JP4631385B2 - Controller, image forming apparatus, and power supply control method - Google Patents

Description

  The present invention relates to a controller, an image forming apparatus, and a power control method, and in particular, a controller applicable to both a copying machine and a multifunction machine having functions such as printing, copying, and facsimile, and the controller. The present invention relates to an image forming apparatus and a power supply control method.

  Recent image forming apparatuses such as multifunction peripherals often have a power saving mode. In the power saving mode, in order to reduce power consumption, power supply to an engine control board that controls the print engine unit and the engine unit is stopped, and unnecessary power supply in the board is stopped.

  For example, in the technique described in Patent Document 1, when an interface capable of causing a host device such as a personal computer to wait for data transmission is connected to a printing device, printing means (print engine) and control means (controller) other than this interface are connected. ) And power off. Also, when an interface such as a network that cannot wait for data transmission to the host device is connected, the power of the printing means (print engine) is stopped and the clock supply to the control means (controller) is stopped. Yes.

  Further, in the technique described in Patent Document 2, when the option board is installed, only the power supply to the reading unit and the recording unit is stopped, and when the option board is not installed, the reading unit and the recording unit are stopped. And stopping the power supply to the image processing unit has been proposed.

  By the way, as an image forming apparatus, there are a copying machine and a multifunction machine (having a copying and printing function). The single copy machine only needs to allow the user to set a document on the reading device and copy the document. On the other hand, the multifunction peripheral provides a printing function via a network in addition to copying, and means for communicating with the host is indispensable.

  Conventionally, a single copy machine is equipped with a copy controller for controlling printing of an image read by a scanner, and a multi-function machine is equipped with a communication means for communicating between the copy controller and the host to receive print data from the host. A print controller for image processing was installed, and a separate controller was installed for each copy machine and multifunction machine.

Recently, with the main purpose of image data processing and data path unification, a common controller that realizes both copying and printing functions has been installed and controlled. This makes it possible to unify the storage media for copying (for example, hard disks) and the storage media for printing. Furthermore, it is possible to upgrade a copy machine to a multifunction machine later by simply changing the software. It becomes.
Japanese Patent Laid-Open No. 2001-180083 JP 2002-281190 A

  However, the copy machine requires a different power consumption target than the multifunction machine and requires lower power consumption. In the technology described in Patent Document 1, it is not premised on the use of a controller supplied by a single copy machine and a multifunction machine. Therefore, when the controller described in Patent Document 1 is mounted on a single copy machine, the single copy machine is used. However, since power is supplied to unnecessary communication interface circuits, there is a problem that it cannot be said that reduction of power consumption is sufficient.

  Also in the technique described in Patent Document 2, when the option board is not mounted, power is supplied to the control means (controller), so it cannot be said that the power consumption is sufficiently reduced.

  The present invention has been made to solve the above problems, and provides a controller, an image forming apparatus, and a power supply control method capable of performing optimum power saving control according to apparatuses such as a copying machine and a multifunction machine. The purpose is to do.

In order to achieve the above object, a controller according to claim 1 is a controller that has a power saving mode for reducing power consumption and can be mounted in common in an image forming apparatus including a single copying machine and a multifunction machine. A first power supply that supplies power to a main control unit that controls the entire image forming apparatus including communication with the outside, and a second power supply that supplies a print processing unit that performs processing for printing. And a dividing unit that divides the power supply control circuit to supply power to the main control unit and the print processing unit, and that is divided into three power supply units , the first power supply, and the second power supply. Of the power supply and the third power supply, the controller stops the first power supply and the second power supply during the power saving mode when the controller is mounted on a copy machine. Compound machine In the power saving mode when mounted, to stop the second power supply is characterized by comprising a control means for controlling the power supply divided by the dividing means. The controller according to claim 2 is a controller that is equipped with a power saving mode for reducing power consumption and can be mounted in common in an image forming apparatus including a single copying machine and a multi-function machine. Processing for performing first power supply and printing to be supplied to the main control unit excluding storage means used when executing a program in the main control unit that controls the entire image forming apparatus including communication with the outside. The second power supply to be supplied to the print processing unit to be performed, and the third power supply to be supplied to the power control circuit for controlling the power supply to the main control unit and the print processing unit and the storage unit Of the first power supply, the second power supply, and the third power supply in the power saving mode when the controller is mounted on a single copy machine. of The power supply divided by the dividing means so as to stop the power supply and the second power supply, and stop the second power supply in the power saving mode when the controller is mounted on the multifunction peripheral. And a control means for controlling.

According to the first and second aspects of the present invention, the dividing means divides the power supply into a plurality of parts, and the control means supplies the power supply divided by the dividing means in the power saving mode according to the device on which the controller is mounted. Is controlled. That is, since power supply in the power saving mode is controlled according to the image forming apparatus equipped with the controller, optimal power saving control according to the image forming apparatus such as a single copying machine or a multifunction peripheral can be performed.

According to claim 1 this time, dividing means, the power supply line, supply a first power supply for supplying to the main control unit for controlling the entire image forming apparatus including the communication with the outside, a process for performing printing second power supply supplies to the print processing unit that performs, as well, the main control unit and divided into three third power supply for supplying a power supply control circuit for controlling the power supply to the print processing unit, the control means a first power supply, a second power supply, and a third of the power supply, the power saving mode when the controller is mounted to the copy a single unit, the first power supply Kyu及 beauty second the power supply is stopped, the controller in the power saving mode when mounted in the MFP, and controls the dividing means so as to stop the second power supply. That is, in the case of copying a single unit because communication from the outside is not required, becomes unnecessary energization of the main control unit stops the first power supply Kyu及 beauty second power supply, the MFP in the case of, since a communication with the outside, and stops only the second power supply. At this time, since the power is always supplied to the power control unit that controls the power supply to the main control unit and the print processing unit, the power control unit can perform the power saving mode return operation and the like. Therefore, this makes it possible to perform optimum power saving control according to the image forming apparatus equipped with the controller.

Further, in claim 2, storage means dividing means, a power supply, for use in performing the program in the main control unit for controlling the entire image forming apparatus including the communication with the outside (e.g., system RAM, etc.) first power supply supplies to the main control unit except the second power supply supplies to the print processing unit that performs processing for printing, as well as the power supply to the main control unit and a print processing unit divided into control to the power control circuit and the three third power supply for supplying to the storage means, control means, first power supply, a second power supply, and a third of the power supply, the controller There in the power saving mode when mounted in copying a single unit, the first power supply Kyu及 beauty second power supply is stopped, the power saving mode when the controller is mounted on the MFP, to stop the second power supply. That is, in the case of copying a single unit because communication from the outside is not required, becomes unnecessary energization of the main control unit stops the first power supply Kyu及 beauty second power supply, the MFP in the case of, since a communication with the outside, and stops only the second power supply. In addition, since the power is always supplied to the power control unit that controls the power supply to the main control unit and the print processing unit, the power control unit can perform the power saving mode return operation and the like. Therefore, this makes it possible to perform optimum power saving control according to the image forming apparatus equipped with the controller.

Furthermore, since the power is always supplied to the storage means, it is possible to hold the program or the like developed in the storage means when the power is turned on and to start the program immediately upon return from the power saving mode. . For example, as in the third aspect of the present invention, the information processing apparatus further includes a determination unit that determines whether the power is turned on or the return from the power saving mode. When the determination result of the determination unit is power on, The program is executed after the program is expanded to the storage means, and when the determination result of the determination means is a return from the power saving mode, the program expanded in the storage means is executed when the power is turned on. As a result, the time required for the return operation from the power saving mode can be shortened.

An image forming apparatus according to a fourth aspect includes the controller according to any one of the first to third aspects.

According to the fourth aspect of the present invention, since the controller according to any one of the first to third aspects is provided, the optimum saving according to the apparatus such as a single copy machine or a multifunction machine is provided. Power control can be performed.

The power control method according to claim 5 is a power control method by a controller having a power saving mode for reducing power consumption and that can be mounted in common on apparatuses including a single copying machine and a multifunction machine. A first power supply that supplies a main control unit that controls the entire image forming apparatus including communication with the outside, a second power supply that supplies a print processing unit that performs processing for printing, and The first power supply, the second power supply, and the third power supply are divided into three parts: a third power supply that is supplied to a power supply control circuit that controls power supply to the main control unit and the print processing unit. 3, the first power supply and the second power supply are stopped during the power saving mode of the copy machine, and the second power supply is stopped during the power saving mode of the multifunction machine. It is characterized by stopping . The power control method according to claim 6 is a power control method by a controller that can be mounted in common in a device including a copy machine and a multi-function device, which has a power saving mode for reducing power consumption. First power supply and printing for supplying a power supply line to the main control unit excluding storage means used when executing a program in the main control unit that controls the entire image forming apparatus including communication with the outside. A second power supply to be supplied to a print processing unit that performs processing for performing, and a third power source to be supplied to a power control circuit that controls power supply to the main control unit and the print processing unit, and the storage unit The first power supply, the second power supply, and the third power supply among the first power supply, the third power supply, and the first power supply Second power supply Stop, in the power saving mode of the MFP, it is characterized by stopping the second power supply.

According to the fifth and sixth aspects of the invention, the power supply is divided into a plurality of parts, and the divided power supply is controlled according to the image forming apparatus equipped with the controller in the power saving mode. That is, since the power supply in the power saving mode is controlled according to the image forming apparatus equipped with the controller, the optimum power saving control according to the image forming apparatus such as a single copying machine and a multifunction peripheral can be performed. It is possible to mount a controller that is common to a single copy machine and a multifunction machine.

According to claim 5 this time, the power supply line, a first power supply for supplying to the main control unit for controlling the entire image forming apparatus including the communication with the outside, the print processing unit that performs processing for printing second power supply for supplying, as well as divided into three third power supply for supplying a power supply control circuit for controlling the power supply to the main control unit and a print processing unit, the first power supply, a second power supply, and a third of the power supply, the power saving mode when the controller is mounted to the copy a single unit, to stop the first power supply Kyu及 beauty second power supply, the controller in the power saving mode when mounted in the MFP stops the second power supply. That is, in the case of copying a single unit because communication from the outside is not required, becomes unnecessary energization of the main control unit stops the first power supply Kyu及 beauty second power supply, the MFP in the case of, since a communication with the outside, and stops only the second power supply. In addition, since the power is always supplied to the power control unit that controls the power supply to the main control unit and the print processing unit, the power control unit can perform the power saving mode return operation and the like. Therefore, this makes it possible to perform optimum power saving control according to the image forming apparatus equipped with the controller.

According to a sixth aspect of the present invention, the main control of the power supply line excluding the storage means (for example, system RAM, etc.) used when executing the program in the main control unit for controlling the entire image forming apparatus including communication with the outside. first power supply for supplying the parts, the second power supply supplies to the print processing unit that performs processing for printing, as well as the power supply control for controlling the power supply to the main control unit and a print processing unit divided into three third power supply supplied to the circuit and the memory unit, the first power supply, a second power supply, and a third of the power supply, the controller is mounted to the copy single unit in the power saving mode when a first power supply Kyu及 beauty second power supply is stopped, the power saving mode when the controller is mounted on the MFP, stops the second power supply To do. That is, in the case of copying a single unit because communication from the outside is not required, becomes unnecessary energization of the main control unit stops the first power supply Kyu及 beauty second power supply, the MFP in the case of, since a communication with the outside, and stops only the second power supply. In addition, since the power is always supplied to the power control unit that controls the power supply to the main control unit and the print processing unit, the power control unit can perform the power saving mode return operation and the like. Therefore, this makes it possible to perform optimum power saving control according to the image forming apparatus equipped with the controller.

Furthermore, since the power is always supplied to the storage means, it is possible to hold the program or the like developed in the storage means when the power is turned on and to start the program immediately upon return from the power saving mode. . For example, as in the seventh aspect of the invention, it is determined whether to turn on the power or return from the power saving mode, and when the determination result is power on, the storage unit is initialized and the program is stored in the storage unit. When the program is executed after deployment and the determination result is a return from the power saving mode, the program deployed in the storage means is executed when the power is turned on, so that the operation returns from the power saving mode. The required time can be shortened.

  As described above, according to the present invention, the power supply is divided into a plurality of units, and in the power saving mode, the divided power supply is controlled according to the device such as a copy machine or a multifunction machine. There is an effect that it is possible to perform optimum power saving control according to the apparatus such as a machine.

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

  FIG. 1 is a block diagram showing a configuration of a controller that can be commonly mounted in an image processing apparatus such as a single copying machine or a multifunction machine.

  As shown in FIG. 1, a controller 10 according to the present embodiment includes a main control unit 22 including a CPU 12, a system RAM 14, a program ROM 16, a bus bridge circuit 18, a host interface controller 20, and the like, and a user interface controller (UI controller). 24, a print processing unit 28 including a video interface controller 26, a power control unit 30, a power saving key press detection circuit 32, a return control unit 52 including an LED lighting circuit 34, an FET switch A36, an FET And a switch B38.

  A system RAM 14 and a program ROM 16 are arranged on the memory bus 40. The CPU 12 that executes a control program (hereinafter referred to as a program) communicates with the system RAM 14 and the program ROM 16 by the control function of the memory bus 40 by the bus bridge circuit 18.

  The bus bridge circuit 18 is also connected to the I / O bus 42. The I / O bus 42 includes a user interface controller 24 serving as an interface with an external device, a video interface controller 26 serving as an interface with the print engine 44 and the scanner 46, and a host interface controller serving as an interface with the host machine 47. 20 is connected.

  The CPU 12 develops and executes the program stored in the program ROM 16 on the system RAM 14 and performs processing using the system RAM 14 as a work area. Data and programs being processed are written in the system RAM 14.

  The bus bridge circuit 18 has a relay of data exchange between the CPU 12 and the I / O bus 42 and a control function of the memory bus 40 (a control function of the system RAM 14 and an access control function of the program ROM 16).

  The user interface controller 24 connected to the I / O bus 42 controls an interface with a control panel 48 having an LCD (Liquid Crystal Display) or a numeric keypad.

  The video interface controller 26 controls the print engine 44 and the scanner 46 to be connected. The video interface controller 26 has a function of outputting image data to the print engine 44 and a function of inputting image data read by the scanner 46.

  The host interface controller 20 is a USB or IEEE. An interface with an external host machine such as a PC connected by 1284 is controlled.

  The above-mentioned program ROM 16 refers to a flash memory, a one-time PROM (Programmable Read Only Memory), a mask ROM, etc., and the system RAM 14 refers to an SDRAM (Synchronous Dynamic Random Access Memory), a DDR SDRAM (Double Data Rate SDRAM). It is assumed that it indicates a RAM that can be accessed at high speed.

  The FET switch A36 is a switch for turning on / off the supply of the power supplied from the power supply 50 to the main control unit 22, and the FET switch B38 is the switch of the power supplied from the power supply 50 to the print processing unit 28. This is a switch for turning on / off the supply, and the FET switch A 36 and FET switch B 38 are controlled by the power supply controller 30.

  As shown in FIG. 1, the return control unit 52 includes a power control unit 30, a power saving key press detection circuit 32, and an LED lighting circuit 34.

  The power control unit 30 detects pressing of the power saving key 54 provided on the control panel 48. When the power saving key 54 is pressed, a detection signal is output to the power supply control unit 30.

  When the LED lighting circuit 34 is set in the power saving mode, the power saving LED 56 provided on the control panel 48 is turned on under the control of the CPU 12. By turning on the power saving LED 56, it is displayed that the image processing apparatus on which the controller 10 is mounted is set in the power saving mode.

  As shown in FIG. 1, the FET switch A 36, the FET switch B 38, and the return control unit 52 are connected to the third power supply line Vcc-0 and are constantly supplied with power from the power supply 50. Yes.

  The main control unit 22 is connected to the first power supply line Vcc-1, and the print processing unit 28 is connected to the second power supply line Vcc-2.

  That is, the controller 10 according to the present embodiment supplies the power supply from the power supply 50 to the three power supply lines by using the FET switch A36 and the FET switch B38. The power supply line Vcc-0 always supplies power from the power supply 50, and the power supply lines Vcc-1 and Vcc-2 are controlled by turning on / off the FET switch A36 and FET switch B38. .

  Next, detailed configurations of the power saving key press detection circuit 32, the power supply control unit 30, and the FET switch A36 will be described. FIG. 2 is a diagram showing a detailed configuration of the power saving key press detection circuit 32, the power supply control unit 30, and the FET switch A36. In FIG. 2, only the portion related to the FET switch A36 is shown.

  The FET switch A36 is composed of a P-channel MOSFET as shown in FIG. 2, and the output of the power supply control unit 30 is input to the gate. Further, the drain is connected to the power supply line Vcc-0 (third power supply line), and the source is connected to the power supply line Vcc-1 (first power supply line) for supplying power to the main controller 22. . In this embodiment, an example in which a P-channel MOSFET is used as the FET switch A36 will be described. However, an N-channel MOSFET may be applied. As a matter of course, the logic change of the gate control is necessary.

  The power supply control unit 30 includes the register circuit 30A shown in FIG. 2, and receives control signals such as an address signal, a chip select signal, and a write enable signal and write data from the CPU 12. Further, a clear signal (detection signal) described later is input from the power saving key press detection circuit 32. The register circuit 30A writes the write data according to the control signal output from the CPU 12, more specifically, the CPU 12 writes from the I / O bus 42 to the register circuit 30A via the bus bridge circuit 18. The written data is output to the gate of the FET switch A36. Further, upon receiving a clear signal (detection signal) from the power saving key press detection circuit 32, the register circuit 30A clears and initializes the written data. That is, when “1” data is written in the register circuit 30A, a high level voltage is applied to the gate of the FET switch A36, and the FET switch A36 is closed. When a clear signal is input, a low level voltage is applied to the gate of the FET switch A36 to turn on the FET switch A36.

  As shown in FIG. 2, the power saving key press detection circuit 32 connects the power saving key 54 of the control panel 48 and the AND gate 32 </ b> A by wiring, and applies the power supply voltage Vcc-0 to the wiring through the resistor R. . When the power saving key 54 is pressed, the wiring is grounded to GND, and a low level signal is input to the AND gate 32A. A low level clear signal is output from the AND gate 32A to the register circuit 30A. When the clear signal (detection signal) is input to the register circuit 30A, the register circuit 30A clears and initializes the held data. A low level voltage is applied to the gate of the FET switch A36, and the FET switch A36 is turned on.

  The reset signal from the reset IC 32B is input to the AND gate 32A. When the power is turned on, the reset IC outputs a PowerON reset signal at a low level for a predetermined period. The reset signal is input as a clear signal (detection signal) to the register circuit 30A, and the register circuit 30A clears and resets the held data. As a result, when the power is turned on, the FET switch A36 is turned on, the power supply line Vcc-1 is at the same voltage level as the power supply line Vcc-0, and power is supplied to the main controller 22 through the power supply line Vcc-1. Is called.

  When shifting to the power saving mode, the CPU 12 writes “1” data in the register circuit 30A. As a result, the gate of the FET switch A36 becomes high level, and the FET switch A36 is turned off. The drain / source of the FET switch A36 is cut off, and the first power supply line (Vcc-1) for supplying power to the main controller 22 becomes 0V.

  The operation is restored by pressing the power saving key 54 on the control panel 48. When the power saving key 54 is pressed, the wiring connecting the power saving key 54 and the AND gate 32A becomes low level. For this reason, a clear signal (detection signal) is output to the register circuit 30A, and the output of the register circuit 30A becomes low level. As a result, the FET switch A36 is turned on and the power supply line Vcc-1 is set to a voltage level equivalent to that of the power supply line Vcc-0. Accordingly, the power supply from the power source 50 is resumed to the main control unit 22.

  Next, detailed configurations of the power supply control unit 30 and the FET switch B38 described above will be described. FIG. 3 is a diagram showing a detailed configuration of the power supply control unit 30 and the FET switch B38. In FIG. 3, only the portion related to the FET switch B38 is shown. Further, the power supply control unit 30 that controls the FET switch B32 may be the same as that shown in FIG.

  As shown in FIG. 3, the FET switch B38 is composed of a P-channel MOSFET, and the output of the power supply control unit 30 is input to the gate. The drain is connected to the power supply line Vcc-0 (third power supply line), and the source is connected to the power supply line Vcc-2 (second power supply line) that supplies power to the print processing unit 28. . In this embodiment, an example in which a P-channel MOSFET is used as the FET switch B38 will be described. However, an N-channel MOSFET may be applied. As a matter of course, the logic change of the gate control is necessary.

  The power supply control unit 30 further includes a register circuit 30B shown in FIG. 3 in addition to the register circuit 30A described above, and receives control signals such as an address signal, a chip select, a write enable signal, and write data from the CPU 12. The register circuit 30B writes the write data in accordance with the control signal output from the CPU 12, more specifically, the CPU 12 writes from the I / O bus 42 to the register circuit 30B via the bus bridge circuit 18. The written data is output to the gate of the FET switch B38. Further, the written data is cleared and initialized. That is, similarly to the register circuit 30A, when “1” data is written in the register circuit 30B, a high level voltage is applied to the gate of the FET switch B38, and the FET switch B38 is closed. When a clear signal is input, a low level voltage is applied to the gate of the FET switch B38, and the FET switch B38 is turned on.

  The reset signal from the reset IC 32B is input to the register circuit 30B. The reset IC 32B outputs a PowerON reset signal at a low level for a predetermined period when the power is turned on. The reset signal is input as a clear signal (detection signal) to the register circuit 30B, and the register circuit 30B clears and resets the held data. As a result, when the power is turned on, the FET switch B38 is turned on, the power supply line Vcc-2 becomes the same voltage level as the power supply line Vcc-0, and the power supply line Vcc-2 is supplied to the print processing unit 28. Is called.

  Further, when shifting to the power saving mode, the CPU 12 writes data “1” in the register circuit 30B. As a result, the gate of the FET switch B38 becomes high level, and the FET switch B38 is turned off. The drain / source of the FET switch B38 is cut off, and the second power supply line (Vcc-2) for supplying power to the print processing unit 28 becomes 0V.

  To restore the operation, the CPU 12 writes “0” data in the register circuit 30B. As a result, the gate of the FET switch B38 becomes low level, the FET switch B38 is turned on, and the power supply line Vcc-2 is set to a voltage level equivalent to that of the power supply line Vcc-0. Accordingly, the supply of power to the print processing unit 28 is resumed.

  Next, the operation of the entire controller will be described. The controller 10 has two operation modes, a normal operation mode and a power saving mode. The controller 10 according to the present embodiment performs different power saving modes depending on whether the controller 10 is mounted on a single copy machine or a multifunction peripheral.

  In the normal operation mode, power is supplied to the entire controller. The controller 10 shifts to the power saving mode when the printing operation or the like is not performed for a predetermined time or when the power saving key 54 is pressed.

  Here, a flow of processing in the power saving mode performed by the controller 10 will be described. FIG. 4 is a flowchart showing an example of a processing flow in the power saving mode performed by the controller 10 according to the embodiment of the present invention.

  First, in step 100, it is determined whether or not the controller 10 is mounted on the copying machine. The determination is made, for example, by determining whether the program stored in advance in the program ROM 16 is for a single copying machine or a multifunction machine, or by checking the contents set in advance in the controller 10 by the CPU 12. If the determination is negative, that is, if the controller 10 is mounted on the multi-function peripheral, the process proceeds to step 102 where the power saving LED 56 on the control panel 48 is lit by the LED lighting circuit 34, and the process proceeds to step 104. Transition.

  In step 104, the CPU 12 writes "1" data to the register circuit 30B. As a result, a high level voltage is applied to the gate of the FET switch B38, and the FET switch B36 is closed. As a result, power supply to the power supply line Vcc-2 (second power supply line) is stopped. That is, as shown in FIG. 5, the power supply to the print processing unit 28 is stopped. In FIG. 5, the hatched portion represents a portion where power supply is stopped.

  In step 106, the CPU 12 and the bus bridge circuit 18 are shifted to a predetermined power save mode such as a clock stop. For example, in a predetermined power save mode, the CPU 12 and the bus bridge circuit 18 stop some of the clocks within themselves.

  Next, in step 108, it is determined whether or not the power saving mode has been canceled. This determination is made, for example, by the power saving key pressing detection circuit 32 determining whether or not the power saving key 54 on the control panel 48 is pressed. If the determination is negative, the process waits until the determination is affirmed and proceeds to step 110.

  In step 110, the CPU 12 and the bus bridge circuit 18 in the own power save in the CPU 12 and the bus bridge circuit 18 are also released. Next, the process proceeds to step 112, where the CPU 12 writes “0” data in the register circuit 30B. As a result, the gate of the FET switch B38 becomes low level, the FET switch B38 is turned on, and the power supply line Vcc-2 is set to a voltage level equivalent to that of the power supply line Vcc-0. Accordingly, the supply of power to the print processing unit 28 is resumed.

  In step 114, the power saving LED 56 on the control panel 48 is turned off, and the process of the power saving mode is ended.

  On the other hand, if the determination in step 100 is affirmative, that is, if the controller 10 is mounted on a single copy machine, the process proceeds to step 116, and the power saving LED 56 on the control panel 48 is lit by the LED lighting circuit 34. Transition.

  In step 118, the CPU 12 writes "1" data into the two register circuits 30A and 30B. As a result, a high level voltage is applied to the gates of the FET switch A36 and the FET switch B38, and the FET switch A36 and the FET switch B38 are closed. As a result, power supply to the power supply line Vcc-2 (second power supply line) and the power supply line Vcc1 (first power supply line) is stopped. That is, as shown in FIG. 6, the power supply to the main control unit 22 and the print processing unit 28 is stopped. In FIG. 6, the hatched portion represents the portion where the power supply is stopped.

  Next, in step 120, it is determined whether or not the power saving mode has been canceled. This determination is made, for example, by the power saving key pressing detection circuit 32 determining whether or not the power saving key 54 on the control panel 48 is pressed. Specifically, when the power saving key 54 is pressed, the determination is affirmed by clearing the register circuit 30A. If the determination is negative, the process waits until the determination is affirmed and the process proceeds to step 122.

  In step 122, the register circuit 30A is cleared by pressing the power saving key 54, the output of the register circuit 30A becomes low level, the FET switch A36 is turned on, and the power supply line Vcc-1 is equivalent to Vcc-0. Set to voltage level. Accordingly, the supply of power to the main control unit 22 is resumed.

  Subsequently, in step 124, when power is supplied to the main control unit 22 and the CPU 12 is activated, the CPU 12 writes "0" data to the other register circuit 30B. As a result, the gate of the FET switch B38 becomes low level, the FET switch B38 is turned on, and the power supply line Vcc-2 is set to a voltage level equivalent to that of the power supply line Vcc-0. Accordingly, the supply of power to the print processing unit 28 is resumed.

  Finally, in step 126, the power saving LED 56 on the control panel 48 is turned off, and the process of the power saving mode is ended.

  As described above, when the controller 10 according to the present embodiment is mounted on a multi-function peripheral, it can respond to a request from an external device such as a host machine when it shifts to the power saving mode. The power supply to the main control unit 22 is maintained and the power supply to the print processing unit 28 is stopped. In addition, when installed in a single copy machine, there is no problem even if the power supply to the main control unit 22 is stopped when shifting to the power saving mode, so the power to the main control unit 22 and the print processing unit 28 is not affected. Stop supplying. Accordingly, it is possible to perform optimum power saving control according to each of the single copy machine and the multifunction machine, and it is possible to mount the controller 10 in common to the single copy machine and the multifunction machine.

  In the above-described embodiment, when the controller 10 is mounted on a single copy machine, the power supply to the entire main control unit 22 is stopped when the mode is shifted to the power saving mode. The power may be turned on.

  FIG. 7 is a diagram showing a modified example of the power supply state in the power saving mode when the controller 10 is mounted on a single copy machine.

  In recent controllers, a program is developed and executed in a RAM that is faster than ROM in order to speed up image processing. In the power saving mode, the DRAM is put into the self-refresh mode without stopping the power supply of the RAM. In order to put the DRAM into self-refresh, it is necessary to keep the clock enable (CKE) signal at a low level. For example, a pull-down resistor is attached to the CKE signal, and the bus bridge circuit 18 drives the CKE signal to a low level, and then shifts to the power saving mode to control the FET switch A36 and the FET switch B38. Thus, before and after the power supply of the bus bridge circuit 18 is turned off, the CKE signal can be set to a low level, and self-refreshing can be performed.

  Further, as in the above-described embodiment, in the power saving mode of the single copy machine, the power of the CPU 12 is turned off, so that it cannot be distinguished from the power on even when returning to the normal operation mode. Therefore, the CPU 12 is provided with a signal for notifying whether it is the return from the power saving mode or the normal power-on. For example, the power supply control unit 30 further includes a register circuit, and before the CPU 12 shifts to the power saving mode, the CPU 12 accesses the register circuit and sets a bit indicating return from the power saving mode. A reset signal similar to that in FIG. 3 is connected to the clear terminal of the register circuit. For example, the CPU 12 writes “1” to the register circuit before shifting to the power saving mode. As a result, the CPU 12 can read the register circuit after the PowerON reset is released, and can detect that the power saving mode is restored if the value is “1”. On the other hand, when the power is turned on, the register circuit is cleared by the reset signal, and the value when the CPU 12 reads the register circuit becomes “0”. Alternatively, the output signal level of the register circuit may be confirmed.

  A DRAM such as an SDRAM needs a predetermined initialization when the power is turned on. Specifically, after the CKE signal is set to high level, bank precharge, mode register setting, refresh command issuance, and the like. When the CPU 12 detects the return from the power saving mode based on the value of the register circuit, the program has been developed on the DRAM and the data is retained by self-refresh. Without performing the above, the CKE signal is set to the high level, the self-refresh is canceled, and the normal operation mode is restored. By doing so, the program in the DRAM can be executed without developing the program from the ROM to the DRAM, and the time required to return to the normal operation mode can be shortened.

  On the other hand, when the CPU 12 detects that the power is normally turned on based on the value of the register circuit, after the DRAM is initialized, the program is expanded from the ROM to the DRAM, and then the program in the DRAM is executed. To do.

  Note that the controller 10 according to the embodiment of the present invention is commonly installed in a single copying machine and a multifunction machine, and can be copied by changing software or setting a software key code issued by the manufacturer of the image forming apparatus. It is also possible to upgrade a single machine to a multifunction machine.

  Moreover, said embodiment is a suitable Example of this invention. However, the present invention is not limited to this, and various modifications can be made without departing from the scope of the present invention. For example, the return control unit 52 of the above-described embodiment can be configured as a part of a programmable device such as a CPLD (Complex Programmable Logic Device).

1 is a block diagram illustrating a configuration of a controller that can be commonly mounted in an image processing apparatus such as a single copying machine or a multifunction peripheral according to an embodiment of the present invention. 2 is a diagram illustrating a detailed configuration of a power saving pressing detection circuit, a power supply control unit, and an FET switch 1. FIG. FIG. 3 is a diagram illustrating a detailed configuration of a power supply control unit and an FET switch 2. It is a flowchart which shows an example of the flow of the process at the time of the power saving mode performed with the controller concerning embodiment of this invention. FIG. 5 is a diagram illustrating a power supply state in a power saving mode when a controller is mounted on the multifunction peripheral. FIG. 5 is a diagram illustrating a power supply state in a power saving mode when a controller is mounted on a single copy machine. It is a figure which shows the modification of the power supply state at the time of a power saving mode when a controller is mounted in a single copy machine.

Explanation of symbols

10 Controller 14 System RAM
22 Main Control Unit 28 Print Processing Unit 30 Power Supply Control Unit 30A, 30B Register Circuit 32 Power Saving Key Press Detection Circuit 32A And Gate 32B Reset IC
36 FET switch A
38 FET switch B
50 Power supply 52 Return control unit 54 Power saving key

Claims (7)

A controller equipped with a power saving mode for reducing power consumption, which can be mounted in common in an image forming apparatus including a single copying machine and a multifunction machine,
A first power supply that supplies power to a main control unit that controls the entire image forming apparatus including communication with the outside; a second power supply that supplies a print processing unit that performs processing for printing; And a dividing means that divides the power supply control circuit for supplying power to the main control unit and the print processing unit into three third power supply units ,
Among the first power supply, the second power supply, and the third power supply, the first power supply and the third power supply are in the power saving mode when the controller is mounted on a copy machine. Control means for controlling the power supply divided by the dividing means so as to stop the second power supply in the power saving mode when the controller is mounted on the multifunction peripheral. When,
A controller characterized by comprising. A controller equipped with a power saving mode for reducing power consumption, which can be mounted in common in an image forming apparatus including a single copying machine and a multifunction machine,
First power supply and printing are performed to supply power to the main control unit excluding storage means used when executing a program in the main control unit that controls the entire image forming apparatus including communication with the outside. A second power supply to be supplied to the print processing unit for performing processing for the above, and a third power supply to be supplied to the power control circuit for controlling the power supply to the main control unit and the print processing unit and the storage unit Dividing means to divide the supply into three,
Among the first power supply, the second power supply, and the third power supply, the first power supply and the third power supply are in the power saving mode when the controller is mounted on a copy machine. Control means for controlling the power supply divided by the dividing means so as to stop the second power supply in the power saving mode when the controller is mounted on the multifunction peripheral. When,
A controller characterized by comprising . The apparatus further includes a determination unit that determines whether the power is turned on or the return from the power saving mode. When the determination result of the determination unit is power-on, the storage unit is initialized and the program is expanded in the storage unit. after running the program, according to when the determination result of said determination means is a return from the power saving mode, to claim 2, characterized in that executing the program loaded in the storage means when the power is turned on Controller. An image forming apparatus comprising the controller according to claim 1. A power control method by a controller that can be mounted in common on apparatuses including a copy machine and a multi-function machine having a power saving mode for reducing power consumption,
A first power supply that supplies power to a main control unit that controls the entire image forming apparatus including communication with the outside; a second power supply that supplies a print processing unit that performs processing for printing; And a third power supply that is supplied to a power control circuit that controls power supply to the main control unit and the print processing unit.
Out of the first power supply, the second power supply, and the third power supply, the first power supply and the second power supply are stopped when the copy machine is in the power saving mode. A power control method comprising: stopping the second power supply when the multifunction apparatus is in the power saving mode. A power control method by a controller that can be mounted in common on apparatuses including a copy machine and a multi-function machine having a power saving mode for reducing power consumption,
First power supply and printing for supplying a power supply line to the main control unit excluding storage means used when executing a program in the main control unit that controls the entire image forming apparatus including communication with the outside. A second power supply to be supplied to a print processing unit that performs processing for performing, and a third power source to be supplied to a power control circuit that controls power supply to the main control unit and the print processing unit, and the storage unit Divided into three power supply ,
Out of the first power supply, the second power supply, and the third power supply, the first power supply and the second power supply are stopped when the copy machine is in the power saving mode. A power control method comprising: stopping the second power supply when the multifunction apparatus is in the power saving mode . Determine whether the power is turned on or return from the power saving mode, and if the determination result is power on, initialize the storage means and deploy the program to the storage means, execute the program, and the determination result is 9. The power control method according to claim 8 , wherein when the power is restored from the power saving mode, the program developed in the storage unit is executed when the power is turned on.

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