in either the data area of the packet including the predetermined data or the data area of the packet not including the predetermined data for all or part of the packet determined to be captured based on the predetermined data to realize a function of determining whether capture based on,
The function of performing the determination based on the predetermined data supplies power to the control unit when it is determined that the packet is captured by satisfying a condition for permitting capturing of the packet set with respect to the predetermined data. Is determined to capture the packet that does not satisfy either of the conditions for permitting the capture of the packet set for the predetermined data and the condition for rejecting the capture, and supplying power to the control unit Without instructing
The function of performing the determination based on data included in any of a data area of the packet including the predetermined data and a data area of the packet not including the predetermined data includes the condition for permitting the acquisition and the acquisition A program for instructing the start of power supply to the control unit when it is determined that the packet is determined to be captured that does not satisfy any of the conditions for rejecting . A function of storing in the storage unit the packet determined to be captured based on the predetermined data;
A function of storing in the storage unit the packet determined to be captured based on data included in either the data area of the packet including the predetermined data or the data area of the packet not including the predetermined data. The program according to claim 6 , wherein the program is realized.

Images