JP2014142818A - Image processing device, control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image processing device which enables a user to use a facsimile function when the device is equipped with a facsimile as an option, and reduces power consumption when the device is not equipped with the facsimile as an option.SOLUTION: An image processing device can be equipped with a communication apparatus as an option, and operates in one of power consumption modes of at least a normal mode which activates the communication apparatus and a low power consumption mode which inactivates the communication apparatus. The image processing device comprises: means for detecting surrounding illuminance of the image processing device; means for determining whether the image processing device is equipped with the communication apparatus as an option; and means for shifting the power consumption mode into the low power consumption mode when the surrounding illuminance is found less than a predetermined threshold for a predetermined time. When it is determined that the image processing device is equipped with the communication apparatus as an option, even if the surrounding illuminance is found less than the predetermined threshold for the predetermined time, the image processing device maintains the power consumption mode as the normal mode.

Description

  The present invention relates to an image processing apparatus, a control method, and a program.

  An example of an image processing apparatus is a multifunction peripheral. A multifunction device is a device in which functions such as a copying machine, a printer, a scanner, and a facsimile are combined. When power is supplied to the operation unit panel, control unit, scanner unit, plotter unit, etc. when the multifunction device is not used, the multifunction device consumes wasted power. In view of this, the multi-function device normally has a normal mode in which power is supplied to the entire multi-function device in order to operate itself and a low power consumption mode in which power consumption is lower than that in the normal mode. A technique for switching the power consumption mode is known by using an operation key, a timer, an illuminance sensor, an ultrasonic sensor, an infrared sensor, or the like.

  Patent Document 1 discloses a method of turning on an image forming unit when the periphery of an image forming apparatus or a facsimile is brightened by an illuminance sensor for the purpose of reducing power consumption and improving user convenience. Has been.

  There are devices that can select whether or not to install a facsimile as an option in the multifunction machine. When the multifunction device does not have a facsimile as an option, it is determined that the surrounding area of the multifunction device has become dark based on the output value of the illuminance sensor, and the power of the multifunction device is shifted to the low power consumption mode. Power consumption can be reduced.

  However, when the multifunction device is equipped with a facsimile as an option, if it is determined from the output value of the illuminance sensor that the surrounding of the multifunction device has become dark and the power of the multifunction device is shifted to the low power consumption mode, There is a problem that a facsimile cannot be received. That is, if the facsimile is an option and the transition state of the power consumption mode is the same regardless of whether the facsimile is installed or not, the multifunction device cannot receive the facsimile in the low power consumption mode, and the user There was a problem that it was inconvenient for.

  The technique described in Patent Document 1 controls whether or not to activate the image forming unit based on the output of the illuminance sensor. However, Patent Document 1 is intended only for a facsimile machine that cannot select whether or not a facsimile is installed as an option in the first place, that is, on the premise that a facsimile is installed.

  Therefore, the case where the facsimile becomes an option is not considered. Then, even if a facsimile is installed, the power consumption mode remains the normal mode, so that power is supplied to other than the image forming unit. Therefore, the technique of Patent Document 1 has a problem that power consumption during standby cannot be reduced.

  Therefore, the present invention has been made in view of the above-described problems of the prior art, and when a communication device is installed as an option, the communication device can be used, and the communication device is installed as an option. When not, an object is to provide an image processing apparatus capable of reducing power consumption.

  In order to solve the above-described problem, the image processing apparatus according to the first aspect of the present invention can be equipped with a communication device as an option, and as a power consumption mode, a normal mode in which the communication device is in an operating state; An image processing apparatus having at least a low power consumption mode for disabling a device, wherein detection means for detecting illuminance around the image processing device and whether or not the communication device is installed as an option Determining means for determining, and control means for transitioning the power consumption mode to the low power consumption mode when the ambient illuminance is detected to be smaller than a predetermined threshold for a predetermined time by the detection means; And when it is determined by the determination means that the communication device is installed as an option, the ambient light intensity is determined by the detection means, Constant time, even when it is detected that is smaller than a predetermined threshold value, said control means, said power consumption mode, and maintains the normal mode.

  According to the present invention, it is determined whether or not a communication device is installed as an option, and when it is determined that the communication device is installed as an option, the power consumption mode is not changed to the low power consumption mode, Maintain mode. Thereby, a communication apparatus can be utilized. If it is determined that the communication device is not installed as an option, the power consumption mode is shifted to the low power consumption mode. Thereby, an image processing apparatus capable of reducing power consumption can be obtained.

1 is a schematic block diagram illustrating an overall configuration of an image processing apparatus according to an embodiment of the present invention. It is a schematic block diagram which shows the structure of the operation control part in the image processing apparatus which concerns on embodiment of this invention. It is a schematic block diagram which shows the structure of the execution control part in the image processing apparatus which concerns on embodiment of this invention. FIG. 3 is a circuit diagram illustrating a configuration of a facsimile option determination unit in the image processing apparatus according to the embodiment of the present invention. It is a figure explaining the interface between the execution control part and the operation control part in the image processing apparatus which concerns on embodiment of this invention. It is a state transition diagram explaining operation | movement of the power consumption mode in the image processing apparatus which concerns on embodiment of this invention. It is a flowchart explaining the operation | movement of the power consumption mode in the image processing apparatus which concerns on embodiment of this invention. It is a figure explaining the case where (a) it became bright and (b) it became dark as an example of the illumination intensity detection in the image processing apparatus which concerns on embodiment of this invention. It is a flowchart figure explaining the detection flow of the illumination intensity sensor in the image processing apparatus which concerns on embodiment of this invention.

  Next, embodiments for carrying out the present invention will be described in detail with reference to the drawings. In addition, in each figure, the same code | symbol is attached | subjected to the part which is the same or it corresponds, The duplication description is simplified thru | or abbreviate | omitted suitably. According to the present invention, when a communication device is installed as an option, the power consumption mode is maintained in the normal mode, and the convenience of the user is improved. If it is not installed as an option, power consumption will be reduced.

  In short, the image processing apparatus according to the embodiment of the present invention includes a normal mode and a power consumption mode such as a low power consumption mode. And the illuminance sensor which detects illumination intensity, and the illumination intensity judgment part which detects light and dark from the output value of an illumination intensity sensor are provided. Further, a facsimile option determining unit that determines whether or not a facsimile as an example of a communication device is installed as an option is provided.

  When the facsimile option determining unit determines that the facsimile is installed as an option, even if the illuminance determining unit determines that the illuminance is dark, the power consumption mode is not changed to the low power consumption mode, and the normal mode is selected. It is characterized by maintaining. In the following description, a facsimile is used as an example of a communication device, but the communication device is not limited to a facsimile.

  First, a schematic configuration of an image processing apparatus according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a schematic block diagram showing the overall configuration of an image processing apparatus according to an embodiment of the present invention. In FIG. 1, a power supply 101 supplied from the outside is supplied to the image processing apparatus 100 and operates the image processing apparatus 100.

  The image processing apparatus 100 includes a PSU (Power Supply Unit) 102 that supplies power from the power source 101 to the image processing apparatus 100, an LCD (Liquid Crystal Display) 103 that displays image data, and an operation panel 104 that is operated by a user. Is composed of. In addition, the image processing apparatus 100 includes an operation control unit 105 that transmits operation information input from the operation panel 104 to the execution control unit 106, a scanner unit 107 that reads and converts a document into image data, and inputs image data. And a plotter unit 108 for executing printing. Further, the image processing apparatus 100 is connected to a public line, can send and receive facsimiles, and can be optionally installed as a facsimile unit 109, and a facsimile option for determining whether the facsimile unit 109 is installed in the image processing apparatus 100 And a determination unit 110.

  In addition, the image processing apparatus 100 includes an execution control unit 106. The execution control unit 106 executes the operation information from the operation control unit 105 and converts the image data output from the scanner unit 107 into image data that can be printed by the plotter unit 108. The execution control unit 106 is an interface that can communicate with an external network 111 and a USB (Universal Serial Bus) 112.

  Further, the image processing apparatus 100 includes F1 113 that supplies power supplied from the PSU 102 to the plotter unit 108, and F2 114 that supplies power supplied from the PSU to the scanner unit 107. F1 113 and F2 114 are both FETs (Field Effect Transistors).

  Next, the operation control unit 105 shown in FIG. 1 will be described with reference to FIG. FIG. 2 is a schematic block diagram showing the configuration of the operation control unit in the image processing apparatus according to the embodiment of the present invention. The operation control unit 105 includes a key input receiving unit 202 that receives input from a plurality of keys 201 on the operation panel, and a display unit (LED: Light Emitting Diode) 204 of the operation panel 203 of the image processing apparatus 100. .

  The operation control unit 105 includes an illuminance sensor 205 that detects brightness around the image processing apparatus, and an A / D (Analog / Digital) conversion 206 that quantizes the output of the illuminance sensor 205. Further, the operation control unit 105 includes an interface unit 207 that connects to the execution control unit 106 and a control unit 208 that controls the entire operation control unit 105. The operation control unit 105 includes a nonvolatile ROM (Read Only Memory) 209 that stores a program for the control unit 208 to control the entire operation control unit 105, and data for executing the operation of the entire operation control unit 105. And a RAM (Random Access Memory) 210 for storing.

  The key input accepting unit 202 removes chattering of the pressed key, and notifies the execution control unit 106 when there is a key input. The nonvolatile ROM 209 is configured by a flash ROM. Note that the control unit 208, the A / D conversion 206, the ROM 209, the RAM 210, and the interface unit 207 may be configured by the microcomputer 211. The microcomputer 211 determines the brightness around the image processing apparatus based on the value obtained by converting the output of the illuminance sensor 205 by the A / D conversion 206.

  Next, the execution control unit 106 shown in FIG. 1 will be described with reference to FIG. FIG. 3 is a schematic block diagram showing the configuration of the execution control unit in the image processing apparatus according to the embodiment of the present invention. The execution control unit 106 includes a clock generation unit 301 that supplies a clock to the entire execution control unit 106 and a main CPU (Central Processing Unit) 302 that controls the entire execution control unit 106.

  The execution control unit 106 includes a non-volatile ROM 303 that stores a first program that operates the Main CPU 302, and a DDR (Double Data Rate Synchronous Dynamic Random Access Memory) 304 that executes the first program at high speed. Composed. Furthermore, the execution control unit 106 includes a board power control unit 305 that controls the power of the execution control unit 106, an external power control unit 306 that controls the power of the scanner unit 107 (FIG. 1), the plotter unit 108, and the LCD 103, Consists of

  The execution control unit 106 includes a Sub CPU 307 that controls the board power control unit 305 and the external power control unit 306, a PHY (Physical Layer) 308 that communicates with the network 111, an ASIC (Application Specific Integrated Circuit) 309, Consists of

  The Sub CPU 307 includes a GIO, a flash ROM, a RAM, and an oscillation circuit. The ASIC 309 includes a CPU I / F 310 that is an interface with the Main CPU 302, a ROM I / F 311 that is an interface with the ROM 303, and a MEM I / F 312 that is an interface with the DDR 304.

  The ASIC 309 includes a PCI I / F 313 that is an interface with the scanner unit 107, the plotter unit 108, and the facsimile unit 109, and an OPU (Option Unit) I / F 314 that is an interface with the operation control unit 105. The Further, the ASIC 309 includes an LCD I / F 315 that is an interface with the LCD 103 and a USB 316 that communicates with the outside. The ASIC 309 includes a MAC (logical layer) 317 for connecting to the PHY 308 that performs network communication, and an internal BUS 318 that is an internal bus for connecting the above.

  Next, the facsimile option determining unit 110 shown in FIG. 1 will be described with reference to FIG. FIG. 4 is a circuit diagram showing a configuration of a facsimile option determination unit in the image processing apparatus according to the embodiment of the present invention.

  Since the facsimile unit 109 shown in FIG. 1 is an option, when the facsimile unit 109 is installed, the facsimile unit 109 outputs an active (High) signal via the buffer 401. If the facsimile unit 109 is not installed, the facsimile unit 109 does not output a signal.

  When an active (High) signal is output from the facsimile unit 109, the facsimile option determining unit 110 is an active signal indicating that the facsimile unit 109 is mounted on the execution control unit 106 (FIG. 1). High). The facsimile option determination unit 110 does not output a signal from the facsimile unit 109 to the facsimile option determination unit 110 unless the facsimile unit 109 is installed.

  Since the input of the facsimile option determining unit 110 is grounded by the Pull Down resistor 402, when there is no input to the facsimile option determining unit 110, the input of the buffer 401 of the facsimile option determining unit 110 becomes Low. Therefore, if the facsimile unit 109 is not installed, the facsimile option determining unit 110 outputs an inactive (Low) signal.

  Next, an interface between the execution control unit and the operation control unit will be described with reference to FIG. FIG. 5 is a diagram illustrating an interface between the execution control unit and the operation control unit in the image processing apparatus according to the embodiment of the present invention.

  The OPU I / F 314 on the execution control unit 106 side includes an I2C I / F Master 3141 and a GIO 3142. The I2C I / F Master 3141 in the OPU I / F 314 performs a master operation.

  The interface unit 207 on the operation control unit 105 side includes an I2C I / F Slave 2071 and a GIO 2072. The I2C I / F Slave 2071 in the interface unit 207 performs a slave operation. The I2C I / F Master 3141 and the I2C I / F Slave 2071 are connected by two signal lines of SCL and SDA. GIO3142 and GIO2072 are connected by KEYREQ_N.

  Next, the operation in the power consumption mode of the image processing apparatus will be described with reference to FIG. FIG. 6 is a state transition diagram for explaining the operation in the power consumption mode in the image processing apparatus according to the embodiment of the present invention.

  The Power OFF mode 601 is a state in which power is not supplied to all or a part of the image processing apparatus, and the power plug of the image processing apparatus is not inserted into an AC (Alternative Current) outlet. Hereinafter, the operation in the power consumption mode will be described in order.

  (1) When the power plug is inserted into the AC outlet, SDMODE_N becomes active (Low), so that the power consumption mode changes from the Power OFF mode 601 to the low power consumption mode 602.

  (3) When the power consumption mode is the low power consumption mode 602, when the Power SW 115 (FIG. 1) is pressed, the power consumption mode transits to the normal mode 603. In the normal mode 603, when the facsimile unit 109 is installed, the facsimile unit 109 is also in an operating state.

  If the facsimile unit 109 is not installed and the microcomputer 211 determines that the surroundings of the image processing apparatus have become bright, the power consumption mode changes from the low power consumption mode 602 to the normal mode 603.

  (4) When the power consumption mode is the normal mode 603, when a predetermined time has passed since the outside communication is lost, that is, when the non-operating state continues for a predetermined time, or when the ECO key 116 is pressed, The power consumption mode transitions to the energy saving mode 604.

  (5) When the power consumption mode is the energy saving mode 604, when the facsimile unit 109 receives a signal or when the ECO key 116 or another key 201 is pressed, the power consumption mode transits to the normal mode 603.

  (6) When the power consumption mode is the energy saving mode 604, if the facsimile unit 109 is not installed and the microcomputer 211 determines that the surroundings of the image processing apparatus have become dark, the power consumption mode transitions to the low power consumption mode 602. To do. In the low power consumption mode 602, the operation of the facsimile unit 109 is also stopped (hereinafter, this state is referred to as “non-operation state”).

  (7) When the power consumption mode is the normal mode 603, when the Power SW 115 is pressed, the power consumption mode transits to the low power consumption mode 602, and the facsimile unit 109 is also inoperative. However, when the facsimile unit 109 is installed, it is necessary to keep the facsimile unit 109 in an always operating state. For this reason, when the facsimile unit 109 is installed, even when the power SW 115 is pressed, the low power consumption mode 602 is not changed. Note that the user may be alerted that the facsimile unit 109 is in an inoperative state.

  Further, when the power consumption mode is the normal mode 603, even if the microcomputer 211 determines that the surroundings of the image processing apparatus have become dark with the facsimile unit 109 installed, the power consumption mode is changed from the normal mode 603. It is necessary to prevent transition to the low power consumption mode 602. This is to prevent the facsimile unit 109 from entering an inoperative state without the user's knowledge.

  (2) In this specification, the case where the power consumption mode is any one of the normal mode 603, the energy saving mode 604, and the low power consumption mode 602 is referred to as a power-supplied mode 605. When the power consumption mode is the Power Applied mode 605, SDMODE_N becomes inactive (High). In the power-supplied mode 605, when the power SW 115 is pressed or the power plug is removed from the AC outlet, the power consumption mode transitions to the power-off mode 601.

  Next, the operation in the power consumption mode of the image processing apparatus will be described with reference to FIG. FIG. 7 is a flowchart for explaining the operation in the power consumption mode in the image processing apparatus according to the embodiment of the present invention.

  First, when a power plug is inserted into an AC outlet, power is supplied to the PSU 102. Next, in the process of step 701 (hereinafter referred to as “S”) 701, the PSU 102 performs processing on the Sub CPU 307 of the execution control unit 106, the microcomputer 211 of the operation control unit 105, the facsimile unit 109, and the facsimile option determination unit 110. Supply power.

  When power is supplied to the Sub CPU 307 and the microcomputer 211, in the processing of S702, the programs on the ROM 303 and the ROM 209 are executed, and the Sub CPU 307 and the microcomputer 211 initialize. When the initialization of the Sub CPU 307 is completed, the power consumption mode is set to the low power consumption mode 602 in the process of S703.

  In the process of S704, the Sub CPU 307 determines whether or not the Power SW 115 is turned on. When the Sub CPU 307 detects that the Power SW 15 is turned on (S704: Y), the Sub CPU 307 sets the power consumption mode to the normal mode 603 in the processing of S705.

  When the facsimile option determining unit 110 determines that no facsimile is mounted and the microcomputer 211 of the operation control unit 105 determines that the surroundings of the image processing apparatus have become bright, the microcomputer 211 sets LDET_N to active (Low). (S708: Y). Thereby, the Sub CPU 307 sets the power consumption mode to the normal mode 603 (S705).

  When the sub CPU 307 sets the power consumption mode to the normal mode 603, the sub C 307 PU performs control so that power is supplied to the entire execution control unit 106 via the board power control unit 305. Further, the sub CPU 307 controls the power to be supplied to the scanner unit 107, the plotter unit 108, and the LCD 103 via the external power control unit 306. In this way, power is supplied to the entire image processing apparatus (S706).

  Since the facsimile unit 109 is an option, the facsimile unit may or may not be installed. When the facsimile unit 109 is installed, the facsimile unit 109 performs initialization when power is supplied from the PSU 102. When power is supplied to the execution control unit 106, the Sub CPU 307 supplies power to the clock generation unit 301, the Main CPU 302, the ASIC 309, the DDR 304, and the PHY 308.

  When power is supplied to the clock generation unit 301, the clock generation unit 301 generates a clock and supplies the clock to the main CPU 302, the ASIC 309, and the PHY 308. In the process of S707, the Main CPU 302 activates the first program stored in the ROM 303, and initializes the Main CPU 302 and the ASIC 309.

  When the initialization of the MEM I / F 312 in the ASIC 309 is completed, the Sub CPU 307 transfers the first program stored in the ROM 303 and the second program stored in the ROM 303 to the DDR 304. Sub CPU307 starts the 2nd program in DDR304 after transfer of the 2nd program. Since there is a program on the DDR 304, the Sub CPU 307 can execute the program at high speed.

  When the second program is started, the Sub CPU 307 initializes the OPU I / F 314, the LCD I / F 315, the USB 316, the MAC 317, and the PCI I / F 313 other than the ROM I / F 311 and the MEM I / F 312. When the initialization in the ASIC 309 is completed, the LCD 103 can display. Furthermore, if the operation control unit 105, the scanner unit 107, the plotter unit 108, and the facsimile unit 109 are installed, the Sub CPU 307 can communicate with the facsimile unit 109.

  In the process of S707, when the main CPU 302 completes the initialization of the execution control unit 106, the execution control unit 106 can communicate with the PC and the network. When there is an input from the network 111 or the USB 112, the execution control unit 106 performs processing. If the facsimile unit 109 is installed, the facsimile unit 109 can communicate with the execution control unit 106 via a PSTN (Public Switched Telephone Networks).

  The main CPU 302 transmits LED control information to the operation control unit 105 via the OPU I / F 314 and receives key state information from the operation control unit 105. Transmission / reception between the OPU I / F 314 and the operation control unit 105 is performed through the I2C I / F. Since the I2C I / F Master 3141 in the OPU I / F 314 is a master, communication is performed from the master side to the I2C I / F Slave 2071 of the interface unit 207 of the operation control unit 105.

  When the key state changes, the operation control unit 105 activates KEYREQ_N (Low) and notifies the OPU I / F 314 of the change. When the notification to the OPU I / F 314 is detected by the main CPU 302, the main CPU 320 receives a key status from the microcomputer 211 via the OPU I / F 314.

  When the main CPU 302 determines that the key is input and the ECO key 116 is pressed as the key, the main CPU 302 notifies the sub CPU 307 to shift the power consumption mode from the normal mode 603 to the energy saving mode 604. To do. If the main CPU 302 determines that a key 201 other than the ECO key 116 has been pressed, the execution control unit 106 executes processing according to the state of the pressed key 201.

  When there is no input from the PSTN, the network 111, and the USB 112 (S710: N, S711: N, S712: N), and there is no input from the key 201 (S713: N), in the processing of S714, the main CPU 302 performs a predetermined time. Judge whether or not it has passed. When the predetermined time has elapsed (S714: Y), the Main CPU 302 notifies the Sub CPU 307 to change the power consumption mode from the normal mode 603 to the energy saving mode 604 (S716).

  When the power consumption mode transitions to the energy saving mode 604, the Sub CPU 307 stops power supply to the scanner unit 107, the plotter unit 108, and the LCD 103 via the external power control unit 306. When the facsimile unit 109 is installed and the facsimile unit 109 detects the reception of the facsimile (S710: Y), the facsimile unit 109 notifies the sub CPU 307.

  When the operation control unit 105 detects that the ECO key 116 is pressed, the microcomputer 211 sets KEYREQ_N to active (Low) and notifies the sub CPU 307 of it. Even when the key 201 other than the ECO key 116 is pressed, the microcomputer 211 may make KEYREQ_N active (Low) and notify the sub CPU 307 of it.

  When the sub CPU 307 detects that there is a reception from the facsimile unit 109 (S717: Y) or KEYREQ_N becomes active (S718: Y), the sub CPU 307 changes the power consumption mode to the normal mode 603 (S705). . When the power consumption mode is the energy saving mode 604, if the facsimile option determination unit 110 determines that the facsimile unit 109 is not installed (S719: N), the process proceeds to S720. If the microcomputer 211 determines in the processing of S720 that the surroundings of the image processing apparatus have become dark, the microcomputer 211 makes LDET_N active (Low) and notifies the Sub CPU 307.

  When the Sub CPU 307 is in the energy saving mode 604 and detects that the LDET_N is active (Low) (S720: Y), the process proceeds to S703, and the Sub CPU 307 changes the power consumption mode to the low power consumption mode 602. Set.

  It is assumed that the power consumption mode is the power-supplied mode 605 that is one of the normal mode 603, the energy saving mode 604, or the low power consumption mode 602. If the Power SW 115 is pressed at this time, the Sub CPU 307 detects that the Power SW 115 is pressed. Then, the Sub CPU 307 performs control for stopping the supply of power to the external power control unit 306 and the board power control unit 305.

  Further, when the power plug is removed from the AC outlet, the power supply to the image processing apparatus 100 is stopped, so that the power consumption mode becomes the Power OFF mode 601.

  Next, illuminance detection of the image processing apparatus will be described with reference to FIG. FIG. 8 is a diagram illustrating (a) when brightened and (b) darkened as examples of illuminance detection in the image processing apparatus according to the embodiment of the present invention.

  8A and 8B, the horizontal axis represents time, and the vertical axis represents illuminance, which shows the relationship between the passage of time and illuminance. FIG. 8A is a graph showing how the illuminance around the image processing apparatus 100 becomes brighter as time elapses.

  If the threshold illuminance when the microcomputer 211 determines that the brightness has been increased is set to L2, the microcomputer 211 can determine that the illuminance has increased when the time t4 is reached. Time t4 is when the periphery of the image processing apparatus 100 becomes sufficiently bright.

  There are few users who use the image processing apparatus 100 when the sky is dim. Therefore, if the microcomputer 211 determines that the illuminance has become bright when the time t2 is reached, power is supplied to the image processing apparatus 100 in a time zone where there are few users of the image processing apparatus 100, and wasteful power is consumed. Will be consumed. When the time t4 is reached, the surroundings of the image processing apparatus 100 are sufficiently bright, so that power is not supplied to the dawn where there are few users, and the microcomputer 211 consumes unnecessary power. Can be suppressed.

  From time t7 to time t8, the illuminance exceeds the threshold illuminance L2 over a predetermined time T2, but in this time zone, the power consumption mode of the image processing apparatus 100 is the normal mode 603 or the energy saving mode 604, It is not the low power consumption mode 602. Therefore, the microcomputer 211 does not determine that the illuminance has become brighter.

  In this way, if the threshold illuminance for determining that the image has become bright is set to L2, the microcomputer 211 does not determine that the surroundings of the image processing apparatus 100 have become bright in a dimly lit way with few users, and wasteful power is consumed. Consumption can be suppressed. Further, since the microcomputer 211 does not frequently turn on / off the power of the image processing apparatus 100, the influence on the life of components in the image processing apparatus 100 can be reduced.

  Next, FIG. 8B will be described. FIG. 8B is a graph showing how the illuminance around the image processing apparatus 100 becomes darker as time elapses. Assume that the user turns on the illumination at time T11 when the illuminance around the image processing apparatus 100 becomes dark, and turns off the illumination at time t13.

  Due to an abnormality in illumination, the illumination is turned on again from time t14 to t15 after the illumination is turned off at time t13. However, since the illuminance is not smaller than the threshold illuminance L1 for the predetermined time T1 or more, the microcomputer 211 does not detect that the periphery of the image processing apparatus 100 has become dark at the time t14. When the illumination is turned off again at time t15 and the illuminance becomes smaller than the threshold illuminance L1 for T1 which is a predetermined time until time t17, the microcomputer 211 determines that the periphery of the image processing apparatus 100 has become dark.

  Next, a detection flow of the illuminance sensor in the image processing apparatus will be described with reference to FIG. FIG. 9 is a flowchart for explaining a detection flow of the illuminance sensor in the image processing apparatus according to the embodiment of the present invention.

  The illuminance detection is performed by the A / D conversion 206 performing A / D conversion on the output of the illuminance sensor 205 in the operation control unit 105 at regular intervals. Since the A / D conversion 206 consumes power when performing A / D conversion, the control unit 208 of the operation control unit 105 controls to perform A / D conversion at predetermined intervals.

  Before performing A / D conversion, the microcomputer 211 initializes and clears the time tL1 when the illuminance is smaller than the threshold illuminance L1 and the time tL2 when the illuminance is larger than the threshold illuminance L2 in the processes of S901 and S902. To do. Next, in the process of S903, the microcomputer 211 performs A / D conversion on the output of the illuminance sensor 205 by the A / D conversion 206 at regular intervals, and calculates the illuminance L.

  When SDMODE_N is active (Low), that is, when the power consumption mode is the low power consumption mode 602 (S904: Y), when the illuminance L is larger than the threshold illuminance L2 (S905: Y), the processing proceeds to S906. Transition. In the process of S906, the microcomputer 211 calculates the elapsed time of the time tL2 when the illuminance L is greater than the threshold illuminance L2 (S906).

  When the time tL2 is shorter than the predetermined time T2 (S907: N), the microcomputer 211 again performs A / D conversion on the output of the illuminance sensor 205 and calculates the illuminance L (S903). When tL2 is longer than the predetermined time T2 (S907: Y), the microcomputer 211 sets LDET_N to active (Low) for a predetermined time (S908), and notifies the sub CPU 307 that the surrounding has become bright. When the illuminance L is not greater than the threshold L2 (S905: N), the process proceeds to S902, and the microcomputer 211 clears the time tL2 and obtains the illuminance L again.

  When the SDMODE_N is inactive (High), that is, when the power consumption mode is the Power Applied mode 605 (S904: N), when the illuminance L is smaller than the threshold illuminance L1 (S910: Y), the process proceeds to S911. To do. In the process of S911, the microcomputer 211 calculates the elapsed time of the time tL1 when the illuminance L is smaller than the threshold illuminance L1 (S911).

  When the time tL1 is longer than the predetermined time T1 (S812: Y), the microcomputer 211 determines that the surrounding has become dark, sets LDET_N to active (Low) for a predetermined time (S908), and darkens the Sub CPU 307. Notify that. When the illuminance L is not smaller than the threshold illuminance L1 (S910: N), the process proceeds to S901, and the microcomputer 211 clears the time tL1 and obtains the illuminance L again. When tL1 is not larger than T1 (S912: N), the microcomputer 211 performs A / D conversion on the output of the illuminance sensor 205 again and calculates the illuminance L (S903).

  Each operation flow of the image processing apparatus 100 in the embodiment of the present invention shown in FIGS. 7 and 9 can be executed by a program on a computer. That is, the microcomputer 211, the Main CPU 302, and the Sub CPU 307 built in the image processing apparatus 100 load programs stored in the ROMs 209 and 303, the RAM 210, and the DDR 304. This is realized by sequentially executing the processing steps of the program.

  The present invention has been described above by the preferred embodiments of the present invention. While the invention has been described with reference to specific embodiments thereof, various modifications and changes can be made to these embodiments without departing from the broader spirit and scope of the invention as defined in the claims. is there.

100 image processing apparatus 101 power supply 102 PSU
103 LCD
104, 203 Operation panel 105 Operation control unit 106 Execution control unit 107 Scanner unit 108 Plotter unit 109 Facsimile unit 110 Facsimile option determination unit 111 Network 112, 316 USB
113, 114 FET
115 Power SW
116 ECO key 201 key 202 key input reception means 204 display means 205 illuminance sensor 206 A / D conversion 207 interface means 208 control means 209, 303 ROM
210 RAM
211 Microcomputer 301 Clock generator 302 Main CPU
304 DDR
305 Board power control unit 306 External power control unit 307 Sub CPU
308 PHY
309 ASIC
310 CPU I / F
311 ROM I / F
312 MEM I / F
313 PCI I / F
314 OPU I / F
315 LCD I / F
317 MAC
318 Internal BUS
401 Buffer 402 Pull Down resistance 601 Power OFF mode 602 Low power consumption mode 603 Normal mode 604 Energy saving mode 605 Power Applied mode 2071 I2C I / F Slave
3141 I2C I / F Master
2072, 3142 GIO

JP 2009-192716 A

Claims (8)

An image processing apparatus that can be equipped with a communication device as an option and has at least a normal mode for operating the communication device and a low power consumption mode for disabling the communication device as power consumption modes. ,
Detection means for detecting illuminance around the image processing apparatus;
Determining means for determining whether or not the communication device is installed as an option;
Control means for transitioning the power consumption mode to the low power consumption mode when the detection means detects that the ambient illuminance is smaller than a predetermined threshold for a predetermined time;
The determination means determines that the communication device is installed as an option when the detection means detects that the ambient illuminance is lower than a predetermined threshold for a predetermined time. However, the control means maintains the power consumption mode in the normal mode.   When the detection means detects that the ambient illuminance is less than a predetermined threshold for a predetermined time, and the determination means determines that the communication device is not installed as an option, the power consumption The image processing apparatus according to claim 1, wherein the mode is changed from the normal mode to the low power consumption mode.   When the detection means detects that the ambient illuminance is greater than a predetermined threshold for a predetermined time and determines that the communication device is not installed as an option, the power consumption mode is set to the low power mode. The image processing apparatus according to claim 1, wherein a transition is made from the power consumption mode to the normal mode.   As the power consumption mode, there is an energy saving mode in addition to the normal mode and the low power consumption mode. When the non-operating state continues for a predetermined time in the normal mode, the power consumption mode is changed from the normal mode to the energy saving mode. The image processing apparatus according to claim 1, wherein the mode is changed to a mode.   The image processing apparatus according to claim 4, wherein when any operation is performed in the energy saving mode, the power consumption mode is changed from the energy saving mode to the normal mode.   In the energy saving mode, when the detection means detects that the ambient illuminance is lower than a predetermined threshold for a predetermined time, and the determination means determines that the communication device is not installed as an option The image processing apparatus according to claim 4, wherein the power consumption mode is changed from the energy saving mode to the low power consumption mode. A control method for an image processing apparatus, which can be equipped with a communication device as an option, and has at least a normal mode for operating the communication device and a low power consumption mode for disabling the communication device as power consumption modes Because
Detecting means for detecting illuminance around the image processing apparatus;
A step of determining whether or not the communication device is installed as an option;
When the detecting step detects that the ambient illuminance is smaller than a predetermined threshold for a predetermined time, the control means transitions the power consumption mode to the low power consumption mode; and
When it is determined by the determining step that the communication device is installed as an option, the detection step detects that the ambient illuminance is lower than a predetermined threshold for a predetermined time. Even so, the control means maintains the power consumption mode in the normal mode;
The control method characterized by including. A computer of an image processing apparatus that can be equipped with a communication device as an option and has at least a normal mode for operating the communication device and a low power consumption mode for disabling the communication device as power consumption modes. ,
Processing for detecting illuminance around the image processing device;
A process of determining whether or not the communication device is installed as an option;
When the detection process detects that the ambient illuminance is lower than a predetermined threshold for a predetermined time, a process of transitioning the power consumption mode to the low power consumption mode;
When it is determined by the determination process that the communication device is installed as an option, the detection process detects that the ambient illuminance is smaller than a predetermined threshold for a predetermined time. Even so, the process of maintaining the power consumption mode in the normal mode,
A program to realize

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