JP5759774B2 - Electronic apparatus and image forming apparatus - Google Patents

Description

  The present invention relates to an electronic apparatus and an image forming apparatus.

  There is an image processing apparatus that shifts to a power saving mode and reduces power consumption when the non-operation time exceeds a certain time (see, for example, Patent Document 1).

JP 2009-178855 A

  By the way, for example, when the electronic device performs a power-on operation in response to the restart of the power supply from the external power supply after the power supply from the external power supply to the electronic device is stopped, it is convenient for the user. Is expensive. However, when the electronic device always performs a power-on operation (or starts up) in response to resumption of power supply, useless power consumption may occur.

  SUMMARY An advantage of some aspects of the invention is that it provides an electronic apparatus and an image forming apparatus capable of suppressing wasteful power consumption while improving convenience.

An electronic apparatus according to the present invention includes a process execution unit that executes predetermined processing using electric power, and a power supply unit that supplies power supplied from an external power source to the process execution unit. When the power supply from the external power source is resumed, when the power supply to the power supply unit was stopped last time, the power supply to the process execution unit was performed. A power supply unit that starts supply and does not start power supply to the process execution unit when power supply to the process execution unit is not performed when power supply to the power supply unit was stopped last time; , have a, the power supply means, said first state indicating that the power supply is the power supply to the processing execution means upon stop was done to the power supply means or said power supply means, What State holding means for holding a second state indicating that power supply to the process execution means has not been performed when power supply is stopped; and power supplied from the external power source to the process execution means When the power supply to the power supply means is started, when the state holding means is in the first state, the power supply to the processing execution means is started. And when the state holding means is in the second state, the power supply means includes a switch means that does not start power supply to the processing execution means, and the power supply means is supplied with power. And when power is not supplied to the process execution means, the power supply to the process execution means is started in response to an input from the outside, and the process execution means is supplied from the power supply means. When the power supply to the process execution unit is started, the power supply to the process execution unit is started in response to the input from the outside, or the power supply to the power supply unit is restarted. It is determined whether power supply to the process execution unit is started. When it is determined that power supply to the process execution unit is started according to the input from the outside, the first operation mode is started, and the power When it is determined that the supply of power to the processing execution unit is started in response to the restart of the supply of power to the supply unit, a second operation mode different from the first operation mode is started .

The image forming apparatus according to the present invention includes: a process execution unit that executes an image forming process using power; and a power supply unit that supplies power supplied from an external power source to the process execution unit. When the supply of power from the external power source to the supply means is resumed, when the power supply to the power supply means was stopped when the power supply to the process execution means was performed last time, the process execution means Power that does not start power supply to the process execution means when power supply to the process execution means has not been performed when power supply to the power supply means was stopped last time. possess a supply means, said power supply means, said first state indicating that the power supply is the power supply to the processing execution means upon stop was done to the power supply means or said, Electric State holding means for holding a second state indicating that power supply to the processing execution means has not been performed when power supply to the supply means is stopped; and power supplied from the external power source Switch means for supplying or shutting off to the process execution means, and when the power supply to the power supply means is started, when the state holding means is in the first state, the switch to the process execution means Switching means for starting power supply and not starting power supply to the processing execution means when the state holding means is in the second state, and the power supply means supplies power to the power supply means. Is supplied and power is not supplied to the process execution means, the power supply to the process execution means is started in response to an input from the outside, and the process execution means When power supply from the supply unit to the process execution unit is started, power supply to the process execution unit is started in response to the input from the outside, or power supply to the power supply unit is resumed. Accordingly, it is determined whether power supply to the process execution unit is started. When it is determined that power supply to the process execution unit is started according to the input from the outside, the first operation mode is started. When it is determined that the supply of power to the processing execution unit is started in response to the resumption of the supply of power to the power supply unit, the second operation mode different from the first operation mode is started. To do.

  According to the present invention, it is possible to provide an electronic apparatus and an image forming apparatus that can suppress wasteful power consumption while improving convenience.

3 is a block diagram illustrating an example of a configuration of a printing apparatus as an electronic apparatus according to Embodiment 1. FIG. 3 is a flowchart illustrating an example of an operation of a process execution unit according to the first embodiment. FIG. 3 is a circuit diagram illustrating an example of a specific configuration of a power supply unit in the first embodiment. 3 is a flowchart illustrating an example of a specific operation of a control unit in the first embodiment. 10 is a block diagram illustrating an example of a configuration of a printing apparatus as an electronic apparatus according to Embodiment 2. FIG. 10 is a flowchart illustrating an example of an operation at the time of printing by a control unit according to the second embodiment. 10 is a flowchart illustrating an example of an operation after the start of power supply by a control unit according to the second embodiment. FIG. 10 is a block diagram illustrating an example of a configuration of a printing apparatus as an electronic apparatus in a third embodiment. 10 is a circuit diagram illustrating an example of a specific configuration of a power supply unit according to Embodiment 3. FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is a block diagram illustrating an example of a configuration of a printing apparatus 1 as an electronic apparatus according to the first embodiment. The printing apparatus 1 is an apparatus that prints an image on a printing medium such as paper. For example, the printing apparatus 1 is an apparatus having at least one of a printer function, a copy function, and a facsimile function. In the example of FIG. 1, the printing apparatus 1 is a printer that is communicably connected to an upper apparatus (for example, a host computer or a personal computer) 2 and performs printing in response to a print request from the upper apparatus 2. The printing apparatus 1 includes a processing execution unit 10 and a power supply unit 20.

  The process execution unit 10 executes a predetermined process using the power supplied from the power supply unit 20. The predetermined process is specifically an original process of the electronic device, and in this example, is a process of forming an image (specifically, a printing process). The process execution part 10 can be called the main body of an electronic device, for example.

  The power supply unit 20 supplies power supplied from the external power supply 3 to the process execution unit 10. The external power supply 3 is a commercial power supply, for example. The power supply unit 20 can also be called a power-on unit that turns on the processing execution unit 10.

  In the example of FIG. 1, the printing apparatus 1 includes a power supply unit 30, and power from the external power supply 3 is supplied to the power supply unit 20 via the power supply unit 30. Specifically, the power supply unit 30 is a circuit that converts a voltage (for example, an AC voltage) from the external power supply 3 into a voltage (for example, a DC voltage) corresponding to the power supply unit 20 and supplies the voltage to the power supply unit 20.

  The printing apparatus 1 has an “ON mode” that is a mode in which power is supplied from the power supply unit 20 to the processing execution unit 10 as a mode when power from the external power supply 3 is supplied to the power supply unit 20. “OFF mode” is a mode in which power is not supplied from the power supply unit 20 to the processing execution unit 10. In FIG. 1, in the ON mode, power is supplied to the processing execution unit 10, the power supply unit 20, and the power supply unit 30, and in the OFF mode, power is supplied to the power supply unit 20 and the power supply unit 30. The OFF mode is a mode in which, for example, power is supplied only to a portion that monitors the operation of a power switch (ON operation accepting unit 23 in FIG. 1). In the OFF mode, the power consumption of the printing apparatus 1 is 0.5 W or less, for example.

  The power supply unit 20 performs an operation (power-on operation) for shifting the mode of the printing apparatus 1 to the ON mode. Specifically, when power supply from the external power supply 3 to the power supply unit 20 is resumed, the power supply unit 20 returns to the process execution unit 10 when power supply to the power supply unit 20 was previously stopped. Power supply to the process execution unit 10 was started, and when the power supply to the power supply unit 20 was stopped last time, the power supply to the process execution unit 10 was not performed. Sometimes, power supply to the process execution unit 10 is not started. That is, when the power supply to the power supply unit 20 is resumed, the power supply unit 20 starts the power supply to the process execution unit 10 when the power supply is in the ON mode when the power supply was stopped last time. When the power supply to the supply unit 20 is in the OFF mode when it was stopped last time, the power supply to the processing execution unit 10 is not started. Therefore, when the power supply to the power supply unit 20 is stopped during the ON mode, the power supply unit 20 is turned on when the power supply is resumed, and the power supply to the power supply unit 20 is stopped during the OFF mode. When the power supply is resumed after that, the OFF mode is set. For example, when the power supply to the power supply unit 20 is stopped, there is a case where the external power supply 3 fails, or the power cable C1 of the printing apparatus 1 is disconnected from the outlet of the external power supply 3. For example, when the external power supply 3 is restored from a power failure, or the power cable C1 of the printing apparatus 1 is plugged into an external power supply 3 outlet.

  As shown in FIG. 1, specifically, the power supply unit 20 includes a state holding unit 21 and a switch unit 22.

  When the power supply to the power supply unit 20 is stopped, the state holding unit 21 is in the first state indicating that the power supply to the processing execution unit 10 has been performed, or the power supply to the power supply unit 20 is performed. When the operation is stopped, the second state indicating that the power supply to the processing execution unit 10 has not been performed is held. In FIG. 1, the state holding unit 21 is an electronic circuit including a power holding unit 21 a that holds power and a self-holding circuit 21 b that holds the first or second state using the power holding unit 21 a as a power source. . Specifically, the power holding unit 21a is a battery, a capacitor, or the like. For example, a capacitor can be kept for several minutes to several days, and a battery can be kept for a longer period.

  The state of the state holding unit 21 is set by the processing execution unit 10, for example. In this case, for example, when the power supply from the power supply unit 20 is stopped (that is, when shifting to the OFF mode), the process execution unit 10 sets the state holding unit 21 to the second state and supplies power. When the power supply from the unit 20 is started (that is, when shifting to the ON mode), the state holding unit 21 is set to the first state. However, the state holding unit 21 may be configured such that the state is set based on a signal from the switch unit 22, an operation from the user, or the like.

  The switch unit 22 supplies or blocks the power supplied from the external power supply 3 to the processing execution unit 10, and when the power supply to the power supply unit 20 is started, the state holding unit 21 is the first one. When the state holding unit 21 is in the second state, the power supply to the process execution unit 10 is not started. The switch unit 22 is, for example, an electronic circuit including a switch element 22a that electrically connects or disconnects between the external power supply 3 and the processing execution unit 10 according to the state of the self-holding circuit 21b. When the power supply from the external power source 3 is started and the state holding unit 21 is in the first state, the switch element 22a connects the external power source 3 and the processing execution unit 10 and the state holding unit 21 Is in the second state, the external power source 3 and the processing execution unit 10 are disconnected. In one aspect, the switch unit 22 includes a self-holding circuit 22b that self-holds the power supply state when power supply to the processing execution unit 10 is started. For example, the self-holding circuit 22b includes a switch element 22a and is a circuit that self-holds the ON state of the switch element 22a. When the power supply from the external power supply 3 is stopped or when a reset signal (for example, a power supply OFF signal) is supplied, the self-holding state of the self-holding circuit 22b is released and the switch element 22a is turned off.

  In one aspect, the power supply unit 20 is supplied to the power supply unit 20, and when the power is not supplied to the process execution unit 10, the power supply unit 20 is supplied to the process execution unit 10 according to an input from the outside. Start supplying power. That is, in the OFF mode, the power supply unit 20 performs an operation (power-on operation) for shifting the mode of the printing apparatus 1 to the ON mode in response to an input from the outside. In the present embodiment, the power supply unit 20 includes an ON operation accepting unit 23 that accepts a power ON operation from the user as an input from the outside, and the power ON operation is accepted by the ON operation accepting unit 23. Then, power supply to the process execution unit 10 is started. For example, the power supply unit 20 is configured such that the switch element 22a is turned on in response to a power ON operation on the ON operation receiving unit 23. The ON operation receiving unit 23 is, for example, a push button type power switch that receives a pressing operation from the user.

  In addition, when power is supplied to the process execution unit 10, the power supply unit 20 stops power supply to the process execution unit 10 in response to an input from the outside. That is, in the ON mode, the power supply unit 20 performs an operation (power cutoff operation) for shifting the mode of the printing apparatus 1 to the OFF mode in response to an input from the outside. For example, the power supply unit 20 includes an OFF operation reception unit 24 that receives a power OFF operation from the user as an input from the outside. When the power OFF operation is received by the OFF operation reception unit 24, the processing execution unit The power supply to 10 is stopped. For example, the process execution unit 10 is configured to output a power OFF signal to the power supply unit 20 after performing a predetermined end process when detecting a power OFF operation on the OFF operation reception unit 24. Is configured such that the switch element 22a is turned off in response to the power OFF signal from the processing execution unit 10. The OFF operation reception unit 24 is, for example, a push button type power switch that receives a pressing operation from a user. The ON operation reception unit 23 and the OFF operation reception unit 24 may be realized by the same switch.

  In one aspect, the power supply unit 20 is a part that substantially performs only the power-on operation or only the power-on operation and the power-off operation. For example, the power supply unit 20 operates to turn on the processing execution unit 10 in response to resumption of power supply, operates to turn on the processing execution unit 10 in response to input from the outside, and responds to input from the outside Then, only the operation of shutting off the power to the processing execution unit 10 is performed.

  The process execution unit 10 is activated when power supply from the power supply unit 20 is started. In one aspect, the process execution unit 10 performs processing when the power supply to the process execution unit 10 is started according to an input from the outside and when the power supply to the power supply unit 20 is resumed. When the power supply to is started, different operation modes are started. Specifically, the processing execution unit 10 has “normal mode” and “power saving mode” with lower power consumption (suppressing power consumption) than the normal mode as operation modes. When the power supply is started according to the input, the normal mode is started. When the power supply is started according to the restart of the power supply to the power supply unit 20, the power supply mode is started. In the power saving mode, for example, power supply to a predetermined load (for example, a fixing heater) energized in the normal mode is stopped or reduced. In this aspect, the process execution unit 10, for example, based on the state of the state holding unit 21, starts power supply in response to an input from the outside, or responds to restart of power supply to the power supply unit 20. It is determined whether power supply is started. Specifically, when the state holding unit 21 is in the first state, the process execution unit 10 determines that power supply has started in response to resumption of power supply to the power supply unit 20 and enters the power saving mode. When the state holding unit 21 is in the second state, it is determined that the power supply has been started in response to an input from the outside, and the normal mode is started. In this case, the process execution unit 10 sets the state of the state holding unit 21 so that the above determination can be made based on the state of the state holding unit 21. For example, when the process execution unit 10 sets the state holding unit 21 to the first state when the power supply from the power supply unit 20 is started, the process execution unit 10 is based on the state of the state holding unit 21 after the start of power supply. After the operation mode is determined, the state holding unit 21 is set to the first state.

  FIG. 2 is a flowchart illustrating an example of the operation of the process execution unit 10 according to the first embodiment. Hereinafter, the operation of the printing apparatus 1 will be described with reference to FIG.

  When the power supply from the external power supply 3 to the printing apparatus 1 is stopped during the ON mode, and then the power supply to the printing apparatus 1 is resumed, the state holding unit 21 holds the first state. The switch unit 22 is turned on, and the supply of power to the process execution unit 10 is started.

  On the other hand, when the power supply from the external power supply 3 to the printing apparatus 1 is stopped during the OFF mode, and then the power supply to the printing apparatus 1 is resumed, the state holding unit 21 holds the second state. For this reason, the switch unit 22 maintains the OFF state, and the supply of power to the processing execution unit 10 is not started. Thereafter, when a power ON operation is performed during the OFF mode, the switch unit 22 is turned on, and power supply to the processing execution unit 10 is started.

  When power supply to the process execution unit 10 is started as described above, the process execution unit 10 starts the process of FIG.

  In FIG. 2, the process execution unit 10 determines whether the state holding unit 21 is in the first state or the second state (S1), and if it is determined that the state holding unit 21 is in the second state ( (S1: second state), the state holding unit 21 is set to the first state (S2), and the normal mode is activated (S3). In the normal mode, the process execution unit 10 executes print processing in response to a print request from the higher-level device 2. The process execution unit 10 maintains the normal mode until the power OFF operation is detected (S4: NO), and when the power OFF operation is detected (S4: YES), the process proceeds to step S8.

  On the other hand, if it is determined in step S1 that it is in the first state (S1: first state), the process execution unit 10 is activated in the power saving mode (S5). In the power saving mode, the process execution unit 10 maintains the power saving mode until it receives a print request from the host apparatus 2 or detects a power-off operation (S6: NO, S7: NO), and receives the print request. In such a case (S6: YES), the process shifts to the normal mode to execute the printing process (S3), and when the power OFF operation is detected (S7: YES), the process proceeds to step S8.

  In step S8, the process execution unit 10 sets the state holding unit 21 to the second state. Next, the process execution unit 10 outputs a power OFF signal to the switch unit 22 (S9). The switch unit 22 is turned off by the power OFF signal, and the power supply to the processing execution unit 10 is stopped.

Hereinafter, a more specific example of the configuration and operation of the printing apparatus 1 will be described.
In the example of FIG. 1, the processing execution unit 10 includes a ROM (Read Only Memory) 11, a RAM (Random Access Memory) 12, a memory controller 13, a communication interface 14, an EEPROM (Electrically Erasable Programmable Read Only Memory) 15, and an expansion circuit 16. , Timer unit 17, printing unit 18, and control unit 19.

  The ROM 11 is a read-only nonvolatile memory, and stores a program to be executed by the control unit 19. The RAM 12 is a readable / writable volatile memory, and temporarily stores data such as image data from the host device 2 and compressed raster data. The memory controller 13 is a circuit that controls access to the ROM 11 and the RAM 12. The communication interface 14 is an interface for communicating with the host device 2 and is, for example, a USB interface. The EEPROM 15 is a rewritable nonvolatile memory, and stores data such as a power saving mode transition time and an OFF mode transition time. The decompression circuit 16 is a circuit that decompresses the compressed raster data and outputs the original raster data. The timer unit 17 is a circuit that measures time, and is, for example, a real time clock (RTC). The printing unit 18 is an apparatus that prints an image on a sheet based on raster data. In this case, the printing unit 18 performs printing using an electrophotographic method. However, the printing unit may use a printing method other than the electrophotographic method such as an inkjet method. The control unit 19 controls the operation of the printing apparatus 1 and is, for example, a CPU (Central Processing Unit). Specifically, the control unit 19 is connected to the above-described units via the bus B or the like, and performs various processes such as a printing process by reading a program stored in the ROM into the RAM and executing it.

  Here, the printing process will be described. The host device 2 creates image data based on a user operation, converts the image data into print data in a printer language using a predetermined printer driver, and transmits the print data to the printing device 1. The control unit 19 receives print data from the higher-level device 2 via the communication interface 14 and stores it in the RAM 12. Based on the emulation program stored in the ROM 11, the control unit 19 expands the print data stored in the RAM 12 into raster data, compresses the raster data, and stores the raster data in the RAM 12. Then, the control unit 19 sends a decompression start instruction to the decompression circuit 16 and sends a print start instruction to the printing unit 18. In response to this, the decompression circuit 16 decompresses the compressed raster data stored in the RAM 12 and sends the raster data to the printing unit 18, and the printing unit 18 creates an image based on the raster data from the decompression circuit 16. Form and print on paper.

  In addition to the printing process described above, the control unit 19 performs the following process for controlling the mode of the printing apparatus 1.

  When the power supply to the processing execution unit 10 is started, the control unit 19 receives a Mode signal indicating the state of the state holding unit 21 via the Mode signal line L1, and based on the Mode signal, the normal mode And which operation mode of the power saving mode is to be activated.

  In addition, when power supply to the processing execution unit 10 is started, the control unit 19 sets the state holding unit 21 to the first state holding unit 21 via the Go_ps signal line L2 after determining the operation mode. The Go_ps signal for setting to the state is output. This Go_ps signal is a signal having a meaning of shifting to the power saving mode when the power supply from the external power source 3 to the printing apparatus 1 is resumed.

  The control unit 19 changes the mode of the printing apparatus 1 from the normal mode to the power saving mode when the standby time in the normal mode reaches a preset power saving mode transition time based on the time counted by the time measuring unit 17. To move to. Here, the standby time in the normal mode is, for example, the elapsed time from the transition to the normal mode when the printing process is not performed after the transition to the normal mode, and when the printing process is performed after the transition to the normal mode. Is the elapsed time from the end of the last print process.

  Further, based on the time measured by the time measuring unit 17, the control unit 19 is configured so that the standby time in the power saving mode (that is, the elapsed time from the power saving mode transition time) reaches the preset OFF mode transition time, The mode of the printing apparatus 1 is shifted from the power saving mode to the OFF mode. When the standby time in the normal mode reaches the OFF mode shift time, the control unit 19 may shift the mode of the printing apparatus 1 from the normal mode to the OFF mode.

  For example, the initial value of the power saving mode transition time and the initial value of the OFF mode transition time are set when the printing apparatus 1 is shipped from the factory. The power saving mode transition time and the OFF mode transition time are changed from an operation panel (not shown). The setting range of the power saving mode transition time is, for example, approximately 1 minute to 120 minutes, and the setting range of the OFF mode transition time is, for example, 1 hour to 12 hours.

  Further, when the control unit 19 detects that the OFF operation receiving unit 24 is operated, the control unit 19 sets the state holding unit 21 to the second state via the Go_off signal line L3 with respect to the state holding unit 21. A Go_off signal is output, and a power OFF signal for stopping power supply to the processing execution unit 10 is output to the switch unit 22 via the Power_off signal line L4. The Go_off signal has a meaning that it stays in the OFF mode when power supply from the external power supply 3 to the printing apparatus 1 is resumed.

  FIG. 3 is a circuit diagram illustrating an example of a specific configuration of the power supply unit 20 according to the first embodiment. Hereinafter, an example of a specific configuration of the state holding unit 21 and the switch unit 22 will be described with reference to FIG.

  The state holding unit 21 includes a self-holding circuit 21 b including a p-channel FET (field effect transistor) 50 and an n-channel FET 51. The gate of the FET 50 is connected to the drain of the FET 51 through the resistor 52. A resistor 53 is connected between the gate and the source of the FET 50. The source of the FET 50 is connected to a power supply line (specifically, a 5V voltage line) VDD from the power supply unit 30 via a diode 54. The diode 54 is inserted so that the cathode is connected to the FET 50. The source of the FET 50 is connected to the positive electrode of the battery 57 serving as the power holding unit 21 a via the diode 55 and the resistor 56. The diode 55 is inserted so that the cathode is connected to the FET 50. The negative electrode of the battery 57 is connected to the ground. The source of the FET 50 is connected to the gate of the FET 51 through the resistor 58. The gate of the FET 51 is connected via a diode 59 to a Go_ps signal line L 2 that connects the state holding unit 21 and the control unit 19. The diode 59 is inserted so that the cathode is connected to the FET 51. The gate of the FET 51 is connected to the drain of the n-channel FET 60. The gate of the FET 60 is connected to a Go_off signal line L3 that connects the state holding unit 21 and the control unit 19 via a diode 61. The diode 61 is inserted so that the cathode is connected to the FET 60. A resistor 62 is connected between the gate and the source of the FET 60, and the source of the FET 60 is connected to the ground. A resistor 63 is connected between the gate and source of the FET 51. The source of the FET 51 is connected to the ground. The drain of the FET 50 is connected to the gate of the n-channel FET 64. A resistor 65 is connected between the gate and the source of the FET 64, and the source of the FET 64 is connected to the ground. The drain of the FET 64 is connected to the Mode signal line L 1 that connects the state holding unit 21 and the control unit 19. The drain of the FET 64 is connected to the gate of the p-channel FET 67 via the resistor 66. A resistor 68 is connected between the gate and the source of the FET 67, and the source of the FET 67 is connected to the power supply line VDD. The drain of the FET 67 is connected to a Ps signal line L 5 that connects the state holding unit 21 and the switch unit 22.

  The switch unit 22 includes a self-holding circuit 22b including a p-channel FET 70 (corresponding to the switch element 22a in FIG. 1) and an n-channel FET 71. The gate of the FET 70 is connected to the drain of the FET 71 through the resistor 72. A resistor 73 is connected between the gate and source of the FET 70, and the source of the FET 70 is connected to the power supply line VDD from the power supply unit 30. The drain of the FET 70 is connected to the gate of the FET 71 through the resistor 74. The gate of the FET 71 is connected to the Ps signal line L5 through the resistor 75. The gate of the FET 71 is connected to the drain of the n-channel FET 76. The gate of the FET 76 is connected to a Power_off signal line L 4 that connects the switch unit 22 and the control unit 19 through a diode 77. The diode 77 is inserted so that the cathode is connected to the FET 76. A resistor 78 is connected between the gate and the source of the FET 76, and the source of the FET 76 is connected to the ground. A resistor 79 is connected between the gate and the source of the FET 71, and the source of the FET 71 is connected to the ground. The drain of the FET 70 is connected to a power supply line VDD_P that connects the switch unit 22 and the processing execution unit 10. Further, the gate of the FET 71 is connected to the contact 81 through the resistor 80. The switch unit 22 includes an operation switch 82. While the operation switch 82 is pressed, the contact 81 and the contact 83 connected to the power supply line VDD are in a conductive state, and the power supply line VDD and the gate of the FET 71 are connected. And are configured to be connected. The operation switch 82 is a power ON / OFF switch that functions as the ON operation reception unit 23 and the OFF operation reception unit 24 in FIG. 1, and is disposed on, for example, an operation panel of the printing apparatus 1 (not shown). Although not shown in FIG. 3, when the operation switch 82 is pressed, a signal indicating the operation is supplied to the control unit 19. For example, a contact point connected to the signal line to the control unit 19 and a contact point connected to the power supply line VDD are provided, and both the contacts become conductive while the operation switch 82 is pressed, and the power supply line VDD is connected. A voltage is applied to the signal line.

Next, the operation of the state holding unit 21 shown in FIG. 3 will be described.
When the FETs 50 and 51 are in the OFF state, when the Go_ps signal line L2 changes from the low level to the high level (specifically, 5 V), the FET 51 is turned on, the drain voltage of the FET 51 decreases, and the gate voltage of the FET 50 decreases. . As a result, the FET 50 is turned on, the voltage of the power supply line VDD is applied again to the gate of the FET 51 via the FET 50 and the resistor 58, and the self-holding circuit 21b is brought into a self-holding state. That is, the Go_ps signal is a set signal for the self-holding circuit 21b, and the self-holding circuit 21b is set to a set state (self-holding state) when the high-level Go_ps signal is supplied. The Go_ps signal is normally at a low level, and is set to a high level for a predetermined time by the control unit 19 when the self-holding circuit 21b is set. Note that after the supply of voltage from the power supply unit 30 is stopped, the self-holding state of the self-holding circuit 21b is maintained by the voltage of the battery 57.

  When the self-holding circuit 21b is in the set state, that is, when the FETs 50 and 51 are in the ON state, if the Go_off signal line L3 changes from the low level to the high level (specifically 5V), the FET 60 is turned on, and the FET 51 , And the FET 51 is turned off. As a result, the drain voltage of the FET 51 is increased, the gate voltage of the FET 50 is increased, the FET 50 is turned off, and the self-holding state of the self-holding circuit 21b is released. That is, the Go_off signal is a reset signal for the self-holding circuit 21b, and the self-holding circuit 21b is reset by the supply of the high-level Go_off signal. The Go_off signal is normally at a low level, and is set to a high level for a predetermined time by the control unit 19 when the self-holding circuit 21b is reset.

  When the self-holding circuit 21b is in the set state, the voltage of the power supply line VDD is applied to the gate of the FET 64 via the FET 50, the FET 64 is turned on, the Mode signal line L1 is connected to the ground via the FET 64, and the Mode signal Becomes low level. Further, the gate voltage of the FET 67 decreases, the FET 67 is turned on, the voltage of the power supply line VDD is applied to the Ps signal line L5 via the FET 67, and the Ps signal becomes high level.

  On the other hand, when the self-holding circuit 21b is in the reset state, the FET 64 is turned off, the voltage of the power supply line VDD is applied to the Mode signal line L1 through the resistors 68 and 66, and the Mode signal becomes high level. Further, the FET 67 is turned off, the Ps signal line L5 is connected to the ground via the resistors 75 and 79, and the Ps signal becomes low level.

  Thus, the Mode signal and the Ps signal are signals indicating the state of the self-holding circuit 21b. The Mode signal is a signal for transmitting the state of the self-holding circuit 21b to the control unit 19, and when it is at a high level (logic value 1), it indicates that the self-holding circuit 21b is in a reset state, and a low level (logic The value 0) indicates that the self-holding circuit 21b is in the set state. On the other hand, the Ps signal is a signal for transmitting the state of the self-holding circuit 21b to the switch unit 22, and when it is at a high level (logic value 1), it indicates that the self-holding circuit 21b is in a set state and is at a low level. (Logical value 0) indicates that the self-holding circuit 21b is in a reset state. That is, the Ps signal and the Mode signal are opposite in polarity.

Next, the operation of the switch unit 22 shown in FIG. 3 will be described.
When there is no power supply from the power supply unit 30, the FETs 70 and 71 are in the OFF state, the self-holding circuit 22b is in the reset state, and the voltage of the power supply line VDD_P is 0V.

  When the power supply from the power supply unit 30 starts when the self-holding circuit 21b of the state holding unit 21 is in the set state, the voltage of the power supply line VDD (specifically 5V) is applied to the Ps signal line L5 via the FET 67. When applied, the Ps signal becomes high level, and the gate of the FET 71 becomes high level. As a result, the FET 71 is turned on, the gate voltage of the FET 70 is lowered, and the FET 70 is turned on. As a result, the power supply line VDD is connected to the power supply line VDD_P via the FET 70, and power supply to the processing execution unit 10 is started. In addition, the voltage of the power supply line VDD is applied again to the gate of the FET 71 via the FET 70 and the resistor 74, and the self-holding circuit 22b enters the self-holding state (set state), and the power supply state to the processing execution unit 10 is maintained. .

  When the power supply from the power supply unit 30 is started when the self-holding circuit 21b of the state holding unit 21 is in the reset state, the FET 71 and the FET 70 remain OFF because the Ps signal is at a low level. The self-holding circuit 22b maintains the reset state. Thereafter, when the operation switch 82 is pressed, the voltage of the power supply line VDD is applied to the gate of the FET 71 via the resistor 80, and the FET 71 is turned on. As a result, the gate voltage of the FET 70 is lowered and the FET 70 is turned on. As a result, the power supply line VDD is connected to the power supply line VDD_P via the FET 70, and power supply to the processing execution unit 10 is started. In addition, the voltage of the power supply line VDD is applied again to the gate of the FET 71 via the FET 70 and the resistor 74, and the self-holding circuit 22b enters the self-holding state (set state), and the power supply state to the processing execution unit 10 is maintained. .

  When the power-off signal of the Power_off signal line L4 changes from low level to high level (specifically 5V) when the self-holding circuit 22b of the switch unit 22 is in the set state, the FET 76 is turned on, and the gate voltage of the FET 71 Falls, and the FET 71 is turned off. As a result, the gate voltage of the FET 70 increases, the FET 70 is turned off, the power supply line VDD_P becomes 0 V, and the power supply to the processing execution unit 10 is stopped. Further, the self-holding state of the self-holding circuit 22b is released. That is, the power OFF signal is a reset signal for the self-holding circuit 22b, and the self-holding circuit 22b is reset by the supply of the high-level power OFF signal. The power OFF signal is normally at a low level, and is set to a high level for a predetermined time by the control unit 19 when the self-holding circuit 22b is reset.

  FIG. 4 is a flowchart showing an example of a specific operation of the control unit 19 in the first embodiment. Hereinafter, an example of the operation of the control unit 19 will be described with reference to FIG.

  When the control unit 19 detects that the power supply from the switch unit 22 is started, the control unit 19 starts the operation of FIG. Specifically, when the control unit 19 starts supplying power to the processing execution unit 10 and detects that a reset signal of a reset circuit (not shown) has changed to inactive, the control unit 19 starts the operation of FIG.

  The control unit 19 reads a program from the ROM 11, initializes the RAM 12 (S101), and initializes the communication interface 14 (S102). Specifically, the control unit 19 performs register setting for the control IC of the USB device.

  Next, the control unit 19 checks the Mode signal (S103). If the Mode signal is at a high level (logical value 1) (S103: “1”), the process proceeds to Step S104, and the Mode signal Is at the low level (logical value 0) (S103: "0"), the process proceeds to step S108. Here, the high level of the Mode signal indicates that the power supply to the previous process execution unit 10 has been normally completed (specifically, the power supply to the process execution unit 10 was interrupted by the previous power OFF operation). The low level of the Mode signal indicates that the power supply to the previous process execution unit 10 ended abnormally (specifically, the power supply to the process execution unit 10 was interrupted due to a power failure or the like during the previous ON mode) ).

  In step S104, the control unit 19 sets the Go_ps signal to a high level for a predetermined time in order to set the self-holding circuit 21b of the state holding unit 21.

  Next, the control unit 19 initializes the printing unit 18 (S105). Specifically, based on an instruction from the control unit 19, the printing unit 18 starts energization and control of a heater (for example, a heater of a fixing device), and performs an initial operation of the motor.

  Then, the control unit 19 sets the operation mode of the printing apparatus 1 to the normal mode (S106). In this normal mode, the printing unit 18 performs heater control, maintains a printable state, and executes print processing in response to a print request.

  Next, the control unit 19 makes a determination regarding the mode change (S107). Specifically, when it is determined that the standby time in the normal mode has reached a predetermined power saving mode transition time (S107: power saving transition), the control unit 19 shifts the processing to step S108. When it is determined that the operation switch 82 has been pressed or the standby time in the normal mode has reached a predetermined OFF mode transition time (S107: POWER OFF), the control unit 19 shifts the processing to step S110. . When the control unit 19 determines that an event for changing the mode has not occurred (S107: NO), the control unit 19 returns the process to step S106.

  In step S108, the control unit 19 sets the operation mode of the printing apparatus 1 to the power saving mode. This power saving mode is different from the normal mode in that the heater is not energized and controlled, and the clock is not supplied to the unused circuit. In the power saving mode, the printing apparatus 1 enters a power saving state as compared to the normal mode.

  Next, in step 109, the control unit 19 makes a determination regarding the mode change. Specifically, when the control unit 19 determines that print data has been received from the communication interface 14 (S109: printing), the control unit 19 shifts the processing to step S105. If the control unit 19 determines that the operation switch 82 has been pressed or the standby time in the power saving mode has reached a predetermined OFF mode transition time (S109: POWER OFF), the process proceeds to step S110. Let When the control unit 19 determines that an event for changing the mode has not occurred (S109: NO), the control unit 19 returns the process to step S108.

  In step S110, the control unit 19 sets the Go_off signal to a high level for a predetermined time in order to reset the self-holding circuit 21b of the state holding unit 21.

  Next, in step S111, the control unit 19 resets the self-holding circuit 22b of the switch unit 22 and sets the power OFF signal to a high level for a predetermined time to stop the power supply to the processing execution unit 10, and performs processing. Terminate.

  As described above, when the state holding unit 21, the switch unit 22, and the control unit 19 operate, the operation of the printing apparatus 1 when the power supply is resumed is as follows.

  When the power supply from the external power supply 3 to the printing apparatus 1 is stopped during the OFF mode and then the power supply from the external power supply 3 is resumed, the self-holding circuit 21b of the state holding unit 21 is in the reset state, and Ps The signal is at a low level, the FET 70 remains in an OFF state, and power supply to the processing execution unit 10 is not started. That is, the printing apparatus 1 remains in the OFF mode. Thereafter, when the operation switch 82 is pressed, the FET 70 is turned on, and power supply to the processing execution unit 10 is started. When detecting the start of power supply, the control unit 19 of the process execution unit 10 performs an initial operation, detects that the Mode signal is at a high level, initializes the printing unit 18, and enters the normal mode. Transition.

  On the other hand, when the power supply from the external power supply 3 to the printing apparatus 1 is stopped during the ON mode (power saving mode or normal mode) and then the power supply from the external power supply 3 is resumed, the state holding unit 21 self Since the holding circuit 21b is in the set state, the Ps signal becomes high level, the FET 70 is turned on, and power supply to the processing execution unit 10 is started. That is, the printing apparatus 1 shifts to the ON mode. When detecting the start of power supply, the control unit 19 of the processing execution unit 10 detects that the Mode signal is at a low level after performing an initial operation, does not initialize the printing unit 18, and does not initialize the power supply mode. Migrate to

According to the first embodiment described above, the following effects (1) to (10) can be obtained.
(1) In the present embodiment, the electronic device includes a processing execution unit that executes predetermined processing using power, and a power supply unit that supplies power supplied from an external power source to the processing execution unit. When the power supply from the external power supply to the power supply unit is resumed, the power supply unit performs the processing when the power supply to the power supply unit was stopped when the power supply to the process execution unit was performed last time. When power supply to the execution unit is started, and power supply to the process execution unit is not performed when power supply to the power supply unit was stopped last time, power supply to the process execution unit is not started. For this reason, according to this Embodiment, it becomes possible to suppress useless power consumption, improving the convenience.

  Specifically, when the power supply to the electronic device is stopped when the power supply to the processing execution unit is being performed, the power supply unit supplies the processing execution unit to the process execution unit in response to the restart of the power supply to the electronic device. Power supply is started. That is, the power supply unit performs a power-on operation in response to the restart of power supply. This eliminates the need for the user to perform a power-on operation, improving the user convenience. In addition, the process execution unit can be activated immediately after the supply of power to the electronic device is resumed, thereby shortening the operation stop period of the electronic device due to a power failure or the like. For example, when the electronic device has a function of receiving information from an external device (for example, a facsimile function), it becomes possible to shorten the period of unreceivability due to a power failure or the like.

  On the other hand, when power supply to the electronic device is stopped when power supply to the processing execution unit is not performed, when power supply to the electronic device is resumed, to the process execution unit by the power supply unit The power supply is not started. For this reason, useless power consumption can be suppressed compared with the case where the power supply to the process execution unit is always started in response to the restart of the power supply. Specifically, when power supply to the process execution unit was not originally performed, when power supply to the electronic device is stopped and restarted, it is not necessary to start power supply to the process execution unit. When power supply to the processing execution unit is started, it is considered that useless power consumption (for example, power-on operation or power consumption for startup not intended by the user) occurs. For example, as wasteful power consumption, power consumption for power-on operation not intended by the user, power consumption in the power supply unit for maintaining the power supply state, power in the process execution unit for unintended startup by the user Consumption may occur. According to the present embodiment, such wasteful power consumption can be avoided or reduced.

  Further, it is possible to eliminate a strange operation that the user starts up even though the user does not intend (for example, the user has not operated the power ON).

  Also, in the configuration where the power supply to the processing execution unit is always started in response to the restart of the power supply, when there are multiple electronic devices, when the power supply is restarted, the multiple electronic devices are activated simultaneously. As a result, the peak power may become excessive. According to the present embodiment, it is possible to avoid or reduce the occurrence of such a situation.

  By the way, when the external power supply fails, the control unit writes the operation mode at the time of the power failure to the non-volatile storage unit, and when the power failure is restored, the control unit reads the operation mode from the storage unit and restores the original operation mode. It is also possible to consider a configuration returning to However, in this configuration, in order to read the operation mode from the storage unit, it is necessary to supply power to the control unit and start the control unit. For this reason, when a power failure occurs during the OFF mode, it is desirable to maintain the OFF mode when the power failure is restored. However, in the above configuration, the control unit is activated once, so that power for activation is consumed. In addition, it appears to the user that the device has been activated unintentionally. Furthermore, when there are a plurality of electronic devices having the above-described configuration, after the recovery from the power failure, the plurality of electronic devices consume power all at once, and the peak power becomes excessive. An abrupt increase in current may cause the security device to work, and if the security device works, recovery becomes difficult.

  (2) The power supply unit is in the first state indicating that the power supply to the processing execution unit is performed when the power supply to the power supply unit is stopped, or the power supply to the power supply unit is stopped A state holding unit that holds a second state indicating that power supply to the processing execution unit has not been performed, and a switch that supplies or cuts off the power supplied from the external power supply to the processing execution unit When the power supply to the power supply unit is started and the state holding unit is in the first state, the power supply to the processing execution unit is started and the state holding unit is set to the second state. And a switch unit that does not start power supply to the process execution unit. According to this aspect, the power supply unit can be realized with a simple configuration, and the power consumption of the power supply unit can be suppressed.

  (3) The state holding unit includes a power holding unit that holds power and a self-holding circuit that holds the first or second state using the power holding unit as a power source, and the switch unit is in a state of the self-holding circuit. Accordingly, a switch element that electrically connects or disconnects between the external power supply and the processing execution unit is included. According to this aspect, the power supply unit can be configured with a small amount or simple electronic components, and the configuration of the power supply unit can be simplified and the power consumption can be further reduced.

  (4) The switch unit includes a self-holding circuit that self-holds the power supply state when power supply to the processing execution unit is started. According to this aspect, the power supply state can be maintained. For example, it is possible to change the state of the state holding unit while maintaining the power supply state of the switch unit.

  (5) The power supply unit starts power supply to the process execution unit in response to an input from the outside when power is supplied to the power supply unit and power is not supplied to the process execution unit. . According to this aspect, the configuration of the power supply unit for starting the power supply to the process execution unit in response to the restart of the power supply when the power supply to the process execution unit is started according to the input from the outside Can be used (specifically, sharing of parts).

  (6) The power supply unit includes an operation reception unit that receives an operation from the user as the input from the outside, and starts supplying power to the process execution unit when the operation reception unit receives the operation. . According to this aspect, the power supply to the process execution unit can be started in response to an operation from the user while using the configuration for starting the power supply to the process execution unit in response to the restart of the power supply. It becomes possible.

  (7) The process execution unit has different operation modes when power supply is started in response to an input from the outside and when power supply is started in response to resumption of power supply to the power supply unit. To start. According to this aspect, it becomes possible to start in the operation mode according to each case.

  (8) The process execution unit has, as an operation mode, a normal mode and a power saving mode that consumes less power than the normal mode, and is normal when power supply is started in response to an external input. When the power supply is started in response to the restart of the power supply, the power save mode is started. According to this aspect, power consumption can be suppressed when power supply is started in response to resumption of power supply (when power supply is started without the intention of the user). Specifically, it is possible to avoid or reduce consumption of a large amount of power without the user's knowledge.

  (9) In the above (7) or (8), the processing execution unit starts power supply in response to an input from the outside based on the state of the state holding unit, or supplies power to the power supply unit. It is determined whether the supply of power is started in response to the restart. According to this aspect, the configuration can be simplified by using the state holding unit for the determination.

  In the above description, the case of starting in the power saving mode when the supply of power is started in response to the restart of the power supply to the power supply unit is illustrated, but the configuration may be configured to start in the normal mode. Good.

  3 illustrates the configuration in which power from the external power supply 3 is supplied to the self-holding circuit 21b of the state holding unit 21, the power supply from the external power supply 3 to the self-holding circuit 21b may be omitted. . That is, the self-holding state of the self-holding circuit 21b may be held only by the battery 55 regardless of whether or not power is supplied to the printing apparatus 1.

Embodiment 2. FIG.
FIG. 5 is a block diagram illustrating an example of the configuration of the printing apparatus 5 as an electronic apparatus according to the second embodiment. Since this printing apparatus 5 is almost the same as that of the first embodiment, the same parts as those of the first embodiment are denoted by the same reference numerals, and description thereof is omitted or simplified.

  In the present embodiment, as illustrated in FIG. 5, the process execution unit 10 further includes a storage device 40. The storage device 40 is specifically a non-volatile memory, and here is an SD card. However, the storage device 40 may be a hard disk drive (HDD), a compact flash (CF: registered trademark), or the like.

  The process execution unit 10 stores information related to the process being executed in the storage device 40, and when power supply to the process execution unit 10 is started, information related to the process being executed is stored in the storage device 40. Then, the processing is executed using the information. Therefore, when the power supply to the process execution unit 10 is stopped due to a power failure or the like while the process is being executed by the process execution unit 10, the power supply to the process execution unit 10 is resumed due to a power failure recovery or the like The process execution unit 10 uses the information stored in the storage device 40 to perform a process interrupted by a power failure or the like. The information stored in the storage device 40 is information for performing processing interrupted due to the stop of power supply. For example, progress information indicating the progress of the processing being executed, information on the processing target of the processing being executed, etc. It is. Here, the information stored in the storage device 40 includes progress information indicating the progress of the print process being executed, and print data to be printed in the print process being executed.

  FIG. 6 is a flowchart illustrating an example of an operation during printing of the control unit 19 according to the second embodiment. Hereinafter, the operation of the control unit 19 during printing will be described with reference to FIG. The operation of FIG. 6 is executed in the normal mode.

  When receiving the print data from the communication interface 14 (S201), the control unit 19 stores the print data in the storage device 40 (S202).

  Next, the control unit 19 prints one page of the print data (S203), and determines whether the last page of the print data has been printed (S204).

  When it is determined that the last page has been printed (S204: YES), the control unit 19 shifts the process to step S206. Otherwise (S204: NO), the control unit 19 records the progress information of the print process being executed in the storage device 40 (S205), returns the process to step S203, and prints the next page. Here, the control unit 19 records the number of printed pages or the page number (that is, information indicating which page has been printed) as the progress information. The control unit 19 may record the number of printed pages in association with the file name of the print data being printed.

  In step S206, the control unit 19 deletes the print data stored in the storage device 40 in step S202, and ends the process. When the printing process is completed, the control unit 19 may record that the printing is completed in the progress information, or may delete the progress information.

  FIG. 7 is a flowchart illustrating an example of an operation after the start of power supply of the control unit 19 according to the second embodiment. Hereinafter, the operation of the control unit 19 after the start of power supply will be described with reference to FIG. The operation in FIG. 7 is executed when power supply to the process execution unit 10 is started. The operation in FIG. 7 is almost the same as the operation in FIG. 4 in the first embodiment, but steps S130 and S160 in FIG. 7 are different from steps S103 and S106 in FIG. 4, respectively.

  In step S <b> 130, the control unit 19 checks the Mode signal and the progress information of the storage device 40. Then, when the Mode signal is at the high level (logical value 1) (S130: “1”), the control unit 19 shifts the processing to step S104. Further, even when the Mode signal is at a low level (logical value 0), the control unit 19 determines that print data being printed remains in the storage device 40 (S130: “1”). The process proceeds to step S104. On the other hand, when the Mode signal is at the low level and it is determined that there is no print data being printed in the storage device 40 (S130: “0”), the process proceeds to step S108.

  In step S160, the control unit 19 executes the operation of FIG. That is, when executing the printing process, the control unit 19 causes the storage device 40 to store information regarding the printing process being executed. If it is determined in step S130 that print data being printed remains in the storage device 40, after the initialization of the print unit in step S105 is completed, the control unit 19 performs the remaining printing. Resume printing of the print data. Specifically, the control unit 19 prints an unprinted page in the print data based on the progress information recorded in the storage device 40. More specifically, the control unit 19 starts the operation of FIG. 6 from step S203. At this time, the control unit 19 starts printing from the next page after the last printed page based on the number of printed pages recorded in the storage device 40. That is, when the printing process is interrupted due to power supply interruption due to a power failure or the like, when the power supply is resumed due to a power failure recovery or the like, the control unit 19 (automatically) does not depend on the user's operation. Restart the printing process from the state. Note that the control unit 19 may resume the printing process in response to a printing instruction from the user, instead of automatically restarting the printing process after the power supply is resumed.

According to the second embodiment described above, the following effect (10) can be obtained.
(10) The process execution unit stores information related to the process being executed in the storage device, and when power supply to the process execution unit is started, when information related to the process being executed is stored in the storage device, The process is executed using the information. For this reason, when power supply to the process execution unit is stopped due to a power failure or the like during execution of the process, when power supply to the process execution unit is resumed, it is interrupted during execution using the information in the storage device It is possible to execute the process.

  Specifically, when the information to be processed is stored in the storage device, it is not necessary to supply the information to be processed again to the electronic device, and convenience is improved. In addition, when the process progress information is stored in the storage device, the process can be resumed from the position where it was interrupted. Compared with the case where the process is performed from the beginning, the consumption amount of resources such as power and paper, It becomes possible to reduce the work time of the user. For example, if there is an unexpected power interruption such as a power failure while printing several tens of MB or thousands of pages of print data, a large amount of print data will be printed again, which is inconvenient. According to the embodiment, such a problem can be avoided or reduced.

Embodiment 3 FIG.
FIG. 8 is a block diagram illustrating an example of the configuration of the printing apparatus 8 as an electronic apparatus according to the third embodiment. Since this printing apparatus 8 is almost the same as that of the first embodiment, the same parts as those of the first embodiment are denoted by the same reference numerals, and description thereof is omitted or simplified.

  In the present embodiment, the power supply unit 20 includes a reception unit 90 that receives a signal from an external device as an input from the outside. When the signal is received by the reception unit 90, the power supply unit 20 is sent to the processing execution unit 10. Start supplying power. Specifically, when the power supply unit 20 receives a signal indicating that the external device is in a predetermined state, the power supply unit 20 starts power supply. Examples of the predetermined state include a power-on state, an operation state, and a communicable state.

  In one aspect, when power supply to the process execution unit 10 is started when a signal from an external device is received, the process execution unit 10 is activated in the normal mode. However, the process execution unit 10 may be activated in the power saving mode.

  In the example of FIG. 8, the receiving unit 90 of the power supply unit 20 is connected to the host device 2 as an external device via a signal line L6. The communication interface 14 is connected to the host device 2 via the communication cable C2. Here, the communication cable C2 is a USB cable, and includes a D + line and a D− line that transmit a D + signal and a D− signal, which are data signals, a ground (GND) line, and a VBUS line that transmits a VBUS signal. Including. The VBUS signal is a signal indicating the start of communication. When the host device 2 is turned on, the VBUS signal is at a high level (specifically, 5V), and when the host device 2 is turned off, the signal is at a low level (specifically, 0V). Even when the USB cable C2 is disconnected from the USB connector of the printing apparatus 8 or the host apparatus 2, the VBUS signal is at a low level. The signal line L6 is connected to the VBUS line of the communication cable C2.

  FIG. 9 is a circuit diagram illustrating an example of a specific configuration of the power supply unit 20 according to the third embodiment. In FIG. 9, the state holding unit 21 is not shown.

  In the reception unit 90 of the power supply unit 20, the signal line L6 is connected to the Ps signal line L5 via the diode 91. The diode 91 is inserted so that the cathode is connected to the Ps signal line L5, and prevents current from flowing backward when the VBUS signal is at a low level. In the circuit of FIG. 9, when the FETs 70 and 71 are in the OFF state, when the VBUS signal is switched from the low level to the high level, the high level voltage is applied to the gate of the FET 71 through the resistor 75, and the FET 71 is turned on. FET 70 is turned on. That is, the switch unit 22 is turned on.

  Hereinafter, an example of the operation of the printing apparatus 8 according to the third embodiment will be described with reference to FIGS.

  It is assumed that the power supply from the external power source 3 to the printing device 8 and the host device 2 is stopped by the power failure, and then the power failure is restored and the power supply to the printing device 8 and the host device 2 is resumed. Further, it is assumed that the printing apparatus 8 is in the OFF mode at the time of power failure.

  In the above case, when the power supply to the printing apparatus 8 is resumed, the self-holding circuit 21b of the state holding unit 21 is in a reset state, and the power supply to the processing execution unit 10 is not started immediately.

  After the power failure is restored, when the user performs a power-on operation (for example, pressing a power switch) on the host device (for example, personal computer) 2, the host device 2 performs an initial operation and starts up an OS (Operation System). At this time, the driver of the USB interface is also initialized and becomes communicable, and the VBUS signal is changed from low level to high level. As a result, the switch unit 22 of the printing apparatus 8 is turned on, the power supply line VDD is connected to the power supply line VDD_P via the FET 70, and power supply to the processing execution unit 10 is started.

  When power supply to the process execution unit 10 is started, the control unit 19 detects that a reset signal of a reset circuit (not shown) has changed to inactive, and starts operation. When the control unit 19 detects that the VBUS signal is at a high level via the communication interface 14, the control unit 19 initializes the printing unit 18. Specifically, the printing unit 18 starts energization and control of the heater based on an instruction from the control unit 19 and performs an initial operation of the motor. When the initialization process is completed, the printing apparatus 8 enters the normal mode. Thereafter, when the printing apparatus 8 receives the print data from the host apparatus 2, the printing apparatus 8 prints the print data.

  In this way, the printing device 8 operates in conjunction with the state of the higher-level device 2. Specifically, the power supply unit 20 detects the state of the host device 2 (for example, the power state), and when the host device 2 is in a predetermined state (for example, the power ON state or the operation state), the power supply unit 20 Start supplying power. And the process execution part 10 will start in normal mode, if electric power supply is started.

According to the third embodiment described above, the following effect (11) can be obtained.
(11) The power supply unit includes a reception unit that receives a signal from an external device as an input from the outside, and starts supplying power to the processing execution unit when the signal is received by the reception unit. For this reason, it becomes possible to start the electric power supply to a process execution part according to the state and operation | movement of an external device. Thereby, the process execution unit can quickly start or shift to the normal mode according to the state or operation (for example, start) of the external device. Further, for example, according to the configuration in which the printing apparatus is activated in the normal mode in response to the activation of the upper apparatus, even when the print data is in the upper apparatus and has not been transmitted to the printing apparatus, the printing apparatus is activated in response to the activation of the upper apparatus. Can be expected to improve workability.

  In the above description, the printing apparatus is illustrated. However, the electronic apparatus is not limited to the printing apparatus, and may be another type of image forming apparatus (an apparatus that performs processing for forming an image) or an image. An apparatus that executes processes other than the forming process may be used.

  In addition, this invention is not limited to the said embodiment, In the range which does not deviate from the summary of this invention, it can implement with a various aspect. For example, when the power supply from the external power supply is stopped due to a power failure or the like during the ON mode, the printing apparatus retains the standby time (in the normal mode or the power saving mode) at the time of the stop and recovers from the power failure. When the power supply from the external power source is resumed by the above, time measurement (counting) of the standby time may be started from the held standby time (that is, using the held standby time as an initial value).

  1, 5, 8 Printing device (electronic device), 2 Host device (external device), 3 External power supply, 10 Processing execution unit, 20 Power supply unit, 21 State holding unit, 21a Power holding unit, 21b Self holding circuit, 22 Switch unit, 22a switch element, 22b self-holding circuit, 23 ON operation reception unit, 24 OFF operation reception unit, 40 storage device, 90 reception unit.

Claims (14)

Processing execution means for executing predetermined processing using electric power;
A power supply unit that supplies power supplied from an external power source to the processing execution unit, and when power supply from the external power source to the power supply unit is resumed, power supply to the power supply unit is performed. When power supply to the process execution means was performed when the process was stopped last time, power supply to the process execution means is started, and when the power supply to the power supply means is stopped last time, the process execution means Power supply means not starting power supply to the processing execution means, when power supply to is not performed,
I have a,
The power supply means
The first state indicating that the power supply to the processing execution means has been performed when the power supply to the power supply means is stopped, or the processing when the power supply to the power supply means is stopped. State holding means for holding a second state indicating that power supply to the execution means has not been performed;
Switch means for supplying or cutting off power supplied from the external power source to the processing execution means, and when the power supply to the power supply means is started, the state holding means is in the first state. Switch means for starting power supply to the process execution means, and when the state holding means is in the second state, switch means for not starting power supply to the process execution means;
Including
The power supply means starts power supply to the process execution means in response to an input from the outside when power is supplied to the power supply means and no power is supplied to the process execution means. ,
When the power supply from the power supply unit to the process execution unit is started, the process execution unit starts to supply power to the process execution unit according to an input from the outside, or the power supply When it is determined whether power supply to the process execution unit is started in response to restart of power supply to the unit, and it is determined that power supply to the process execution unit is started according to the input from the outside, A second operation different from the first operation mode is started when the first operation mode is started and it is determined that the power supply to the processing execution unit is started in response to the restart of the power supply to the power supply unit. An electronic device that is activated in a mode . The process execution means responds to the start of power supply to the process execution means in response to an input from the outside based on the state of the state holding means, or in response to restart of power supply to the power supply means The electronic apparatus according to claim 1, wherein it is determined whether power supply to the processing execution unit is started . The state holding unit includes a power holding unit that holds power, and a self-holding circuit that holds the first or second state using the power holding unit as a power source.
The switch means includes a switch element that electrically connects or disconnects between the external power supply and the processing execution means, depending on the state of the self-holding circuit.
The electronic device according to claim 1 , wherein the electronic device is an electronic device. Said switch means, when starting the power supply to the processing execution unit, according to the power supply state to any one of claims 1, characterized in that it comprises a self-holding circuit for self-holding 3 Electronics. The power supply unit includes an operation reception unit that receives an operation from a user as an input from the outside, and starts the power supply when the operation is received by the operation reception unit. Item 5. The electronic device according to any one of Items 1 to 4 . The power supply means includes reception means for receiving a signal from an external device as the input from the outside, and starts the power supply when the signal is received by the reception means. Item 6. The electronic device according to any one of Items 1 to 5 . The first operation mode is a normal mode, the second mode of operation, any one of claims 1 to 6, characterized in that the usually low power saving mode power consumption than mode The electronic device as described in. The process execution means stores information related to the process being executed in the storage means, and when power supply to the process execution means is started, information related to the process being executed is stored in the storage means the electronic device according to any one of claims 1 7, characterized in that to execute the process by using the information. 9. The process execution unit according to claim 1, wherein when the power supply from the power supply unit to the process execution unit is started, the state holding unit is set to the first state. The electronic device of Claim 1. When the power supply from the power supply unit to the process execution unit is started, the process execution unit is configured to supply power to the process execution unit in accordance with an input from the outside based on the state of the state holding unit. After determining whether supply has started or whether power supply to the processing execution unit has started in response to resumption of power supply to the power supply unit, the state holding unit is set to the first state. The electronic apparatus according to claim 9. The process execution unit, when stopping the power supply from the power supply unit to the process execution unit, sets the state holding unit to the second state and then sets the switch unit to a cut-off state. The electronic device according to any one of claims 1 to 10. A power supply that is provided between the external power supply and the power supply means, converts a voltage from the external power supply into a voltage corresponding to the power supply means, and supplies power from the external power supply to the power supply means The electronic apparatus according to claim 1, further comprising a unit. The process execution means includes
  A communication interface;
  A printing section;
  A control unit that receives print data from a host device via the communication interface and causes the printing unit to print an image based on the print data;
  The electronic apparatus according to claim 1, comprising: Processing execution means for executing image forming processing using electric power;
A power supply unit that supplies power supplied from an external power source to the processing execution unit, and when power supply from the external power source to the power supply unit is resumed, power supply to the power supply unit is performed. When power supply to the process execution means was performed when the process was stopped last time, power supply to the process execution means is started, and when the power supply to the power supply means is stopped last time, the process execution means Power supply means not starting power supply to the processing execution means, when power supply to is not performed,
I have a,
The power supply means
The first state indicating that the power supply to the processing execution means has been performed when the power supply to the power supply means is stopped, or the processing when the power supply to the power supply means is stopped. State holding means for holding a second state indicating that power supply to the execution means has not been performed;
Switch means for supplying or cutting off power supplied from the external power source to the processing execution means, and when the power supply to the power supply means is started, the state holding means is in the first state. Switch means for starting power supply to the process execution means, and when the state holding means is in the second state, switch means for not starting power supply to the process execution means;
Including
The power supply means starts power supply to the process execution means in response to an input from the outside when power is supplied to the power supply means and no power is supplied to the process execution means. ,
When the power supply from the power supply unit to the process execution unit is started, the process execution unit starts to supply power to the process execution unit according to an input from the outside, or the power supply When it is determined whether power supply to the process execution unit is started in response to restart of power supply to the unit, and it is determined that power supply to the process execution unit is started according to the input from the outside, A second operation different from the first operation mode is started when the first operation mode is started and it is determined that the power supply to the processing execution unit is started in response to the restart of the power supply to the power supply unit. An image forming apparatus that is activated in a mode .

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