JP5393651B2 - Image forming apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus capable of preventing timeout of communication with an external apparatus.

  Conventionally, as an image forming device that can prevent timeout of communication with an external device, when it is in an energy saving state that consumes less energy than in a normal state, when the reception of data from an external device is detected, the energy saving state A printer is known that can prevent a timeout of communication with an external device by starting a transition from a normal state to a normal state and starting receiving data at a low communication speed (for example, a patent) Reference 1). This printer receives data at a high communication speed when the transition from the energy saving state to the normal state is completed.

JP 2001-84116 A

  However, since the conventional printer executes data reception at a low communication speed when it is in the energy saving state, each device such as a CPU (Central Processing Unit) and RAM (Random Access Memory) is in the energy saving state. There is a problem that it is necessary to be supplied with electric power.

  SUMMARY An advantage of some aspects of the invention is that it provides an image forming apparatus that can improve energy-saving performance as compared with the related art.

  An image forming apparatus of the present invention is an image forming apparatus having at least two states, a normal state and an energy saving state in which energy consumption is less than that in the normal state, and an interface unit for communicating with an external device; A main system that receives data from the external device via the interface unit, and a subsystem that starts faster than the main system, and the main system and the subsystem are in the energy saving state. When the interface unit is in the energy saving state, the interface unit starts up the subsystem when a connection request is received from the external device, and the subsystem sends a response to the connection request to the interface unit. Connection response means performed via the main system for starting the main system Characterized in that it comprises a motion means.

  With this configuration, in the image forming apparatus of the present invention, the main system and the subsystem are stopped when in the energy saving state, so that the energy saving performance can be improved as compared with the conventional one. In addition, the image forming apparatus of the present invention responds to a connection request to an external device by the connection response means of the subsystem that is faster to start than the main system, so that it is possible to prevent a timeout of communication with the external device.

  Further, the communication with the external apparatus by the interface unit of the image forming apparatus of the present invention times out when a predetermined time elapses after the connection request is made, and the timing at which the connection response unit makes the response is After the connection request, it is before the elapse of the predetermined time, and the timing at which the main system is activated may be after the elapse of the predetermined time after the connection request is made.

  In the image forming apparatus according to the present invention, when a connection request is transmitted to an external apparatus by the main system, a predetermined request is issued before the main system is started after a connection request is received from the external apparatus. There is a possibility that communication with an external device will time out after a lapse of time. However, the image forming apparatus of the present invention does not send a connection request response to an external device by the main system, but sends a connection request response to the external device by a connection response means of a subsystem that starts faster than the main system. Therefore, timeout of communication with an external device can be prevented.

  The image forming apparatus of the present invention further includes a response information storage unit for storing response information that is information necessary for the connection response unit to perform the response, and the response information storage unit Is provided separately from the volatile storage device among the hardware realizing the main system and the subsystem, and at least one of the main system and the subsystem shifts from the normal state to the energy saving state Sometimes, the response information may be written in the response information storage unit.

  With this configuration, in the image forming apparatus of the present invention, the response information storage unit for storing the response information is provided separately from the volatile storage device among the hardware that realizes the main system and the subsystem. The power supply to the volatile storage device can be stopped when the energy saving state is established. Therefore, the image forming apparatus of the present invention can improve energy saving performance.

  Further, the main system and the subsystem of the image forming apparatus of the present invention may be realized by the same hardware.

  With this configuration, the image forming apparatus of the present invention requires less power consumption than a configuration in which the main system and the sub-system are realized by separate hardware, so that energy saving performance can be improved.

  Further, the energy saving program of the present invention has at least two states, a normal state and an energy saving state in which energy consumption is lower than that in the normal state, and includes an interface unit for communicating with an external device. The forming apparatus functions as a main system that receives data from the external apparatus via the interface unit, and a subsystem that starts up faster than the main system, and the main system and the subsystem are in the energy-saving state. When the interface unit is in the energy saving state, the interface unit starts the subsystem when a connection request is received from the external device, and the subsystem sends a response to the connection request to the interface. Connection response means through the main unit and start the main system Characterized in that it comprises a main system startup means that.

  With this configuration, in the image forming apparatus that executes the energy saving program of the present invention, the main system and the subsystem are stopped when in the energy saving state, so that the energy saving performance can be improved as compared with the conventional one.

  The image forming apparatus of the present invention can improve the energy saving performance as compared with the prior art.

1 is a block diagram of an image forming system according to an embodiment of the present invention. FIG. 2 is a hardware block diagram of the MFP shown in FIG. 1. FIG. 2 is a block diagram of functions of the MFP shown in FIG. 1. FIG. 2 is a sequence diagram of the operation of the MFP shown in FIG. 1 when activated. FIG. 2 is a sequence diagram of the operation of the MFP shown in FIG. 1 when shifting from a normal state to an energy saving state. FIG. 2 is a sequence diagram of the operation of the MFP shown in FIG. 1 when shifting from an energy saving state to a normal state.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  First, the configuration of the image forming system according to the present embodiment will be described.

  FIG. 1 is a block diagram of an image forming system 10 according to the present embodiment.

  As shown in FIG. 1, the image forming system 10 includes an MFP (Multifunction Peripheral) 20 as an image forming apparatus of the present invention and a host PC (Personal Computer) 90 that is an external device of the MFP 20. The MFP 20 and the host PC 90 can be connected to each other via a USB (Universal Serial Bus) cable 11.

  FIG. 2 is a hardware block diagram of the MFP 20.

  The MFP 20 shown in FIG. 2 has at least two states: a normal state and an energy-saving state that consumes less energy than the normal state.

  The MFP 20 includes a CPU 21 that controls the MFP 20, a ROM (Read Only Memory) 22 that stores in advance a program including an energy saving program of the present invention and various data, a RAM 23 that is used as a work area of the CPU 21, and a host PC 90. Energy-saving RAM 24, which is a RAM as a response information storage unit of the present invention for storing response information that is information necessary for performing a response to a connection request, and an interface unit for communicating with the host PC 90 A host I / F (interface) unit 25, a print control unit 26 that executes printing on a recording medium such as paper, a CPU 21, a ROM 22, a RAM 23, an energy saving RAM 24, a host I / F unit 25, and a print control unit 26. A system bus 29 which is a transmission line for connecting And.

  The CPU 21 is an arithmetic processing device that executes a program stored in the ROM 22. The RAM 23 temporarily stores a program and various data when the program is executed by the CPU 21. The RAM 23 is a storage device that consumes power to maintain storage among hardware that implements the main system 30 and the subsystem 40, that is, a volatile storage device.

  The energy saving RAM 24 is a non-volatile storage device, such as a non-volatile random access memory (NVRAM), that does not need to consume power to maintain storage. The response information stored in the energy saving RAM 24 includes, for example, information for specifying the host PC 90. The energy saving RAM 24 is a device for storing information for realizing energy saving, but can also be used as a device for storing information other than information for realizing energy saving.

  The communication with the host PC 90 by the host I / F unit 25 is timed out when a predetermined time (hereinafter referred to as “timeout time”) such as 500 msec elapses after a connection request from the host PC 90 is received. Among USB communication protocols, it is defined by plug and play regulations.

  FIG. 3 is a block diagram of functions of the MFP 20.

  As shown in FIG. 3, the MFP 20 includes a main system 30 that receives data from the host PC 90 via the host I / F unit 25, and a subsystem 40 that has a smaller program size and faster startup than the main system 30. Yes.

  The main system 30 and the sub system 40 are realized by the CPU 21, the ROM 22, the RAM 23, and the energy saving RAM 24. The energy saving RAM 24 is provided separately from the RAM 23.

  The main system 30 writes response information in the energy saving RAM 24 when shifting from the normal state to the energy saving state.

  The subsystem 40 functions as a connection response unit 41 that performs a response to a connection request from the host PC 90 via the host I / F unit 25 and a main system activation unit 42 that activates the main system 30. The connection response means 41 uses the response information stored in the energy saving RAM 24 in order to respond to the connection request from the host PC 90.

  Next, the operation of the image forming system 10 will be described.

  FIG. 4 is a sequence diagram of the operation of the MFP 20 when it is activated.

  When the MFP 20 is activated, power supply to the CPU 21, ROM 22 and RAM 23 is started. Then, as shown in FIG. 4, the CPU 21 reads the program for the subsystem 40 stored in the ROM 22, activates the subsystem 40, and causes the subsystem 40 to start processing (S101).

  If the main system activation means 42 of the subsystem 40 determines that it has been activated by the activation of the MFP 20, it reads the program for the main system 30 stored in the ROM 22 and activates the main system 30 (S111). Stop yourself.

  When the main system 30 is activated by the subsystem 40 in S111, after performing a predetermined activation process (S121), the main system 30 supplies power to the host I / F unit 25 (S122) and also supplies power to the print control unit 26. Is supplied (S123). Therefore, the MFP 20 is in a normal state. The main system 30 can communicate with the host PC 90 when power is supplied to the host I / F unit 25. The main system 30 can execute printing by the print control unit 26 when power is supplied to the print control unit 26. The main system 30 may be configured to execute either the process of S122 or the process of S123 first.

  FIG. 5 is a sequence diagram of the operation of the MFP 20 when shifting from the normal state to the energy saving state.

  As shown in FIG. 5, the main system 30 of the MFP 20 starts transition from the normal state to the energy saving state when a predetermined condition is satisfied, for example, the user has not operated for a predetermined time (S151).

  First, the main system 30 stops supplying power to the print control unit 26 (S152).

  Next, the main system 30 writes the response information in the energy saving RAM 24 (S153). Note that the writing of response information to the energy saving RAM 24 may be executed not by the main system 30 but by the subsystem 40.

  Finally, the main system 30 reads the program for the subsystem 40 stored in the ROM 22 and starts the subsystem 40 to transfer the control to the subsystem 40 in order to cause the subsystem 40 to execute the remaining operations. The main system 30 itself is stopped (S154).

  When the control is moved from the main system 30, the subsystem 40 stops supplying power to the CPU 21 (S161). When power is not supplied to the CPU 21, the subsystem 40 implemented by the CPU 21 is also stopped. Although not shown in FIG. 5, the subsystem 40 also stops supplying power to the ROM 22 and RAM 23 before stopping supplying power to the CPU 21. However, the subsystem 40 may be configured to reduce the power supplied to the RAM 23 to such a low power that the RAM 23 operates in the self-refresh mode without completely stopping the power supply to the RAM 23. .

  When the processing shown in FIG. 5 is completed, the MFP 20 enters an energy saving state in which the supply of power to each unit other than the host I / F unit 25 is stopped.

  FIG. 6 is a sequence diagram of the operation of the MFP 20 when shifting from the energy saving state to the normal state. Here, after first responding to the connection request from the host PC 90, the MFP 20 executes a series of reception processes of receiving data from the host PC 90.

  When the MFP 20 and the host PC 90 are connected by the USB cable 11, the host PC 90 transmits a connection request to the MFP 20 via the USB cable 11 as shown in FIG. 6 (S201).

  When the host I / F unit 25 of the MFP 20 receives a connection request from the host PC 90 via the USB cable 11, it starts supplying power to the CPU 21, ROM 22, and RAM 23 and issues a reception interrupt to the CPU 21 (S 211). ). When the reception interrupt is performed by the host I / F unit 25 in S211, the CPU 21 reads the program for the subsystem 40 stored in the ROM 22, starts up the subsystem 40, and causes the subsystem 40 to start processing (S221). ). That is, the host I / F unit 25 starts the subsystem 40 when there is a connection request from the host PC 90 in the energy saving state.

  If the subsystem 40 determines that the host I / F unit 25 is activated by receiving a connection request via the USB cable 11 when the MFP 20 is in the energy saving state, the main system 30 stores the energy saving RAM 24 in S153. The written response information is acquired from the energy saving RAM 24 (S231).

  Next, the subsystem 40 writes connection information, which is information necessary for the main system 30 to take over the processing from the subsystem 40, during the series of reception processes described above in the energy saving RAM 24 (S232).

  Next, the connection response means 41 of the subsystem 40 transmits a connection response, which is a response to the connection request from the host PC 90, to the host I / F unit 25 based on the response information acquired in S231 (S233). Upon receiving the connection response transmitted by the subsystem 40 in S233, the host I / F unit 25 transmits the received connection response to the host PC 90 via the USB cable 11 (S212). Note that the timing at which the connection response means 41 sends a connection response to the host PC 90 via the host I / F unit 25 is after the connection request from the host PC 90 and before the elapse of the above-described timeout time.

  Finally, the main system activation means 42 of the subsystem 40 reads the program for the main system 30 stored in the ROM 22, activates the main system 30 (S234), and stops the subsystem 40 itself. Note that the subsystem 40 notifies the main system 30 when the main system 30 is activated that it is in the middle of the series of reception processes described above.

  When the main system 30 is activated by the subsystem 40 in S234, the main system 30 performs a predetermined activation process (S241). Note that the timing at which the main system 30 is activated may be after the elapse of the above-described timeout time after a connection request from the host PC 90 is received.

  Next, the main system 30 acquires the connection information written in the energy saving RAM 24 by the subsystem 40 in S232 from the energy saving RAM 24 (S242).

  Upon receiving the connection response transmitted by the host I / F unit 25 in S212, the host PC 90 transmits data to the MFP 20 via the USB cable 11 (S202).

  When the host I / F unit 25 of the MFP 20 receives data from the host PC 90 via the USB cable 11, the host I / F unit 25 issues a reception interrupt to the CPU 21, that is, the main system 30 (S213).

  When a reception interrupt is performed by the host I / F unit 25 in S213, the main system 30 sends a reception response, which is a response related to reception of data from the host PC 90, based on the connection information acquired in S242. The data is transmitted to the unit 25 (S243). That is, the main system 30 can take over the series of reception processes described above from the subsystem 40 and execute them.

  Upon receiving the reception response transmitted by the main system 30 in S243, the host I / F unit 25 transmits the received reception response to the host PC 90 via the USB cable 11 (S214).

  Note that a series of processes including S202, S213, S243, and S214 may be executed a plurality of times in accordance with data transmitted from the host PC 90 to the MFP 20.

  Further, the main system 30 supplies power to the print control unit 26 (S244), and shifts the state of the MFP 20 to the normal state. The main system 30 can execute printing by the print control unit 26 when power is supplied to the print control unit 26. Note that the main system 30 has the series of processes described above, for example, from the process of S242 to the process of S243, and during each process when a series of processes consisting of S202, S213, S243, and S214 is executed a plurality of times. The process of S244 may be executed in the middle of the reception process.

  As described above, when the MFP 20 shifts from the normal state to the energy saving state, the main system 30 stops (S154) and the subsystem 40 stops (S161). That is, the MFP 20 can stop the power supply to the CPU 21, the ROM 22, and the RAM 23 that realize the main system 30 and the subsystem 40 when the energy saving state is achieved, so that the energy saving performance can be improved as compared with the related art.

  When the main system 30 makes a response to the connection request to the host PC 90 by the main system 30, after the connection request is received from the host PC 90, the above-described timeout time elapses before the main system 30 starts up. Communication with the host PC 90 may time out. However, the MFP 20 does not respond to the connection request to the host PC 90 by the main system 30 but responds to the connection request 41 to the host PC 90 by the connection response means 41 of the subsystem 40 that starts faster than the main system 30. A timeout of communication with the PC 90 can be prevented.

  Since the MFP 20 is provided with the energy saving RAM 24 for storing the response information separately from the RAM 23, the power supply to the RAM 23 can be stopped when the MFP 20 is in the energy saving state. Therefore, the MFP 20 can improve the energy saving performance. The MFP 20 may store the response information in the RAM 23 and continue to supply power to the RAM 23 when the MFP 20 is in the energy saving state.

  In the MFP 20, the main system 30 and the subsystem 40 are realized by the same hardware, that is, the CPU 21, the ROM 22, the RAM 23, and the energy saving RAM 24. Therefore, the main system 30 and the subsystem 40 are realized by separate hardware. Compared with, it consumes less power. Therefore, the MFP 20 can improve the energy saving performance.

  In addition, since the main system 30 and the subsystem 40 are realized by the same hardware, the MFP 20 is less expensive to manufacture than the configuration in which the main system 30 and the subsystem 40 are realized by separate hardware. I'll do it.

  The MFP 20 includes the print control unit 26 as a control unit that is supplied with power in a normal state and stops supplying power in an energy saving state. However, the MFP 20 is supplied with power in a normal state and stops supplying power in the energy saving state. In addition to the print control unit 26, various control units may be provided as the control unit.

  Communication with the host PC 90 by the host I / F unit 25 is communication by USB in the present embodiment, but may be communication other than communication by USB.

  A device external to the MFP 20 is a host PC in the present embodiment, but may be a device other than the host PC.

  The image forming apparatus of the present invention is an MFP in the present embodiment, but may be an image forming apparatus other than the MFP, such as a copier or a printer.

20 MFP (image forming apparatus)
23 RAM (volatile storage device)
24 Energy saving RAM (Response information storage unit)
25 Host I / F part (interface part)
30 Main system 40 Subsystem 41 Connection response means 42 Main system activation means 90 Host PC (external device)

Claims (5)

An image forming apparatus having at least two states: a normal state and an energy-saving state that consumes less energy than the normal state,
An interface unit for communicating with an external device, a main system that receives data from the external device via the interface unit, and a subsystem that starts faster than the main system,
The main system and the subsystem are stopped when the energy saving state,
The interface unit activates the subsystem when there is a connection request from the external device in the energy saving state,
2. The image forming apparatus according to claim 1, wherein the subsystem includes a connection response unit that responds to the connection request via the interface unit, and a main system activation unit that activates the main system. Communication with the external device by the interface unit times out when a predetermined time elapses after the connection request is made,
The timing at which the connection response unit performs the response is after the connection request and before the predetermined time has elapsed,
The image forming apparatus according to claim 1, wherein the timing at which the main system is activated is after the predetermined time has elapsed after the connection request is made. A response information storage unit for storing response information which is information necessary for the connection response means to perform the response;
The response information storage unit is provided separately from the volatile storage device among the hardware realizing the main system and the subsystem,
The at least one of the main system and the subsystem writes the response information in the response information storage unit when shifting from the normal state to the energy saving state. The image forming apparatus described.   The image forming apparatus according to claim 1, wherein the main system and the subsystem are realized by the same hardware. An image forming apparatus having at least two states, a normal state and an energy saving state that consumes less energy than the normal state, and having an interface unit for communicating with an external device is provided via the interface unit. A main system that receives data from the external device, and a subsystem that starts faster than the main system,
The main system and the subsystem are stopped when the energy saving state,
The interface unit activates the subsystem when there is a connection request from the external device in the energy saving state,
The energy saving program according to claim 1, wherein the subsystem includes connection response means for responding to the connection request via the interface unit, and main system starting means for starting the main system.

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