JP2016139401A - Information processor and method for controlling information processor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology for shortening a time required for a device having a main system and a sub system to return from a power-saving state to an operational state.SOLUTION: When an instruction to make a shift to a power-saving state is inputted, the sub system notifies the main system of a return time which corresponds to a power state determined from a plurality of power states that can be taken by the sub system and is required for the sub system to return from the power state. The main system determines a power state to which the main system is shifted among a plurality of power states that can be taken by the main system on the basis of the return time transmitted from the sub system.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a technique for shortening a transition time from a power saving state to an operation state in an apparatus having a main system and a subsystem.

  Notifying the main system of the recovery time of the subsystem for the purpose of shortening the transition time (hereinafter referred to as the recovery time) when the device divided into the main system and the subsystem transitions from the power saving state to the operating state. There exists a technique to do (patent document 1). According to Patent Document 1, since the main system can start access to the subsystem by waiting for the notified return time, the return time can be shortened.

JP 2014-182801 A

  However, in the technique described in Patent Document 1, the subsystem notifies only a single return time. On the other hand, when the subsystem has multiple functions, it may have a plurality of power states in the power saving state, and the return time in each power state may be different. That is, as in Patent Document 1, if only one longest recovery time can be notified, even if the subsystem is in a power state having a shorter recovery time in the power saving state, the subsystem must wait for a longer time than that. You will not be able to access. As a result, there is a problem that the return to the operating state of the apparatus is delayed.

  The present invention has been made in view of such problems, and provides a technique for further reducing the time required for a device having a main system and a subsystem to return from a power saving state to an operating state.

  One embodiment of the present invention is an information processing apparatus that includes a main system and a subsystem that is communicably connected to the main system, wherein the subsystem sets a power state of the information processing apparatus to a power saving state. Based on the input of an instruction for shifting to the state, one power state is determined from among a plurality of power states that can be taken by the subsystem, and the return time corresponding to the determined one power state. The subsystem notifies the main system of a recovery time required for the subsystem to recover from the determined one power state, and the main system determines the main system based on the recovery time notified from the subsystem. Is determined from among a plurality of power states that can be taken by the main system.

  According to the configuration of the present invention, it is possible to further reduce the time required for the apparatus having the main system and the subsystem to return from the power saving state to the operating state.

1 is a block diagram illustrating a configuration example of an image forming apparatus 100. FIG. FIG. 2 is a block diagram illustrating a configuration example of a main system 101. FIG. 3 is a block diagram showing a configuration example of a subsystem 102. FIG. 3 is a block diagram showing a configuration example of a subsystem 103. The figure which shows a power supply state and return time. The flowchart of the process which transfers to a power saving state from an operation state. The figure which shows the example of a display of a power supply status change screen. The flowchart of the process which transfers to an operation state from a power saving state. 2 is a block diagram illustrating a configuration example of an information processing apparatus 1000. FIG. The figure which shows an electric power state and return time. The flowchart of the process which transfers to a power saving state from an operation state. The figure which shows the example of a display of an electric power state change screen. The flowchart of the process which transfers to an operation state from a power saving state.

  Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. The embodiment described below shows an example when the present invention is specifically implemented, and is one of the specific examples of the configurations described in the claims.

[First Embodiment]
In this embodiment, an information processing apparatus applied to an image forming apparatus will be described as an example. First, a configuration example of the image forming apparatus according to the present embodiment will be described with reference to the block diagram of FIG. In FIG. 1, the image forming apparatus 100 is assumed to be an MFP (Multi Function Printer) having a copy function, a print function, a FAX function, and the like. However, the information processing apparatus having the main system and the subsystem connected to be communicable with the main system may be applied to any device as long as it has the following configuration.

The subsystem determines one power state from among a plurality of power states that can be taken by the subsystem based on the input of an instruction for shifting the power state of the information processing apparatus to the power saving state. Then, the subsystem notifies the main system of a recovery time corresponding to the determined one power state and required for the subsystem to recover from the determined one power state.
The main system determines a power state to which the main system shifts from a plurality of power states that can be taken by the main system based on the return time notified from the subsystem.
The main system 101 includes a CPU (Central Processing Unit) for controlling the operation of the entire image forming apparatus 100. For example, the main system 101 performs control for changing the power state of the image forming apparatus 100 to various states. The operation of the main system 101 for changing the power state will be described later. Details of the main system 101 will be described later with reference to FIG.

  The subsystem 102 is a SoC (System On Chip) equipped with a CPU, a network IF circuit, and the like. The subsystem 102 is dependent on the main system 101, and the main system 101 performs various settings and operation control of the subsystem 102. Details of the subsystem 102 will be described later with reference to FIG.

  The subsystem 103 is a SoC equipped with a CPU, an image processing circuit, and the like. The subsystem 103 is dependent on the main system 101, and the main system 101 performs various settings and operation control of the subsystem 103. Details of the subsystem 103 will be described later with reference to FIG.

  The main system ROM 110 is a rewritable flash ROM that stores computer programs and data used by the main system 101 (the CPU in the main system 101) to execute various processes. When power is turned on, the main system 101 first executes processing using a computer program and data stored in the main system ROM 110.

  A main system HDD (Hard Disk Drive) 109 is an example of a large-capacity information storage device, and stores an OS (Operating System) for operating the main system 101 and the subsystems 102 and 103, various application programs, data, and the like. . Computer programs and data stored / stored in the main system HDD 109 and the main system ROM 110 are appropriately loaded into the main system DRAM 106 under the control of the main system 101 and are processed by the main system 101.

  The main system DRAM 106 is a DRAM (Dynamic Random Access Memory) in which the OS, computer program, and data of the main system 101 are expanded. The main system 101 executes processing using computer programs and data stored in the main system DRAM 106, thereby executing operation control of the entire image forming apparatus 100 and each processing described later as what the main system 101 performs. To do.

  The operation unit 111 is a device such as a touch panel that has both a display function and an operation function, and functions as a user interface of the main system 101. The operation unit 111 may be configured by combining a liquid crystal display (touch panel screen) and hard keys, for example. The operation unit 111 receives an operation instruction from the user and displays an operation result.

  The subsystem ROM 105 is a rewritable flash ROM (ReadOnlyMemory) that stores computer programs and data used by the subsystem 102 (CPU in the subsystem 102) to execute various processes. Computer programs and data stored in the subsystem ROM 105 are appropriately loaded into the subsystem DRAM 107 under the control of the subsystem 102 and are processed by the subsystem 102.

  The subsystem DRAM 107 is a DRAM in which the OS, computer program, and data of the subsystem 102 are expanded. The subsystem 102 executes processes using the computer program and data stored in the subsystem DRAM 107, thereby executing each process described later as what the subsystem 102 performs.

  The power control unit 104 is responsible for power control of the image forming apparatus 100 and is configured by CPLD (Complex Programmable Logic Device). The power control unit 104 controls a power state such as a power saving state of the image forming apparatus 100 by giving a power ON / OFF control instruction to the power source unit 108. The power supply control unit 104 can also give a control instruction to the power supply control unit built in the subsystem 102 or the subsystem 103. In addition, the transition factor of the power state of the image forming apparatus 100 is managed, and an interrupt is output to the main system 101 when the transition factor is received.

  The power supply unit 108 includes a DC / DC converter or the like, and generates a plurality of types of power supplies necessary for each component of the image forming apparatus 100. The power supply unit 108 is controlled by the power supply control unit 104 to execute ON / OFF of a plurality of types of power supplies, and to match the power state of the image forming apparatus 100 (power ON / OFF pattern for each component) ) Is generated.

  The printer unit 114 is a device that records images and characters on a recording medium such as paper based on supplied print data, and is configured by, for example, a laser beam printer or an inkjet printer.

  The scanner unit 115 is a device that reads information recorded on a recording medium such as paper as an image, and sends the read image to the subsystem 103.

  The FAX unit 116 transmits and receives FAX data using a public line. Depending on the device configuration of the image forming apparatus 100, the connection may not be established.

  The subsystem ROM 112 is a rewritable flash ROM (ReadOnlyMemory) in which computer programs and data used by the subsystem 103 (CPU in the subsystem 103) to execute various processes are stored. Computer programs and data stored in the subsystem ROM 112 are appropriately loaded into the subsystem DRAM 113 under the control of the subsystem 103 and are processed by the subsystem 103.

  The subsystem DRAM 113 is a DRAM in which the OS, computer program, and data of the subsystem 103 are expanded. The subsystem 103 executes processes using the computer program and data stored in the subsystem DRAM 113, thereby executing each process described later as what the subsystem 103 performs.

  Next, a configuration example of the main system 101 will be described using the block diagram of FIG.

  The CPU 201 controls each I / F (Interface) unit of the main system 101. The CPU 201 performs boot processing using the computer program and data stored in the main system ROM 110 when the image forming apparatus 100 is powered on, and performs processing using the OS, computer program, and data expanded in the main system DRAM 106. Execute. Thereby, the CPU 201 executes or controls each process described later as what the main system 101 performs.

  The HDDIF unit 202 is an I / F module for accessing the main system HDD 109.

  The operation unit IF unit 203 is an I / F module for performing communication with the operation unit 111, and the CPU 201 generates a GUI generated using GUI (Graphical User Interface) data stored in the main system HDD 109. The information is transmitted to the operation unit 111, or the contents of the user operation on the operation unit 111 are acquired from the operation unit 111 and transmitted to the CPU 201.

  The ROMIF unit 204 is an I / F module for accessing the main system ROM 110.

  The DRAM IF unit 205 is an I / F module for accessing the main system DRAM 106.

  The power control IF unit 206 notifies the power state of the main system 101 to the power source control unit 104, and communicates with the power source control unit 104 in order to change the power state of the image forming apparatus 100. F module.

  The subsystem IF unit 207 is an I / F module for connecting the subsystem 102 to the main system 101. The subsystem IF unit 208 is an I / F module for connecting the subsystem 103 to the main system 101. Specifically, the subsystem IF unit 207 and the subsystem IF unit 208 are both configured by PCIe (Peripheral Component Interconnect Express), the root complex is the main system 101, and the endpoints are the subsystems 102 and 103.

  Next, a configuration example of the subsystem 102 will be described using the block diagram of FIG. The subsystem 102 has a function of mainly controlling communication with external devices in the image forming apparatus 100.

  The CPU 301 performs settings, data processing, and the like of the network IF unit 305 and the USB (Universal Serial Bus) IF unit 306. The CPU 301 performs boot processing using the computer program and data stored in the subsystem ROM 105 when the image forming apparatus 100 is powered on, and performs processing using the OS, computer program and data expanded in the subsystem DRAM 107. Execute. As a result, the CPU 301 executes or controls each process described later as performed by the subsystem 102.

  The ROMIF unit 302 is an I / F module for accessing the subsystem ROM 105.

  The DRAM IF unit 303 is an I / F module for accessing the subsystem DRAM 107. The DRAM IF unit 303 includes a register for setting and controlling the subsystem DRAM 107, and this register can be accessed from either the CPU 301 or the main system 101. For example, when the subsystem DRAM 107 is set to a self-refresh state, a self-refresh command can be issued to the subsystem DRAM 107 by setting a register of the DRAM IF unit 303.

  The main system IF unit 304 is an I / F module for connecting the main system 101 to the subsystem 102. Specifically, the main system IF unit 304 is configured by PCIe, the root complex is the main system 101, and the endpoint is the subsystem 102.

  The network IF unit 305 is configured by, for example, a LAN card or the like, and is connected to a network such as a LAN (not shown) to input / output device information and image data to / from an external device.

  The USBIF unit 306 is an I / F module that has a USB Device function and performs communication with a USB Host device such as a PC (Personal Computer).

  The internal power supply control unit 307 is a module that controls the power supply in the subsystem 102. The internal power supply control unit 307 performs power supply control such as power ON / OFF for each component in the subsystem 102 according to an instruction from the power supply control unit 104 or the CPU 301.

  Next, a configuration example of the subsystem 103 will be described with reference to the block diagram of FIG. In the image forming apparatus 100, the subsystem 103 mainly has a function of controlling image processing and data input / output with respect to the printer unit 114, scanner unit 115, and FAX unit 116.

  The CPU 401 performs setting of the image processing unit 405, control of data such as an image, and the like. The CPU 401 performs boot processing using the computer program and data stored in the subsystem ROM 112 when the image forming apparatus 100 is powered on, and performs processing using the OS, computer program, and data expanded in the subsystem DRAM 113. Execute. As a result, the CPU 401 executes or controls each process described below as performed by the subsystem 103.

  The ROMIF unit 402 is an I / F module for accessing the subsystem ROM 112.

  The DRAM IF unit 403 is an I / F module for accessing the subsystem DRAM 113. The DRAM IF unit 403 includes a register for setting and controlling the subsystem DRAM 113, and this register can be accessed from either the CPU 401 or the main system 101.

  The main system IF unit 404 is an I / F module for connecting the main system 101 to the subsystem 103. Specifically, the main system IF unit 404 is configured by PCIe, the root complex is the main system 101, and the endpoint is the subsystem 103.

  The image processing unit 405 is a circuit that performs various image processes, and is set and controlled by the CPU 401 to perform various image processes. The image processing unit 405 reads the setting information stored in the setting information storage unit 406 and performs various image processing according to the read setting information. For example, color processing or correction processing is performed on the image read by the scanner unit 115.

  The setting information storage unit 406 is a module that stores setting information necessary for the image processing unit 405 to execute image processing. The setting information storage unit 406 can be read and written from both the main system 101 and the CPU 401.

  The printer IF unit 407 has a function of communicating with the printer unit 114 and outputting an image (print data) subjected to image correction or the like for printing in the image processing unit 405 to the printer unit 114.

  The scanner IF unit 408 has a function of communicating with the scanner unit 115 and transferring an image read by the scanner unit 115 to the subsystem 103.

  The FAXIF unit 409 has a function of transmitting / receiving FAX data to / from the FAX unit 116.

  The internal power supply control unit 410 is a module that controls the power supply in the subsystem 103. The internal power supply control unit 410 controls the power supply in the subsystem 103 according to an instruction from the power supply control unit 104 or the CPU 401.

  Next, the power state of the image forming apparatus 100 will be described. The image forming apparatus 100 has three power states: an operation state, a standby state, and a power saving state. For example, the user can instruct the image forming apparatus 100 to switch the power state by using the operation unit 111. On the other hand, it is performed by the main system 101 instructing when the main system 101 detects that a state in which no operation input is made has passed for a predetermined time or more.

  Regarding power consumption, the operating state is the largest, and decreases in the order of the power saving state and the standby state. Regarding the transition time to the operating state, the power saving state is the shortest and the standby state is the next shortest. From the operating state, it is possible to transition to a standby state and a power saving state. A transition from the standby state to the operating state is possible. From the power saving state, it is possible to transition to the operating state.

  The operation state is a state in which power is supplied to the main system 101 and the subsystems 102 and 103, and a state in which processing such as copying and printing can be executed. For example, information necessary for executing image processing is set in the setting information storage unit 406. Note that “transition from the power saving state to the operating state” means that all the components of the main system 101 and the subsystems 102 and 103 are operable and the processing is executable.

  The standby state is a state in which power is supplied to a part of the main system 101 and the main system DRAM 106 and power is not supplied to the subsystems 102 and 103. In the standby state, the main system DRAM 106 is supplied with power, is in a self-refresh state, and holds a value. Computer program information is stored in the main system DRAM 106. The standby state is a power state used when it is desired to reduce power consumption, such as when the user does not use the image forming apparatus 100 for a long time. Since power is not supplied to the subsystems 102 and 103 in the standby state, the subsystems 102 and 103 do not need to notify the main system 101 of the transition time from the standby state to the operating state.

  FIG. 5 shows the power supply states and recovery times of the components in the main system 101 and the subsystems 102 and 103 in the power saving state. In the power saving state, power is supplied to the main system 101 and the subsystems 102 and 103. The subsystems 102 and 103 have a plurality of power states in the power saving state, and it is determined which component in the subsystems 102 and 103 is supplied with power according to each power state. . When transitioning to the power saving state, the subsystems 102 and 103 need to notify the main system 101 of the return time.

  In the power saving state, the subsystem 102 has four power states: an NW (NetWork) response state, a USB response state, an NW & USB response state, and an operation stop state. However, when the image forming apparatus 100 is in the power saving state, each component of the subsystem 102 depends on whether the subsystem 102 is in the NW response state, the USB response state, the NW & USB response state, or the operation stop state. The power state is different.

  In the NW response state, power is supplied to the CPU 301, the DRAM IF unit 303, the network IF unit 305, the internal power control unit 307, and the subsystem DRAM 107, and no power is supplied to other components (shut off). Have been). That is, the NW response state is a state in which the image forming apparatus 100 can respond to a network packet transmitted from an information device such as a PC or a communication device such as a router. However, in the NW response state, the CPU 301 may perform an operation of analyzing the network packet and determining whether or not to shift the image forming apparatus 100 to the operation state according to the analysis result. As a result, the image forming apparatus 100 can be changed to the operating state only when a network packet that needs to be changed to the operating state is transmitted, so that power consumption can be reduced.

  In the USB response state, power is supplied to the CPU 301, the DRAM IF unit 303, the USB IF unit 306, the internal power control unit 307, and the subsystem DRAM 107, and power is not supplied to other components (shut off). ing). That is, the USB response state is a state in which the image forming apparatus 100 can respond to USB data transmitted from a PC or the like. However, as in the case of the NW response state, the CPU 301 may analyze the USB data and perform an operation of determining whether to make the image forming apparatus 100 transition to the operation state according to the analysis result. Accordingly, the image forming apparatus 100 can be changed to the operating state only when USB data that needs to be changed to the operating state is transmitted, so that power consumption can be reduced.

  In the NW & USB response state, power is supplied to the CPU 301, DRAM IF unit 303, network IF unit 305, USB IF unit 306, internal power control unit 307, and subsystem DRAM 107, and power is supplied to the other components. Not (blocked). However, the NW & USB response state is a state in which the image forming apparatus 100 can respond to the network packet and the USB data.

  In the operation stop state, power is supplied to the CPU 301 and the DRAM IF unit 303, and power is not supplied (blocked) to other components. However, in the operation stop state, processing is not possible. In this state, power may be supplied to the subsystem DRAM 107 to enter the self-refresh state and hold the value.

  The designation of the power state of the subsystem 102 may be performed by the user operating the operation unit 111. Further, the network IF unit 305 and the USBIF unit 306 hold information indicating whether or not the network connector or the USB connector is connected to the image forming apparatus 100, and the CPU 301 reads out the information, thereby the subsystem 102 in the power saving state. The power state may be determined. In that case, information for specifying the power state corresponding to the type of device connected to the image forming apparatus 100 needs to be prepared in advance.

  On the other hand, the subsystem 103 has four states in the power saving state: an image processing setting information holding state, a FAX response state, an image processing setting information holding & FAX response state, and an operation stop state. When the image forming apparatus 100 is in the power saving state, the sub system 103 is in the image processing setting information holding state, the FAX response state, the image processing setting information holding & FAX response state, or the operation stop state. The power state of each component of the system 103 is different.

  In the setting information holding state, power is supplied to the CPU 401, the DRAM IF unit 403, the setting information storage unit 406, the internal power control unit 410, and the subsystem DRAM 113, and no power is supplied to other components. (Blocked). In the setting information holding state, it is not necessary to reset the setting information, so that the recovery time of the subsystem 103 can be shortened.

  In the FAX response state, power is supplied to the CPU 401, DRAMIF unit 403, FAXIF unit 409, internal power supply control unit 410, and subsystem DRAM 113, and power is not supplied to other components (shut off). ing). The FAX response state is a state in which the image forming apparatus 100 can respond to FAX data transmitted from the outside.

  In the setting information holding & FAX response state, power is supplied to the CPU 401, the DRAMIF unit 403, the setting information storage unit 406, the FAXIF unit 409, the internal power supply control unit 410, and the subsystem DRAM 113. For other components, Power is not supplied (shut off). The setting information holding & FAX response state is a state in which the image forming apparatus 100 can respond to FAX data transmitted from the outside. Also, in the setting information holding & FAX response state, it is not necessary to reset the setting information, so that the recovery time of the subsystem 103 can be shortened.

  In the operation stop state, power is supplied to the CPU 401 and the DRAM IF unit 403, and power is not supplied (blocked) to other components. However, in the operation stop state, processing is not possible. In this state, power may be supplied to the subsystem DRAM 113 to enter the self-refresh state and hold the value.

  The designation of the power state of the subsystem 103 may be performed by the user operating the operation unit 111. Further, the CPU 401 may designate the FAX unit 116 by determining whether the FAX unit 116 is connected to the image forming apparatus 100 and notifying the CPU 401 of it.

  In each of the power states of the subsystems 102 and 103 that are in the power saving state, the initial setting is made when the power is supplied from among the components of the subsystems 102 and 103 when the transition is made from the power saving state to the operating state. As a result, the recovery time becomes longer. The time required for the initial setting varies depending on the component.

  Next, FIG. 6 is a flowchart of processing performed by the CPU 201 of the main system 101, the CPU 301 of the subsystem 102, and the CPU 401 of the subsystem 103 in order for the image forming apparatus 100 in the operating state to shift to the power saving state. It explains using.

  In the flowchart of FIG. 6, the processing in each step of steps S601, S602, S604, S605, S611, S620, and S623 is performed by the CPU 201 of the main system 101 by computer programs and data stored in the main system HDD 109 and the main system ROM 110. This is done by executing the process using.

  In the flowchart of FIG. 6, the processes in steps S606 to S610, S612, and S613 are performed by the CPU 301 of the subsystem 102 using a computer program or data stored in the subsystem ROM 105. It is made in.

  In the flowchart of FIG. 6, the processes in steps S603, S614 to S619, S621, and S622 are executed by the CPU 401 of the subsystem 103 using a computer program and data stored in the subsystem ROM 112. It is done by doing.

  In this embodiment, it is assumed that the user operates the operation unit 111 to specify whether the subsystem 103 holds the setting information.

<Step S601>
The CPU 201 displays a power state change screen that is an example of a GUI for changing the power state of the image forming apparatus 100 on the display screen of the operation unit 111. A display example of the power state change screen is shown in FIG. Buttons 702 and 703 are provided on the power state change screen 701 in FIG. The user can switch between selection / non-selection of the buttons 702 and 703 each time the buttons 702 and 703 displayed on the display screen are touched or the hard keys of the operation unit 111 are operated. Note that only one of the buttons 702 and 703 can be selected. However, when the user selects the button 702, the button 703 is in a non-selected state, and when the user selects the button 703, the button 702 is in a non-selected state. The CPU 201 controls the power state change screen 701.

  When the button 702 is selected, the CPU 201 sets the energy-saving setting of the image forming apparatus 100 to prioritize low power. When the button 703 is selected, the CPU 201 sets the energy saving setting of the image forming apparatus 100 to give priority to the short recovery time from the power saving state to the operation state. When the button 702 is selected, the CPU 201 turns off the setting information holding flag for determining the power state in the power saving state of the subsystem 103 (for example, sets “0” in the setting information holding flag), and the button When 703 is selected, the setting information holding flag is turned ON (for example, “1” is set in the setting information holding flag).

<Step S602>
The CPU 201 transmits the setting information holding flag set in step S601 to the subsystem 103 via the subsystem IF unit 208.

<Step S603>
The CPU 401 on the subsystem 103 side receives the setting information holding flag transmitted from the main system 101 via the main system IF unit 404 and stores the received setting information holding flag in the subsystem DRAM 113.

<Step S604>
“A button for shifting the power state of the image forming apparatus 100 from the operating state to the power saving state” (which may be a hard key or displayed on the display screen of the operation unit 111) , A touchable button may be operated), the CPU 201 detects the operation.

<Step S605>
The CPU 201 outputs an instruction to shift to the power saving state via the subsystem IF unit 207 and the subsystem IF unit 208 to each of the subsystem 102 and the subsystem 103.

<Step S606>
The CPU 301 on the subsystem 102 side reads the status information stored in the network IF unit 305 and determines whether or not the status information indicates that “a network connector is connected to the network IF unit 305”. To do. Further, the CPU 301 reads the state information stored in the USBIF unit 306 and determines whether or not the state information indicates that “the USB connector is connected to the USBIF unit 306”.

  As a result of these determinations, if a network connector is connected to the network IF unit 305 and a USB connector is connected to the USBIF unit 306, the process proceeds to step S607.

  When the network connector is connected to the network IF unit 305 and the USB connector is not connected to the USBIF unit 306, the process proceeds to step S608.

  If a network connector is not connected to the network IF unit 305 and a USB connector is connected to the USBIF unit 306, the process proceeds to step S609.

  If the network connector is not connected to the network IF unit 305 and the USB connector is not connected to the USBIF unit 306, the process proceeds to step S610.

<Step S607>
The CPU 301 determines to set the power state of the subsystem 102 in the power saving state to the NW & USB response state, and notifies the main system 101 of the recovery time of the subsystem 102 in the NW & USB response state (25 msec in the case of FIG. 5).

<Step S608>
The CPU 301 decides to change the power state of the subsystem 102 in the power saving state to the NW response state, and notifies the main system 101 of the return time of the subsystem 102 in the NW response state (50 msec in the case of FIG. 5).

<Step S609>
The CPU 301 decides to change the power state of the subsystem 102 in the power saving state to the USB response state, and notifies the main system 101 of the return time of the subsystem 102 in the USB response state (50 msec in the case of FIG. 5).

<Step S610>
The CPU 301 decides to set the power state of the subsystem 102 in the power saving state to the operation stop state, and notifies the main system 101 of the return time of the subsystem 102 in the operation stop state (200 msec in the case of FIG. 5).

<Step S611>
When the CPU 201 on the main system 101 side receives the return time notified in any of steps S607 to S610 via the subsystem IF unit 207, the CPU 201 stores the return time in the main system DRAM.

<Step S612>
The CPU 301 on the subsystem 102 side stores in the subsystem DRAM 107 setting information of the components in the subsystem 102 whose power is shut off in the power state determined in any of steps S607 to S610.

<Step S613>
The CPU 301 stores the power state determined in any of steps S607 to S610 in the subsystem DRAM 107 and notifies the internal power supply control unit 307. When the internal power supply control unit 307 receives the notification of the power state determined from the CPU 301, the internal power supply control unit 307 controls power ON / OFF for each component in the subsystem 102 according to the notified power state (in FIG. 5). The power state corresponding to the notified power state is set to complete the transition of the subsystem 102 to the power saving state.

<Step S614>
When the CPU 401 on the subsystem 103 side receives an instruction to shift to the power saving state from the main system 101, the CPU 401 reads the setting information holding flag stored in the subsystem DRAM 113 in step S603.

<Step S615>
The CPU 401 reads the state information stored in the FAXIF unit 409 and determines whether or not the state information indicates that “the FAX unit 116 is connected to the FAXIF unit 409” (connection state).

  If the setting information holding flag is ON and the FAX unit 116 is connected to the FAXIF unit 409, the process proceeds to step S618. If the setting information holding flag is ON and the FAX unit 116 is not connected to the FAXIF unit 409, the process proceeds to step S616. If the setting information holding flag is OFF and the FAX unit 116 is connected to the FAXIF unit 409, the process proceeds to step S617. If the setting information holding flag is OFF and the FAX unit 116 is not connected to the FAXIF unit 409, the process advances to step S619.

<Step S616>
The CPU 401 decides to set the power state of the subsystem 103 in the power saving state to the setting information holding state, and notifies the main system 101 of the return time of the subsystem 103 in the setting information holding state (50 msec in the case of FIG. 5). To do.

<Step S617>
The CPU 401 determines to change the power state of the subsystem 103 in the power saving state to the FAX response state, and notifies the main system 101 of the return time of the subsystem 103 in the FAX response state (350 msec in the case of FIG. 5).

<Step S618>
The CPU 401 decides to set the power state of the subsystem 103 in the power saving state to the setting information holding & FAX response state, and the main system 101 sets the recovery time of the subsystem 103 in the setting information holding & FAX response state (in the case of FIG. 5). 25 msec).

<Step S619>
The CPU 401 determines to set the power state of the subsystem 103 in the power saving state to the operation stop state, and notifies the main system 101 of the return time of the subsystem 103 in the operation stop state (in the case of FIG. 5, 500 msec).

  The return time has a storage area for setting the return time in the main system IF unit 304 (404) and may be notified by communication according to the PCIe protocol, or the main system 101 reads the storage area. You may make it notify by.

<Step S620>
The CPU 201 on the main system 101 side receives the return time notified in any of steps S616 to S619 via the subsystem IF unit 208, and stores the return time in the main system DRAM 106.

<Step S621>
The CPU 401 on the subsystem 103 side stores, in the subsystem DRAM 113, setting information on the components in the subsystem 103 that are powered off in the power state determined in any of steps S616 to S619.

<Step S622>
The CPU 401 stores the power state determined in any of steps S616 to S619 in the subsystem DRAM 113 and notifies the internal power supply control unit 410 of it. When the internal power supply control unit 410 receives the notification of the power state determined from the CPU 401, the internal power supply control unit 410 controls power ON / OFF for each component in the subsystem 103 according to the notified power state (in FIG. 5). The power state corresponding to the notified power state is set to complete the transition of the subsystem 103 to the power saving state.

<Step S623>
The CPU 201 on the main system 101 side instructs the power supply control unit 104 to shift to the power saving state. The power supply control unit 104 controls the power supply of the image forming apparatus 100 by instructing the power supply unit 108 to change to the power supply state illustrated in FIG. 5 and the transition to the power saving state is completed. At this time, the CPU 201 of the main system 101 determines a power saving mode to be shifted from a plurality of power saving modes based on the return time acquired from the subsystem 102 and the subsystem 103. Then, the CPU 201 of the main system 101 shifts to the determined power saving mode. Specifically, the CPU 201 determines the power saving mode to be shifted based on the shortest return time acquired from the subsystem 102 and the subsystem 103. When the shortest recovery time is longer, the CPU 201 shifts to a deep power saving mode where the power consumption is smaller, and when the shortest recovery time is shorter, the CPU 201 enters a shallow power saving mode where the power consumption is larger. Transition. In the deep power saving mode, the amount of power consumption is small, but the recovery time required for the CPU 201 to return from the deep power saving mode is long. On the other hand, the shallow power saving mode consumes a large amount of power, but the recovery time required for the CPU 201 to return from the shallow power saving mode is short.

  Next, the CPU 201 of the main system 101, the CPU 301 of the subsystem 102, and the CPU 401 of the subsystem 103 are used to shift the image forming apparatus 100 that has shifted to the power saving state through the processing according to the flowchart of FIG. 6 to the operating state. The processing performed by each will be described with reference to the flowchart of FIG.

  In the flowchart of FIG. 8, the processes in steps S801 to S805 and S812 to S814 are performed by the CPU 201 of the main system 101 using computer programs and data stored in the main system HDD 109 and the main system ROM 110. It is done by doing.

  In the flowchart of FIG. 8, the processing in each of steps S806 to S808 is performed by the CPU 301 of the subsystem 102 executing processing using a computer program and data stored in the subsystem ROM 105. It is.

  In the flowchart of FIG. 8, the processes in steps S809 to S811 are performed by the CPU 401 of the subsystem 103 executing processes using computer programs and data stored in the subsystem ROM 112. It is.

<Step S801>
The CPU 201 on the main system 101 side is in a waiting state for a return interrupt from the power supply control unit 104, and upon receiving a return interrupt from the power supply control unit 104, the process proceeds to step S802.

<Step S802>
The CPU 201 outputs a power-on signal to the power control unit 104. Upon receiving the power-on signal, the power control unit 104 instructs the power supply unit 108 to supply power to all the components of the image forming apparatus 100.

<Step S803>
The CPU 201 instructs the subsystems 102 and 103 to return via the subsystem IF units 207 and 208, respectively.

<Step S804>
The CPU 201 compares the return time stored in the main system DRAM 106 in step S611 and the return time stored in the main system DRAM 106 in step S620, and identifies which return time is shorter.

<Step S805>
The CPU 201 measures the elapsed time after the start of the process in step S802 (after the start of the return process to the operating state) using an internal timer (not shown), and the elapsed time is the return time specified in step S804. Judge whether or not it has been exceeded. As a result of this determination, if it exceeds, the process proceeds to step S812, and if not, the process waits in step S805. For example, if the recovery time received from the subsystem 102 <the recovery time received from the subsystem 103, the elapsed time exceeds the recovery time received from the subsystem 102, that is, the recovery of the subsystem 102 is completed. If it can be determined that it would have been, the process proceeds to step S812.

<Step S806>
When the CPU 301 on the subsystem 102 side receives a return instruction from the main system 101 via the main system IF unit 304, it instructs the internal power control unit 307 to turn on the power. Upon receiving the power-on instruction, the internal power control unit 307 supplies power to all the components of the subsystem 102.

<Step S807>
The CPU 301 reads “the power state of the subsystem 102 in the power saving state” stored in the subsystem DRAM 107 in step S613.

<Step S808>
The CPU 301 reads the setting information stored in the subsystem DRAM 107 in step S612, that is, the setting information of the constituent elements in the subsystem 102 whose power is shut off in the power state determined in any of steps S607 to S610. The information is used to reset the components in the subsystem 102 whose power is shut off in the power state determined in any of steps S607 to S610.

<Step S809>
When the CPU 401 on the subsystem 103 side receives a return instruction from the main system 101 via the main system IF unit 404, it instructs the internal power control unit 410 to turn on the power. Upon receiving the power-on instruction, the internal power control unit 410 supplies power to all the components of the subsystem 103.

<Step S810>
The CPU 401 reads “the power state of the subsystem 103 in the power saving state” stored in the subsystem DRAM 113 in step S622.

<Step S811>
The CPU 301 reads the setting information stored in the subsystem DRAM 113 in step S621, that is, the setting information of the components in the subsystem 103 whose power is shut off in the power state determined in any of steps S616 to S619. Using the information, the components in the subsystem 103 whose power is shut off in the power state determined in any of steps S616 to S619 are reset.

<Step S812>
The CPU 201 on the main system 101 side determines from the subsystem 102 and the subsystem 102 in the case of the subsystem corresponding to the recovery time specified in step S804 (recovery time received from the subsystem 102 <recovery time received from the subsystem 103). In the case where the received return time> the return time received from the subsystem 103, access to the subsystem 103) is started via the corresponding IF unit, and the recovery process is performed.

<Step S813>
The CPU 201 determines whether or not the elapsed time has exceeded one return time different from the return time specified in step S804. As a result of this determination, if it exceeds, the process proceeds to step S814. If not, the process waits in step S813. For example, if the recovery time received from the subsystem 102 <the recovery time received from the subsystem 103, the elapsed time exceeds the recovery time received from the subsystem 103, that is, the recovery of the subsystem 103 is completed. If it can be determined that it would have been, the process proceeds to step S814.

<Step S814>
The CPU 201 on the main system 101 side corresponds to one of the return times different from the return time specified in step S804 (in the case of the return time received from the subsystem 102 <the return time received from the subsystem 103). In the case of the return time received from the subsystem 103 and the subsystem 102> the return time received from the subsystem 103, access to the subsystem 102) is started via the corresponding IF unit, and the return processing is performed.

  As described above, according to the present embodiment, when the subsystems 102 and 103 in the power saving state have a plurality of power states with different return times, the return time corresponding to the power state can be notified to the main system 101. It becomes possible. As a result, when the image forming apparatus 100 returns from the power saving state, the recovery can be performed in the minimum time corresponding to the power state of the subsystems 102 and 103. Furthermore, even when the main system 101 is connected to a plurality of subsystems, it is possible to notify the main system 101 of a return time corresponding to each power state of each subsystem.

[Second Embodiment]
In the first embodiment, the main system 101 is connected to a plurality of subsystems (subsystems 102 and 103), and the power control unit 104 manages the transition factor from the power saving state to the operation state of the image forming apparatus 100. Explained. In the present embodiment, a configuration will be described in which the main system 101 is connected to a single subsystem 102, and the subsystem 102 manages a transition factor from the power saving state to the operating state. In the following, differences from the first embodiment will be described mainly, and unless otherwise noted, the same as the first embodiment.

  A configuration example of the information processing apparatus 1000 according to the present embodiment will be described with reference to the block diagram of FIG. 9, the same reference numerals are given to the same functional units as the functional units illustrated in FIG. 1, and the description relating to the functional units is omitted. The configuration illustrated in FIG. 9 is obtained by omitting the subsystem 103, the FAX unit 116, the printer unit 114, the scanner unit 115, the subsystem ROM 112, and the subsystem DRAM 113 from the configuration illustrated in FIG.

  In the present embodiment, the subsystem 102 in the power saving state has three states: a full power ON state, an NW response state, and an operation stop state. FIG. 10 shows the power states and recovery times of the components in the subsystem 102 in the all power ON state, NW response state, and operation stop state. Note that the power states and transition operations that the information processing apparatus 1000 can take are the same as those of the image forming apparatus 100 of the first embodiment.

  In the all power ON state, power is supplied to all the components of the subsystem 102. Although power is supplied, it is possible to reduce power consumption by stopping the clock supplied to each component by the internal power control unit 307.

  In the NW response state, power is supplied to the CPU 301, the DRAM IF unit 303, the network IF unit 305, the internal power control unit 307, and the subsystem DRAM 107, and no power is supplied to other components (shut off). Have been). That is, the NW response state is a state in which the information processing apparatus 1000 can respond to a network packet transmitted from an information device such as a PC or a communication device such as a router.

  In the operation stop state, power is supplied to the CPU 301 and the DRAM IF unit 303, and power is not supplied (blocked) to other components. However, in the operation stop state, processing is not possible. In this state, power may be supplied to the subsystem DRAM 107 to enter the self-refresh state and hold the value.

  The designation of the power state of the subsystem 102 may be performed by the user operating the operation unit 111.

  Next, processing performed by the CPU 201 of the main system 101 and the CPU 301 of the subsystem 102 in order for the information processing apparatus 1000 in the operating state to shift to the power saving state will be described with reference to the flowchart of FIG.

  In the flowchart of FIG. 11, the CPU 201 of the main system 101 uses computer programs and data stored in the main system HDD 109 and the main system ROM 110 for the processes in steps S1101, S1102, S1104, S1105, S1110, and S1113. This is done by executing the process.

  In the flowchart of FIG. 11, the processes in steps S1103, S1106 to S1109, S1111, and S1112 are performed by the CPU 301 of the subsystem 102 using a computer program and data stored in the subsystem ROM 105. It is done by executing.

<Step S1101>
The CPU 201 displays a power state change screen that is an example of a GUI for changing the power state of the information processing apparatus 1000 on the display screen of the operation unit 111. A display example of the power state change screen is shown in FIG. Buttons 1202 and 1203 are provided on the power state change screen 1201 of FIG. The user can switch between selection / non-selection of the buttons 1202 and 1203 every time the buttons 1202 and 1203 displayed on the display screen are touched or every time a hard key of the operation unit 111 is operated. Note that only one of the buttons 1202 and 1203 can be selected. However, when the user selects the button 1202, the button 1203 is in a non-selected state, and when the user selects the button 1203, the button 1202 is in a non-selected state. The CPU 201 controls the power state change screen 1201.

  When the button 1202 is selected, the CPU 201 sets that the information processing apparatus 1000 uses a function of responding to NW packets in the power saving state. When the button 1203 is selected, the CPU 201 sets that all functions are used even in the power saving state. When the button 1202 is selected, the CPU 201 turns on the flag A for determining the power state in the power saving state of the subsystem 102 and turns off the flag B (for example, sets “1” in the flag A). , “0” is set in the flag B). On the other hand, when the button 1203 is selected, the CPU 201 turns off the flag A for judging the power state in the power saving state of the subsystem 102 and turns on the flag B (for example, sets “0” in the flag A). And “1” is set in the flag B). Note that when neither of the buttons 1202 and 1203 is selected on the power state change screen 1201 of FIG. 12, both the flag A and the flag B are OFF.

<Step S1102>
The CPU 201 transmits the flag A and flag B set in step S1101 to the subsystem 102 via the subsystem IF unit 207.

<Step S1103>
The CPU 301 on the subsystem 102 side receives the flag A and flag B transmitted from the main system 101 via the main system IF unit 304 and stores the received flag A and flag B in the subsystem DRAM 107. .

<Step S1104>
“A button for shifting the power state of the information processing apparatus 1000 from the operating state to the power saving state” provided on the operation unit 111 (which may be a hard key or displayed on a display screen of the operation unit 111 , A touchable button may be operated), the CPU 201 detects the operation.

<Step S1105>
The CPU 201 outputs an instruction to shift to the power saving state to the subsystem 102 via the subsystem IF unit 207.

<Step S1106>
The CPU 301 on the subsystem 102 side reads the flag A and flag B stored in the subsystem DRAM 107 in step S1103. If flag A = OFF and flag B = ON, the process advances to step S1107. If flag A = ON and flag B = OFF, the process advances to step S1108. If flag A = OFF and flag B = OFF, the process advances to step S1109.

<Step S1107>
The CPU 301 determines to set the power state of the subsystem 102 in the power saving state to the all power ON state, and notifies the main system 101 of the recovery time of the subsystem 102 in the all power ON state (5 msec in the case of FIG. 10). To do.

<Step S1108>
The CPU 301 determines to set the power state of the subsystem 102 in the power saving state to the NW response state, and notifies the main system 101 of the return time of the subsystem 102 in the NW response state (50 msec in the case of FIG. 10).

<Step S1109>
The CPU 301 determines to set the power state of the subsystem 102 in the power saving state to the operation stop state, and notifies the main system 101 of the return time of the subsystem 102 in the operation stop state (200 msec in the case of FIG. 10).

<Step S1110>
When the CPU 201 on the main system 101 side receives the return time notified in any of steps S 1107 to S 1109 via the subsystem IF unit 207, the CPU 201 stores the return time in the main system DRAM 106.

<Step S1111>
The CPU 301 on the subsystem 102 side stores in the subsystem DRAM 107 setting information on the components in the subsystem 102 whose power is shut off in the power state determined in any of steps S1107 to S1109.

<Step S1112>
The CPU 301 stores the power state determined in any one of steps S1107 to S1109 in the subsystem DRAM 107 and notifies the internal power supply control unit 307. When receiving the notification of the power state determined from the CPU 301, the internal power control unit 307 controls the power ON / OFF for each component in the subsystem 102 according to the notified power state (in FIG. 10). The power state corresponding to the notified power state is set to complete the transition of the subsystem 102 to the power saving state.

<Step S1113>
The CPU 201 on the main system 101 side instructs the power supply control unit 104 to shift to the power saving state. The power supply control unit 104 controls the power supply of the information processing apparatus 1000 by instructing the power supply unit 108 to change to the power supply state illustrated in FIG. 10 and the transition to the power saving state is completed.

  Next, the processing performed by each of the CPU 201 of the main system 101 and the CPU 301 of the subsystem 102 in order to shift the information processing apparatus 1000 that has shifted to the power saving state through the processing according to the flowchart of FIG. 11 to the operating state. This will be described with reference to the flowchart of FIG.

  In the flowchart of FIG. 13, the processes in steps S1301, S1303 to S1305, and S1309 are performed by the CPU 201 of the main system 101 using computer programs and data stored in the main system HDD 109 and the main system ROM 110. It is done by doing.

  In the flowchart of FIG. 13, the processing in each of steps S1302 and S1306 to S1308 is performed by the CPU 301 of the subsystem 102 executing processing using a computer program and data stored in the subsystem ROM 105. Is.

  In the present embodiment, it is assumed that the CPU 301 of the subsystem 102 issues a transition instruction to the operation state of the information processing apparatus 1000. Of course, the power supply control unit 104 may perform the same as in the first embodiment.

<Step S1301>
The CPU 201 on the main system 101 side is waiting for a return interrupt from the CPU 301 of the subsystem 102.

<Step S1302>
The CPU 301 on the subsystem 102 side outputs a return interrupt to the main system 101.

<Step S1303>
When the CPU 201 receives a return interrupt from the CPU 301 of the subsystem 102, it outputs a power-on signal to the power control unit 104. Upon receiving the power-on signal, the power control unit 104 instructs the power supply unit 108 to supply power to all the components of the information processing apparatus 1000.

<Step S1304>
The CPU 201 issues a return instruction to the subsystem 102 via the subsystem IF unit 207.

<Step S1305>
The CPU 201 reads the return time stored in the main system DRAM 106 in step S1110. The CPU 201 measures the elapsed time after the start of the process in step S1303 (after the start of the return process to the operation state) using an internal timer (not shown), and whether or not the elapsed time exceeds the return time. Judging. As a result of this determination, if it exceeds, the process proceeds to step S1309. If not, the process waits in step S1305.

<Step S1306>
When the CPU 301 on the subsystem 102 side receives a return instruction from the main system 101 via the main system IF unit 304, it instructs the internal power control unit 307 to turn on the power. Upon receiving the power-on instruction, the internal power control unit 307 supplies power to all the components of the subsystem 102.

<Step S1307>
The CPU 301 reads “the power state of the subsystem 102 in the power saving state” stored in the subsystem DRAM 107 in step S1112. If the read “power state of the subsystem 102 in the power saving state” is the all power ON state, the processing proceeds without doing anything, and the read “power state of the subsystem 102 in the power saving state”. "Is either the NW response state or the operation stop state, the process proceeds to step S1308.

<Step S1308>
The CPU 301 reads the setting information stored in the subsystem DRAM 107 in step S1111, that is, the setting information of the component in the subsystem 102 that is powered off in the power state read in step S1307, and uses the setting information, In the power state read in step S1307, the components in the subsystem 102 whose power is shut off are reset.

<Step S1309>
The CPU 201 on the main system 101 side starts access to the subsystem 102 via the subsystem IF unit 207 and performs return processing.

  As described above, according to the present embodiment, the return from the power saving state to the operation state can be realized by an interrupt notification from the subsystem 102 to the main system 101. Also, it is possible to take a power state that does not require resetting in the power state of the subsystem 102 in the power saving state.

(Other examples)
The present invention supplies a program that realizes one or more functions of the above-described embodiments to a system or apparatus via a network or a storage medium, and one or more processors in a computer of the system or apparatus read and execute the program This process can be realized. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

  101: Main system 102: Subsystem 103: Subsystem

Claims (11)

An information processing apparatus having a main system and a subsystem communicably connected to the main system,
The subsystem determines one power state from among a plurality of power states that can be taken by the subsystem based on an instruction for shifting the power state of the information processing apparatus to a power saving state. And notifies the main system of a recovery time corresponding to the determined one power state and required for the subsystem to recover from the determined one power state,
The main system determines a power state to which the main system shifts from a plurality of power states that can be taken by the main system based on the return time notified from the subsystem. Processing equipment.   The subsystem is an external device for the subsystem out of a plurality of power states that can be taken by the subsystem based on the input of an instruction for shifting the power state of the information processing apparatus to a power saving state. The information processing apparatus according to claim 1, wherein the main system is notified of a return time corresponding to a power state corresponding to the connection state.   Whether the subsystem gives priority to power consumption in the power saving state based on the input of an instruction for shifting the power state of the information processing apparatus to the power saving state, or the normal operation state from the power saving state The main system is notified of a return time corresponding to a power state in accordance with information indicating whether to give priority to the time for shifting to, and a connection state of an external device to the subsystem. Item 4. The information processing apparatus according to Item 1.   Based on the input of the instruction for shifting the power state of the information processing apparatus to the power saving state, the subsystem returns corresponding to the power state according to the type of processing that can be executed in the power saving state. The information processing apparatus according to claim 1, wherein the time is notified to the main system.   The subsystem corresponds to the one power state among functional units constituting the subsystem under control for the main system to shift the power state of the information processing apparatus to a power saving state. 5. The information processing apparatus according to claim 1, wherein the power supply to the function unit is cut off.   6. The system according to claim 1, wherein when there are a plurality of subsystems, the main system starts access from the subsystems in ascending order of the notified recovery time. Information processing device.   The device for controlling the power supply of the information processing apparatus is input by the device for controlling the power supply of the information processing apparatus as an instruction for returning the power state of the information processing apparatus in the power saving state to the normal operation state. The information processing apparatus according to item 1.   The information processing according to any one of claims 1 to 6, wherein the subsystem inputs an instruction for restoring the power state of the information processing apparatus in a power saving state to a normal operation state. apparatus.   The instruction for returning the power state of the information processing apparatus in the power saving state to the normal operation state is input by the subsystem according to the analysis result of the data that can be received by the information processing apparatus in the power saving state. The information processing apparatus according to claim 8.   The main system accesses the subsystem according to the elapse of the return time from the start of the operation of returning the power state of the information processing apparatus to the normal operation state. Information processing device. A control method of an information processing apparatus having a main system and a subsystem communicably connected to the main system,
The subsystem determines one power state from among a plurality of power states that can be taken by the subsystem based on an instruction for shifting the power state of the information processing apparatus to a power saving state. And notifies the main system of a recovery time corresponding to the determined one power state and required for the subsystem to recover from the determined one power state,
The main system determines a power state to which the main system shifts from a plurality of power states that can be taken by the main system based on the return time notified from the subsystem. A method for controlling a processing apparatus.

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