JP2015018303A - Electronic apparatus, control method of electronic apparatus, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress, even when instantaneous interruption has occurred to a power source to be supplied to an electronic apparatus such as a projection device, the electronic apparatus from being shifted to a stand-by state when the electronic apparatus returns from the instantaneous interruption.SOLUTION: An electronic apparatus 1 includes an electronic apparatus main body unit 50, a delay circuit that receives the input of the voltage of power supplied to the electronic apparatus main body unit 50 and delays the output of a voltage responding to the input voltage, a voltage detection IC 26 that compares the output voltage from the delay circuit with a predetermined threshold and outputs a result of the comparison, and a power source control microcomputer 13 that reads the result of the comparison by the voltage detection IC 26 at the start-up and starts the electronic apparatus main body unit 50 when the result of the comparison indicates that the output voltage is equal to or more than the threshold.

Description

  The present invention relates to an electronic device, an electronic device control method, and a program.

The projection apparatus disclosed in Patent Document 1 includes a backup power source, and even if a power failure occurs, each part of the projection apparatus operates with the backup power source, and a necessary shutdown process is performed on each part of the projection apparatus. Specifically, not only the main CPU and sub CPU, but also a power supply unit (power circuit), a fan, a projection unit (the projection unit has at least a liquid crystal element), a network unit, etc. Since the shutdown process is performed, the backup power supply has a very large capacity. However, when the main power source of the projection apparatus described in Patent Document 1 is an AC-DC converter and the backup power source is a capacitor, the current value of the AC-DC converter is large because the output rating of the AC-DC converter is large. Therefore, it is difficult to secure the voltage of each part of the projection apparatus with the capacity of the capacitor and continue the operation of each part after a power failure.
Further, in the technique described in Patent Document 1, when a momentary interruption (instantaneous power failure) occurs, the projector returns to the standby state when the instantaneous interruption is restored.

JP 2007-316389 A

When the technique described in Patent Document 1 is adopted, when the projection apparatus is continuously used after returning from an instantaneous interruption, the user needs to operate the projection apparatus to activate the projection apparatus. Such an operation is troublesome for the user. Further, if the user is away from the projection apparatus, the projection apparatus cannot be activated.
Therefore, the problem to be solved by the present invention is that even when a voltage drop (decrease) occurs in the power supply supplied to the electronic apparatus such as the projection apparatus, the electronic apparatus is brought into an appropriate state when the state is recovered from the state. It is to return.

  In order to solve the above-described problems, an electronic device according to the present invention includes an electronic device main body and power supplied to the electronic device main body from when the voltage of power supplied to the electronic device main body drops. The voltage drop time until the voltage of the voltage rises is compared with a predetermined threshold, and the comparison result of the voltage drop time comparison unit that outputs the comparison result and the voltage drop time comparison unit at the start-up is read, and the comparison result And a control unit that activates the electronic device main body when the value is equal to or less than the threshold value.

  The electronic device according to the present invention includes an electronic device main body and a voltage from when the voltage of power supplied to the electronic device main body decreases to when the voltage of power supplied to the electronic device main body increases. When the comparison result of the voltage drop time comparison unit that compares the fall time with a predetermined threshold and outputs the comparison result and the comparison result of the voltage drop time comparison unit at the time of start-up and the comparison result is below the threshold value And a control unit that returns the electronic device main body to a power state before the voltage drops.

  An electronic device according to the present invention includes an electronic device main body, a delay unit that inputs a voltage of power supplied to the electronic device main body, and outputs a voltage that responds with a delay with respect to the input voltage, and the delay A comparator that compares the output voltage of the unit with a predetermined threshold, outputs the comparison result, and reads the comparison result of the comparator at start-up, and if the comparison result is equal to or greater than the threshold, the electronic device main unit is A control unit to be activated.

  The electronic device according to the present invention starts counting from the time when the voltage of the power supplied to the electronic device main body and the electronic device main body drops, and before the time exceeds a predetermined threshold, the electronic device A voltage drop time measurement unit that outputs a determination result as to whether or not the voltage of power supplied to the main body has risen; a holding unit that holds a power supply voltage of the voltage drop time measurement unit; and the voltage drop time at startup A control unit that reads a determination result of the measurement unit and activates the electronic device main body when the determination result is not negative.

An electronic device according to the present invention is provided between an electronic device main body, a power supply circuit that supplies power to the electronic device main body, and a power output unit of the power supply circuit and a power input unit of the electronic device main body. The time measurement is started from the time when the voltage of the normally-off switching element and the power input unit of the electronic device main body drops, and before the time exceeds the predetermined threshold, the power output unit of the power supply circuit A voltage drop time measurement unit that outputs a determination result of whether or not the voltage has increased; and
A holding unit that holds the power supply voltage of the voltage drop time measurement unit, a control unit that reads the determination result of the voltage drop time measurement unit at the time of activation, and activates the electronic device main body when the determination result is not negative, Is provided.

  An electronic device according to the present invention is provided between an electronic device main body, a power supply circuit that supplies power to the electronic device main body, and a power output unit of the power supply circuit and a power input unit of the electronic device main body. Input the voltage of the electric power supplied to the electronic device main body with the switching element turned on and the switching element turned on, and start timing from the time when the input voltage drops. When the input voltage rises after exceeding a threshold value, the switching element is turned off, and when the input voltage of the power input part of the electronic device main body part rises before the timed time exceeds the threshold value, the switching element And a holding unit that holds the power supply voltage of the control unit.

The method for controlling an electronic device according to the present invention sets a predetermined voltage drop time from when the voltage of power supplied to the electronic device main body decreases to when the voltage of power supplied to the electronic device main body increases. Outputting a comparison result compared with the threshold value of
Reading the comparison result at the time of activation, and activating the electronic device main body when the comparison result is equal to or less than the threshold value.

  The program according to the present invention is a voltage drop time from when the voltage of power supplied to the electronic device main body decreases to the time when the voltage of power supplied to the electronic device main body increases. A function for comparing the value with a predetermined threshold and outputting the comparison result; a function for reading the comparison result at the time of activation; and for activating the electronic device main body when the comparison result is equal to or less than the threshold; Let the program to realize

  ADVANTAGE OF THE INVENTION According to this invention, even if the voltage drop (decrease) of the electric power supplied to an electronic device generate | occur | produces, when it returns from the state, an electronic device can be returned to an appropriate state.

It is a block diagram of the electronic device which concerns on 1st Embodiment of this invention. The change which arises in the output voltage of the 1st power supply circuit of the same electronic device and the output voltage of a delay part in the case of a momentary interruption and a long-term blackout is shown. It is a flowchart for demonstrating the flow of the process which the power supply control microcomputer with which the electronic device which concerns on 1st Embodiment of this invention is equipped is performed. It is a block diagram of the electronic device which concerns on 2nd Embodiment of this invention. It is a flowchart for demonstrating the flow of the process which the power supply control microcomputer with which the electronic device which concerns on 2nd Embodiment and 3rd Embodiment of this invention is equipped is performed. It is a block diagram of the electronic device which concerns on 3rd Embodiment of this invention.

  EMBODIMENT OF THE INVENTION Below, the form for implementing this invention is demonstrated using drawing. However, the embodiments described below are given various technically preferable limitations for carrying out the present invention. Therefore, the technical scope of the present invention is not limited to the following embodiments and illustrated examples.

[First Embodiment]
FIG. 1 is a block diagram showing an electronic apparatus 1 according to the first embodiment of the present invention. The electronic device 1 is a projection device with an audio output function. That is, the electronic device 1 reproduces video and audio, outputs audio, and projects the video. In particular, the electronic device 1 is a video projection type digital signage (electronic signage), and video and audio are used for advertisement. Note that video and audio reproduced by an external device different from the electronic device 1 may be input to the electronic device 1, the video may be projected by the electronic device 1, and the audio may be output by the electronic device 1. .

When an instantaneous interruption of the power supplied from the AC power supply 2 to the electronic device 1 occurs, the power supply to the electronic device 1 is interrupted for a short time, and the electronic device 1 is forcibly shut down. Even in such a case, when the electronic device 1 has a resume function and power supply to the electronic device 1 is resumed, the electronic device 1 is automatically activated and the electronic device 1 returns to the state immediately before the occurrence of the instantaneous interruption. Then, the processing of the electronic device 1 is resumed from that state. This resume function is effective in the event of a momentary interruption. If the power supply is interrupted for a long time, the resume function is invalid, and the electronic device 1 is automatically activated even if the power supply is resumed. Without entering standby (standby). The momentary interruption is a power failure for a short time, and more specifically, means that the time from when the supply of power to the electronic device 1 is interrupted to when it resumes is equal to or less than a predetermined threshold. A power outage that exceeds the predetermined threshold is called a long-term power outage. When the electronic device 1 is forcibly disconnected from the AC power source 2, if the disconnection time exceeds a predetermined threshold, the disconnection is also referred to as a long-term power failure, and if the disconnection time is equal to or less than the predetermined threshold, This disconnection is also called instantaneous interruption.
As an example of the threshold value, about 50 ms is set.
Thereby, for example, when the AC plug of the electronic device 1 is disconnected from the AC outlet, it is regarded as a long-term power failure.

Next, the configuration of the electronic device 1 will be described.
The electronic device 1 includes a first power circuit 11, a second power circuit 12, a power control microcomputer (control unit) 13, a power switch 14, a switching element 15, a voltage drop time comparison unit (instantaneous interruption detection circuit) 20, a main microcomputer (electronic Device control unit) 30, nonvolatile memory 31, electronic device main body unit 50, and the like. Of these, the power supply device 10 is a device (circuit) having the AC / DC converter 11, the second power supply circuit 12, the power supply control microcomputer 13, the power switch 14, the switching element 15, and the voltage drop time comparison unit 20.

  The power supply device 10 converts AC power supplied from the AC power source 2 into DC power having a constant voltage, and supplies the DC power to the electronic device main body 50, the main microcomputer 30, and the nonvolatile memory 31.

  The electronic device main body 50 is operated by the DC power supplied from the power supply device 10. The electronic device main body 50 includes a content storage unit 51, a reader 52, a decoder 53, a D / A converter 54, an amplifier 55, a speaker 56, a video input terminal 61, a video signal conversion unit 62, a video signal processing unit 63, and a display controller 64. A display element 65, a light source controller 66, a light source device 67, a projection lens unit 68, and the like.

  The electronic device main unit 50 is a DMD type projector main unit, an LCD type projector main unit, or an LCOS (ELCOS: Liquid crystal on silicon: LCoS is a trademark) type main unit. The DMD type projector main body uses a DMD (digital micromirror device) for the display element 65. The LCD type projector main body uses a transmissive LCD panel (liquid crystal display element panel) as the display element 65. The LCOS type projector main body uses a reflective LCD panel for the display element 65.

  The content storage unit 51 is a non-volatile memory, a hard disk drive, or other storage medium. The content storage unit 51 stores a moving image file composed of video data and audio data. The content storage unit 51 may be built in the electronic device main body 50 or may be externally attached to the electronic device main body 50 and removable from the electronic device main body 50.

  The reader 52 reads a moving image file from the content storage unit 51 and transfers the moving image file to the decoder 53.

  The decoder 53 separates the moving image file into video data and audio data, and decodes the separated video data and audio data. The decoder 53 transfers the decoded digital audio signal to the D / A converter 54 and transfers the decoded digital video signal to the video signal conversion unit 62. When video data and audio data are decoded by the decoder 53, the decoder 53 outputs the decoding position (reproduction position) to the main microcomputer 30. The decoding position (reproduction position) represents the time from the beginning of the video data and audio data, and is the position where the decoder 53 is currently decoding the video data and audio data.

The D / A converter 54 converts the digital audio signal input from the decoder 53 into an analog audio signal and outputs the analog audio signal to the amplifier 55.
The amplifier 55 amplifies the analog audio signal input from the D / A converter 54. The amplifier 55 drives the speaker 56 by outputting the amplified audio signal to the speaker 56. As a result, sound corresponding to the sound signal is output from the speaker 56. Note that when audio is input from an external device different from the electronic device 1, if the audio input from the external device is a digital audio signal, the audio signal is input to the D / A converter 54, and the external device If the sound input from is an analog sound signal, the sound signal is input to the amplifier 55.

  The video input terminal 61 is provided on the housing of the electronic device 1. A video output terminal of an external device (for example, a personal computer, a mobile phone, a multi-function mobile phone, a playback device) is connected to the video input terminal 61 via a video signal cable, and a video signal output by the external device is a video input terminal. 61 is input.

  When the signal input from the video input terminal 61 is an analog video signal, the video signal conversion unit 62 converts the input analog video signal into a digital video signal, and the digital video signal or video input from the decoder 53. When the signal input to the input terminal 61 is a digital video signal, the input digital video signal is converted into a predetermined format. The video signal converter 62 converts the digital video signal input from the decoder 53 into a predetermined format.

  The video signal processing unit 63 performs various types of signal processing on the video signal output by the video signal conversion unit 62. For example, the video signal processing unit 63 performs scaling of the video signal input from the video signal conversion unit 62 to increase or decrease the number of pixels (resolution) of the video signal. The video signal processing unit 63 performs keystone correction, fitting correction, or both by performing coordinate conversion (for example, projective conversion) of video based on the scaled video signal. The video signal processed by the video signal processing unit 63 is transferred to the display controller 64.

  The display element 65 is a spatial light modulation element, more specifically a DMD, a transmissive LCD panel, or a reflective LCD panel. The display element 65 has a plurality of pixels arranged in a two-dimensional array. When the display element 65 is a DMD, the pixel of the display element 65 is a movable micromirror, and when the display element 65 is a transmissive LCD panel or a reflective LCD panel, the pixel of the display element 65 is a liquid crystal element. It is.

  The display controller 64 drives the display element 65 based on the video signal input from the video signal processing unit 63. For example, when the display controller 64 performs PWM control or PNM control for each pixel of the display element 65 in accordance with the video signal input from the video signal processing unit 63, the light emitted to the display element 65 is modulated for each pixel by the pixel. The Thereby, an image is formed by the display element 65.

  The number of display elements 65 is one or more (for example, three).

  The light source device 67 emits visible light toward the display element 65. Specifically, the light source device 67 is a time division type or a color separation type.

  When the light source device 67 is a color separation method, the light source device 67 has a white light source, a color separator, and the like, and white light emitted from the white light source has a plurality of colors (for example, red, green, blue) by the color separator. Separated into light. In this case, the number of the display elements 65 is plural, the display elements 65 respectively generate images of the respective colors, the light of each color is irradiated on the display elements 65, and the light of each color transmitted or reflected by the display elements 65, respectively. Is synthesized. The synthesized projection light is projected onto the screen by the projection lens unit 68, so that a color image is projected on the screen.

  When the light source device 67 is a time-division method, the light source device 67 sequentially and repeatedly irradiates the display element 65 with visible light of different colors (for example, red light, green light, and blue light). This corresponds to a period in which a color image of one frame is generated by the display element 65. In this case, the number of display elements 65 is one, and the display elements 65 sequentially generate images of different colors. More specifically, the display element 65 generates an image having the same color as the light emitted from the light source device 67 in synchronization with the light emission timing. The light of each color transmitted or reflected by the display element 65 is combined on the time axis, and the combined projection light is projected onto the screen by the projection lens unit 68, whereby a color image is displayed on the screen.

  When the light source device 67 is a time division method, the light source device 67 is a color filter method or a color light source method. When the light source device 67 is a color filter system, the light source device 67 includes a color filter, a spindle motor, a white light source, and the like, the color filter is rotated by the spindle motor, and the white light emitted from the white light source is rotating. The white light passes through each color (red, green, blue) and is sequentially converted. When the light source device 67 is a color light source method, the light source device 67 has a plurality of light sources having different colors (for example, a red light source, a green light source, and a blue light source), and these light sources are repeatedly turned on sequentially.

  The light source used for the light source device 67 is a semiconductor light emitting element (for example, laser diode, light emitting diode) or a lamp (for example, halogen lamp, xenon lamp, metal halide, mercury lamp, discharge lamp), or a semiconductor light emitting element or lamp. And a combination of phosphors.

  The light source controller 66 controls the luminance of the light source device 67.

  Further, when the light source device 67 is a time division method, the light source control unit 66 controls the emission timing of each color light of the light source device 67 based on the timing signal input from the display controller 64. Thereby, the light emitted from the light source device 67 is synchronized with the timing at which the display element 65 generates the same color image.

  The projection lens unit 68 includes a plurality of lenses and a driving device that moves at least one of these lenses in the optical axis direction. The projection lens unit 68 is capable of adjusting the focusing and adjusting the focal length by moving the lens by the driving device.

  The main microcomputer 30 is an arithmetic processing unit (computer) having a CPU, a RAM, a ROM, and the like. A program is stored in the ROM of the main microcomputer 30. The main microcomputer 30 reads the ROM program and executes processing according to the program. Thereby, the main microcomputer 30 controls the electronic device main body 50 in an integrated manner. When the main microcomputer 30 controls the electronic device main body 50 in an integrated manner, the main microcomputer 30 overwrites and records data representing the state of the electronic device main body 50 (hereinafter referred to as state data) in the nonvolatile memory 31. As a result, the state data recorded in the nonvolatile memory 31 is updated. As a specific example, the main microcomputer 30 executes processes as shown in the following (1) to (4).

(1) The main microcomputer 30 causes the video signal processing unit 63 to perform keystone correction, fitting correction, or both. That is, the main microcomputer 30 outputs a parameter (for example, a correction coefficient) indicating the keystone correction or the fitting correction or both of these states to the video signal processing unit 63, and the video signal processing unit 63 is based on the parameters. Perform keystone correction, fitting correction, or both. At this time, the main microcomputer 30 overwrites and saves the parameter in the nonvolatile memory 31. The parameter recorded in the nonvolatile memory 31 is a kind of state data.

(2) The main microcomputer 30 causes the light source control unit 66 to perform luminance control. That is, the main microcomputer 30 outputs a dimming signal representing the luminance to the light source control unit 66, and the light source control unit 66 causes the light source device 67 to emit light with luminance according to the dimming signal input from the main microcomputer 30. At this time, the main microcomputer 30 overwrites and saves the luminance data represented by the dimming signal in the nonvolatile memory 31. The luminance data recorded in the nonvolatile memory 31 is a kind of state data.

(3) The main microcomputer 30 controls the projection lens unit 68 to adjust the focal length and focusing distance of the projection lens unit 68 (the distance from the front lens of the projection lens unit 68 to the in-focus screen). At this time, the main microcomputer 30 overwrites and stores the focal length and the focusing distance in the nonvolatile memory 31. The focal length and the focusing distance recorded in the nonvolatile memory 31 are a kind of state data.

(4) The main microcomputer 30 causes the reader 52 to execute the reading process and causes the decoder 53 to execute the decoding process. When video data and audio data are decoded by the decoder 53, the decoder 53 outputs the decoding position (reproduction position) to the main microcomputer 30. The decoding position (reproduction position) represents the time from the beginning of the video data and audio data, and is the position where the decoder 53 is currently decoding the video data and audio data. The main microcomputer 30 overwrites and saves the decoding position input from the decoder 53 in the nonvolatile memory 31. The decoding position recorded in the nonvolatile memory 31 is a kind of state data.

  Since the state of the electronic device main body 50 is recorded in the non-volatile memory 31 by the main microcomputer 30, the stored contents of the non-volatile memory 31 are not erased even if a power failure occurs regardless of a momentary power failure or a long-term power failure.

Next, the power supply device 10 will be described in detail.
The power supply device 10 has a resume function related to the power-on state and the standby state even when the AC power supply 2 is momentarily interrupted. In other words, when power is supplied to the electronic device main body 50 and the main microcomputer 30 by the power supply device 10 immediately before the instantaneous interruption of the AC power supply 2 and these are activated (in the ON state), the AC power supply 2 After the power supply is restored from the momentary interruption, power is supplied to the electronic device main body 50 and the main microcomputer 30 by the power supply device 10, and they are activated (turned on). On the other hand, if the power supply 10 does not supply power to the electronic device main body 50 and the main microcomputer 30 before the AC power supply 2 is interrupted, and these are not activated (in the standby state), the AC power supply Even after 2 recovers from the momentary interruption, power is not supplied to the electronic device main body 50 and the main microcomputer 30, and these do not start (become in a standby state).

  In the case of a long-term power failure of the AC power supply 2, the resume function of the power supply device 10 becomes invalid. That is, whether or not power is supplied to the electronic device main body 50 and the main microcomputer 30 by the power supply device 10 immediately before the long-term power failure of the AC power supply 2, after the AC power supply 2 recovers from the long-term power failure, the power supply device 10 As a result, power is not supplied to the electronic device main body 50 and the main microcomputer 30, and they are not activated.

Next, each part of the power supply device 10 will be described in detail.
The first power supply circuit 11 is an AC-DC converter. Therefore, hereinafter, the first power supply circuit 11 is referred to as an AC-DC converter 11. The AC-DC converter 11 converts AC power supplied from the AC power source 2 into DC power. The AC-DC converter 11 is a constant voltage power supply, and the output voltage of the AC-DC converter 11 (the voltage at the A portion) is almost kept at a constant value.

  The power output unit of the AC-DC converter 11 is connected to the power input unit of the electronic device main body 50 and the power input unit of the main microcomputer 30 via the switching element (for example, FET) 15. When the switching element 15 is on, a voltage having a predetermined value is applied to the main microcomputer 30 and the electronic device main body 50, and power is supplied from the AC-DC converter 11 to the main microcomputer 30 and the electronic device main body 50 (B portion). Is supplied.

  From the AC-DC converter 11 to each part of the electronic device main body 50 (reader 52, decoder 53, D / A converter 54, amplifier 55, video signal converter 62, video signal processor 63, display controller 64, display element 65, light source Power is directly supplied to the control unit 66, the light source device 67, the projection lens unit 68, etc.) or supplied via a stabilized power source. The stabilized power source converts direct current power supplied from the AC-DC converter 11 into power of a predetermined voltage, and supplies the converted power to each part of the electronic device main body 50. As the stabilizing power source, a chopper control power source, a switching control power source or a series regulator power source can be used. The stabilized power source may be provided in each part of the electronic device main body 50.

  The switching element 15 is provided on the electric circuit from the power output unit of the AC-DC converter 11 to the power input unit of the main microcomputer 30 and the power input unit of the electronic device main body 50. The switching element 15 is a normally-off FET. That is, when no voltage is applied to the gate of the switching element 15, the switching element 15 is turned off.

  The AC-DC converter 11 supplies power to the power supply control microcomputer 13 via the second power supply circuit 12. Here, the power output unit of the AC-DC converter 11 is connected to the power input unit of the second power supply circuit 12, and the power output unit of the second power supply circuit 12 is connected to the power input unit (Vcc input terminal) of the power control microcomputer 13. It is connected.

Regardless of whether the switching element 15 is on or off, the output voltage of the AC-DC converter 11 is applied to the power input section of the second power supply circuit 12, and power is supplied from the AC-DC converter 11 to the second power supply circuit 12. .
The second power supply circuit 12 converts the DC input power supplied by the AC-DC converter 11 into DC output power. The second power supply circuit 12 is a constant voltage DC-DC converter, and the output voltage of the second power supply circuit 12 is kept substantially constant. In particular, the second power supply circuit 12 is a series regulator.

  The output voltage of the second power supply circuit 12 is applied to the power supply input unit of the power supply control microcomputer 13, and power is supplied from the second power supply circuit 12 to the power supply control microcomputer 13.

  The power output unit of the second power supply circuit 12 is connected to the power input unit of the voltage drop time comparison unit 20 (Vss input terminal of the voltage detection IC 26), and the output voltage of the second power supply circuit 12 compares the voltage drop time. The power is applied to the power input unit of the unit 20, and power is supplied from the second power circuit 12 to the voltage drop time comparison unit 20.

  The voltage drop time comparison unit 20 is an instantaneous interruption detection circuit that detects whether or not the voltage drop of the power supplied from the AC-DC converter 11 to the main microcomputer 30 and the electronic device main body 50 is an instantaneous interruption. The parts whose voltage is monitored by the voltage drop time comparison unit 20 are the power input unit of the main microcomputer 30 and the power input unit (B unit) of the electronic device main body 50. With reference to FIGS. 2 (a) and 2 (b), a description will be given of the voltage change in part A when an instantaneous interruption or a long-term power failure occurs with the switching element 15 turned on. FIG. 2 (a) schematically shows a voltage change in part A when an instantaneous interruption occurs, and FIG. 2 (b) schematically shows a voltage change in part A when a long-term power failure occurs. It is shown in

  As shown in FIGS. 2 (a) and 2 (b), when the AC power supply 2 fails, regardless of the momentary interruption or long-term power failure, the voltage of the A part falls, and when the AC power supply 2 recovers from the power failure, The voltage rises. The voltage drop time comparison unit 20 compares the voltage drop time from when the voltage of the A part drops to when it rises to a predetermined threshold value, and outputs the comparison result to the power supply control microcomputer 13. Note that Va shown in FIGS. 2A and 2B is an output voltage of the AC-DC converter 11.

  Next, the configuration of the voltage drop time comparison unit 20 will be described in detail with reference to FIG. The voltage drop time comparison unit 20 includes a rectifying element 21, a capacitor 22, resistors 23, 24, 25 and a voltage detection IC 26.

  The anode of the rectifying element 21 is connected to the power input unit of the main microcomputer 30, the power input unit of the electronic device main body 50, and the switching element 15.

  The cathode of the rectifying element 21 is connected to one terminal of the capacitor 22, and the other terminal of the capacitor 22 is connected to the ground. Resistors 23, 24, and 25 are connected in series between the cathode of the rectifying element 21 and the ground, and the resistors 23, 24, and 25 and a capacitor are connected in parallel between the cathode of the rectifying element 21 and the ground. Yes. A connection portion between the resistor 24 and the resistor 25 is connected to an input terminal of the voltage detection IC 26. The resistors 23 and 24 may be omitted, and the input terminal of the voltage detection IC 26 may be connected to the cathode of the rectifying element 21 and one terminal of the capacitor 22.

  The delay circuit including the capacitor 22 and the resistors 23, 24, and 25 inputs the voltage of power supplied from the AC-DC converter 11 to the electronic device main body 50 via the rectifier element 21, and with respect to the input voltage. A voltage that responds later is output to the input terminal of the voltage detection IC 26. A change in the input voltage (output voltage of the delay circuit) Vin of the voltage detection IC 26 will be described in detail with reference to FIGS. FIG. 2C shows a change in the input voltage Vin of the voltage detection IC 26 when an instantaneous interruption occurs, and FIG. 2D shows the input voltage Vin of the voltage detection IC 26 when a long-term power failure occurs. This shows the voltage change.

  Regardless of momentary interruption or long-term power failure, if a power failure occurs with the switching element 15 turned on, the input voltage Vin of the voltage detection IC 26 gradually decreases, and the input voltage Vin of the voltage detection IC 26 becomes the voltage of the A section. It falls late with respect to it. This is due to a transient phenomenon related to discharge in the capacitor 22 and the resistors 23, 24, and 25. If a power failure occurs while the switching element 15 is on, the second power supply circuit 12 described later is forcibly shut down, so that the switching element 15 is turned off when the power failure occurs.

  Since the input voltage Vin of the voltage detection IC 26 responds with a delay with respect to the voltage of the A part, as shown in FIG. 2C, at the end of the instantaneous interruption (when the AC power supply 2 is restored from the instantaneous interruption), The input voltage Vin of the voltage detection IC 26 is not less than a predetermined threshold value Vth. On the other hand, in the case of a long-term power failure, as shown in FIG. 2D, when the long-term power failure ends (when the AC power supply 2 is restored from the long-term power failure), the input voltage Vin of the voltage detection IC 26 is the threshold Vth. Is less than. Here, the threshold value Vth is used to determine whether the voltage drop in the part A is an instantaneous interruption or a long-term power failure. Note that Vb shown in FIGS. 2C and 2D represents the input voltage Vin of the voltage detection IC 26 when the voltage of the A section is Va in a state where the switching element 15 is on and the capacitor 22 is fully charged. Value.

The voltage detection IC 26 is a comparator. That is, the voltage detection IC 26 compares the input voltage Vin with the threshold value Vth, and outputs the comparison result to the power supply control microcomputer 13 as the output voltage Vout. If the input voltage Vin is greater than or equal to the threshold Vth, the output voltage Vout is high (1), and if the input voltage Vin is less than the threshold Vth, the output voltage Vout is low (0). The relationship between the comparison result and the output voltage Vout may be reversed.
In this way, the constants and threshold values Vth of the capacitor 22 and the resistors 23, 24, and 25 are determined so that the threshold of the time axis of instantaneous interruption and long-term power failure corresponds to the threshold voltage Vth of the input voltage Vin of the voltage detection IC 26. ing.

  The process in which the voltage detection IC 26 compares the input voltage Vin and the threshold value Vth is equivalent to the process in which the voltage drop time comparison unit 20 compares the voltage drop time of the A part with a predetermined threshold value. Therefore, if the input voltage Vin is equal to or greater than the threshold value Vth, the comparison result by the voltage drop time comparison unit 20 indicates that the voltage drop time is equal to or less than a predetermined threshold value. This is the voltage drop time comparison unit (instantaneous interruption detection unit) 20. This means that an instantaneous interruption has been detected. On the other hand, if the input voltage Vin is less than the threshold value Vth, the comparison result by the voltage drop time comparison unit 20 indicates that the voltage drop time exceeds a predetermined threshold, which is detected by the voltage drop time comparison unit (instantaneous interruption detection unit) 20. A long-term power outage has been detected.

  The voltage detection IC 26 operates with the power supplied from the second power supply circuit 12. Therefore, the voltage detection IC 26 is forcibly stopped when a power failure occurs regardless of the instantaneous interruption or long-term power failure, and regardless of whether the switching element 15 is turned on or off. Thereafter, when the power supply recovers from the power failure, the power is supplied to the voltage detection IC 26 by the second power supply circuit 12, and thus the voltage detection IC 26 operates.

  Even when a momentary interruption occurs when the switching element 15 is turned on, and the voltage detection IC 26 is stopped by this, the input voltage Vin of the voltage detection IC 26 is held above the threshold due to the transient phenomenon of the capacitor 22, and thereafter The instantaneous voltage interruption can be detected by the voltage drop time comparison unit 20 at the time of recovery. On the other hand, when a long-term power failure occurs with the switching element 15 turned on, the transient phenomenon of the capacitor 22 has ended or is about to end, so that the input voltage Vin of the voltage detection IC 26 becomes less than the threshold value, thereby A power failure can be detected by the voltage drop time comparison unit 20. That is, the voltage drop time comparison unit 20 can identify whether the switching element 15 is turned on or an instantaneous interruption or a long-term power failure.

  Considering the case where a power failure occurs with the switching element 15 turned off, the capacitor 22 is already fully discharged when the power failure occurs, so the input voltage Vin of the voltage detection IC 26 is the threshold value. It remains below Vth. Therefore, regardless of whether there is a momentary power failure or a long-term power failure, if the power failure occurs with the switching element 15 turned off, the voltage drop time comparison unit 20 cannot identify whether it is a momentary power failure or a long-term power failure. Either a power failure or a long-term power failure is detected by the voltage drop time comparison unit 20 as the same phenomenon as when a long-term power failure occurs while the switching element 15 is on. This is because the voltage drop of the B part, not the voltage of the A part shown in FIG.

Next, the power control microcomputer 13 and the power switch 14 will be described.
The power switch 14 is turned on / off by the user. When the power switch 14 is turned on by the user, a signal to that effect is output from the power switch 14 to the power control microcomputer 13. On the other hand, when the power switch 14 is turned off by the user, a signal to that effect is output from the power switch 14 to the power control microcomputer 13.

  The power supply control microcomputer 13 is an arithmetic processing unit (computer) having a CPU, a RAM, a ROM, and the like. A program is stored in the ROM of the power supply control microcomputer 13. The power supply control microcomputer 13 reads a ROM program and executes processing according to the program.

  The power supply control microcomputer 13 operates with the power supplied from the second power supply circuit 12. Therefore, the power supply control microcomputer 13 is forcibly stopped when a power failure occurs regardless of the instantaneous interruption or the long-term power failure. On the other hand, when power is restored from a power failure, power is supplied to the power supply control microcomputer 13 by the second power supply circuit 12, so that the power supply control microcomputer 13 is activated.

Next, processing of the power supply control microcomputer 13 after startup will be described with reference to FIG.
When the power supply control microcomputer 13 is activated regardless of the instantaneous interruption or long-term power failure and the power supply control microcomputer 13 is activated, the power supply control microcomputer 13 executes the process shown in FIG.

  First, the power supply control microcomputer 13 reads the comparison result (output voltage Vout) by the voltage detection IC 26 (step S1). Here, when the switching element 15 is in the ON state immediately before the power failure, if the power supply control microcomputer 13 is started after the instantaneous interruption, the voltage drop time of the A part immediately before the power supply control microcomputer 13 is started is less than a predetermined threshold value. The comparison result by the voltage detection IC 26 indicates that the input voltage Vin is equal to or higher than the threshold value Vth. If the power supply control microcomputer 13 is activated after the long-term power failure when the switching element 15 is in the ON state immediately before the power failure, the voltage drop time of part A immediately before the power supply control microcomputer 13 is activated exceeds a predetermined threshold, The comparison result by the voltage detection IC 26 indicates that the input voltage Vin is less than the threshold value Vth. When the switching element 15 is in an off state immediately before a power failure (when the off state has continued for a long time), if the power control microcomputer 13 is activated after either a long power failure or a momentary power failure, the power control microcomputer 13 Since the voltage drop itself in part B just before starting up does not occur (below the threshold Vth from the time of the power failure), the comparison result by the voltage detection IC 26 indicates that the input voltage Vin is less than the threshold Vth.

  Then, the power supply control microcomputer 13 determines on / off of the switching element 15 according to the comparison result by the voltage detection IC 26 (step S2, step S3, step S4).

  In other words, if the comparison result indicates that the input voltage Vin is equal to or greater than the threshold value Vth (instant interruption at the time of power-on before a power failure) (step S2: YES), the power supply control microcomputer 13 turns on the switching element 15 to 50 and the main microcomputer 30 are activated (step S3). Therefore, when the switching element 15 is in the on state immediately before the momentary interruption, if the power supply control microcomputer 13 is activated after returning from the momentary interruption, the electronic apparatus 1 is automatically activated by the activation of the electronic apparatus main body 50 and the main microcomputer 30. Start up automatically. Thereafter, the processing of the power supply control microcomputer 13 ends.

  On the other hand, when the comparison result indicates that the input voltage Vin is less than the threshold value Vth (long-time power outage before power failure, or off before power failure) (step S2: NO), the power supply control microcomputer 13 turns on the switching element 15. First, it waits to respond to the ON output of the power switch 14 (set to the standby state) (step S4 (step S5: NO)). Therefore, when the switching element 15 is in the ON state immediately before the long-term power failure, if the power supply control microcomputer 13 is activated after the recovery from the long-term power failure, the electronic device main body 50 and the main microcomputer 30 are not activated, and the electronic device 1 becomes a standby state (standby state). Furthermore, when the switching element 15 is in the off state immediately before the power failure, if the power supply control microcomputer 13 is activated after the recovery from the long-term power failure or instantaneous interruption, the electronic device main body 50 and the main microcomputer 30 are not activated. The electronic device 1 enters a standby state.

  When the electronic device 1 is in a standby state, the user turns on the power switch 14. Then, a signal to that effect is output from the power switch 14 to the power supply control microcomputer 13 (step S5: YES), and the power supply control microcomputer 13 that has input it turns on the switching element 15 (step S6). If it does so, the electronic device main-body part 50 and the main microcomputer 30 will start, and the electronic device 1 will be in an ON state.

  Subsequently, when the electronic device main body 50 and the main microcomputer 30 are operating before the occurrence of the power failure, the electronic device main body 50 and the main microcomputer when the electronic device main body 50 and the main microcomputer 30 are activated after the recovery from the power failure. The operation of 30 will be described.

  As described above, the main microcomputer 30 overwrites and records the state data in the nonvolatile memory 31 before the occurrence of a power failure. Therefore, the state data is stored in the nonvolatile memory 31 even after a power failure occurs. When the main microcomputer 30 is activated after the recovery from the power failure, the main microcomputer 30 reads the state data from the nonvolatile memory 31 and controls the electronic device main body 50 according to the state data to initialize the electronic device main body 50. Do. As a specific example, the main microcomputer 30 executes processes as shown in the following (A) to (D).

(A) The main microcomputer 30 reads parameters representing the keystone correction, the fitting correction, or both of these states from the nonvolatile memory 31. Then, the main microcomputer 30 outputs the parameters to the video signal processing unit 63 and causes the video signal processing unit 63 to perform keystone correction or fitting correction or both. Then, the video signal processing unit 63 performs keystone correction and / or fitting correction based on the parameters.

(B) The main microcomputer 30 reads luminance data from the nonvolatile memory 31. When the main microcomputer 30 outputs a dimming signal corresponding to the luminance data to the light source control unit 66, the light source control unit 66 causes the light source device 67 to emit light with a luminance corresponding to the dimming signal input from the main microcomputer 30.

(C) The main microcomputer 30 reads the focal length and the focusing distance from the nonvolatile memory 31. The main microcomputer 30 controls the projection lens unit 68 to set the focal length and focusing distance of the projection lens unit 68 to the read focal length and focusing distance.

(D) The main microcomputer 30 reads the decode position from the nonvolatile memory 31. Then, the main microcomputer 30 causes the reader 52 to read the moving image file from the read decoding position, and causes the decoder 53 to execute the decoding process. Then, even after a power failure, the movie is played from the position immediately before the power failure.

  According to the embodiment of the present invention, the following operational effects can be obtained.

(1) Regardless of momentary interruption or long-term power failure, when a power failure occurs, the electronic device main body 50, the main microcomputer 30, the power supply control microcomputer 13, and the voltage detection IC 26 are forcibly shut down. Even so, the delay circuit composed of the capacitor 22 and the resistors 23 to 25 causes the output voltage of the delay circuit to fall with a delay from the output voltage of the first power supply circuit 11. An instantaneous interruption can be detected by the detection IC 26. Then, the switching element 15 is turned on upon detection of the instantaneous interruption, and the electronic device main body 50 and the main microcomputer 30 are activated, so that the electronic apparatus 1 is automatically turned on after the recovery from the instantaneous interruption. Therefore, it is not necessary for the user to turn on the electronic device 1 after a momentary interruption.

(2) A large-capacity capacitor necessary for continuously operating the main microcomputer 30, the power supply control microcomputer 13, the voltage detection IC 26, and the electronic device main body 50 (among these, especially the electronic device main body 50) immediately after the occurrence of a power failure There is no need to provide a backup power source.

(3) If the switching element 15 is in an off state before the occurrence of a power failure, the electronic device main body 50 and the main microcomputer 30 are not activated even if a momentary power interruption or long-term power failure occurs and then recovers. (This is because the voltage B on the electronic device main body 50 side of the switching element 15 is input to the delay circuit including the capacitor 22 and the resistors 23 to 25. That is, the switching element 15 is turned off. This is because the input voltage of the delay circuit does not drop.
Therefore, it is possible to prevent sudden activation when the AC plug is removed and the AC plug is inserted.

(4) Since the state data is recorded in the nonvolatile memory 31 before the occurrence of a power failure, the electronic device main body 50 operates in a state before the occurrence of the instantaneous interruption after returning from the instantaneous interruption.

[Second Embodiment]
FIG. 4 is a block diagram showing an electronic apparatus 1A according to the second embodiment of the present invention.
This electronic apparatus 1A is obtained by changing the voltage drop time comparison unit 20 of the electronic apparatus 1 according to the first embodiment to a voltage drop time measurement microcomputer 120. The electronic device 1A and the electronic device 1 are similarly provided except that the voltage drop time measurement microcomputer 120 and the voltage drop time comparison unit 20 are different. Therefore, portions where the electronic device 1A and the electronic device 1 match are denoted by the same reference numerals, and redundant description is omitted.

  The voltage drop time measurement microcomputer 120 is a voltage drop time comparison unit and also an instantaneous interruption detection unit. The power input part of the voltage drop time measurement microcomputer 120 is connected to the cathode of the rectifying element 121, and the anode of the rectifying element 121 is connected to the power output part of the second power supply circuit 12. A voltage having a predetermined value is applied to the power input unit of the voltage drop time measurement microcomputer 120 by the second power supply circuit 12, and power is supplied from the second power supply circuit 12 to the voltage drop time measurement microcomputer 120. As a result, the voltage drop time measurement microcomputer 120 operates.

  A capacitor (holding unit) 122 is provided to prevent the voltage drop time measurement microcomputer 120 from being forcibly shut down immediately after a power failure. One terminal of the capacitor 122 is connected to the power input part of the voltage drop time measuring microcomputer 120, and the other terminal of the capacitor 122 is connected to the ground. Even if the output voltage of the second power supply circuit 12 falls due to a power failure, the voltage at the power input part of the voltage drop time measurement microcomputer 120 decreases with a delay due to the charging of the capacitor 122. The power supply voltage of the fall time measurement microcomputer 120 is held, and the voltage drop time measurement microcomputer 120 operates.

The terminal ST of the voltage drop time measuring microcomputer 120 is connected to the power input section of the main microcomputer 30, the power input section of the electronic device main body section 50, and the switching element 15 (B section).
The power output unit (A unit) of the AC-DC converter 11 is connected to the terminal STP of the voltage drop time measurement microcomputer 120.

  The voltage drop time measurement microcomputer 120 is an arithmetic processing unit (computer) having a CPU, a RAM, a ROM, and the like. A program is stored in the ROM of the voltage drop time measurement microcomputer 120. The voltage drop time measurement microcomputer 120 reads a ROM program and executes processing according to the program. Specifically, the voltage drop time measurement microcomputer 120 executes an initialization process and a process for measuring the voltage drop time of the part A shown in FIG.

First, the initialization process will be described.
The voltage drop time measurement microcomputer 120 resets the output voltage Vout to low when the voltage drop time measurement microcomputer 120 is activated and, as will be described later, at the rise of the voltage of the A part input to the terminal STP. Thereafter, the voltage drop time measurement microcomputer 120 maintains the output voltage Vout low.

Next, the voltage drop time measurement process will be described.
If a power failure occurs while the voltage drop time measurement microcomputer 120 is activated with the switching element 15 turned on, the output voltage of the AC-DC converter 11 falls, and the power supply control microcomputer 13, the main microcomputer 30, and the electronic device The main body 50 is forcibly shut down, and the switching element 15 is turned off. Then, the voltage at the terminal ST of the voltage drop time measurement microcomputer 120 also falls, whereby the voltage drop time measurement microcomputer 120 starts measuring time. Note that immediately after the power failure, the voltage drop time measurement microcomputer 120 does not shut down due to the transient phenomenon of the capacitor 122.

  Thereafter, when recovering from the power failure, the output voltage of the AC-DC converter 11 rises, and the voltage at the terminal STP of the voltage drop time measurement microcomputer 120 also rises. The voltage drop time measurement microcomputer 120 detects whether the voltage drop of the part A is an instantaneous interruption or a long-term power failure by the rise of the voltage at the terminal STP of the voltage drop time measurement microcomputer 120. Specifically, when the output voltage of the AC-DC converter 11 rises before the time measured during measurement exceeds a predetermined threshold, the voltage drop time measurement microcomputer 120 raises the output voltage Vout to high. On the other hand, when the output voltage of the AC-DC converter 11 rises after the measured time exceeds the predetermined threshold, the voltage drop time measurement microcomputer 120 keeps the output voltage Vout low.

  The process of detecting either an instantaneous interruption or a long-term power failure according to when the output voltage of the AC-DC converter 11 rises is compared with a predetermined time threshold when the output voltage of the AC-DC converter 11 rises. This is equivalent to the process of outputting the comparison result. If the comparison result indicates that the measured time is less than or equal to the predetermined threshold, the voltage drop time measurement microcomputer 120 raises the output voltage Vout to a high level. If the comparison result indicates that the measured time exceeds the predetermined threshold, the voltage drop time is measured. The microcomputer 120 keeps the output voltage Vout low.

  The output voltage Vout represents a determination result (comparison result) by the time measurement process of the voltage drop time measurement microcomputer 120. That is, if the output voltage Vout is high, the determination result indicates that the output voltage of the AC-DC converter 11 has risen (instantaneous interruption) before the measured time exceeds the predetermined threshold. On the other hand, if the output voltage Vout is low, the determination result indicates that the output voltage of the AC-DC converter 11 has risen (long-term power failure) after the measured time exceeds the predetermined threshold.

  Before or after the output voltage of the AC-DC converter 11 rises, the discharge of the capacitor 122 is completed, or when it is about to end, the voltage drop time measurement microcomputer 120 is shut down due to the voltage drop of the power input part of the voltage drop time measurement microcomputer 120. Therefore, the voltage drop time measurement process is terminated halfway.

  Even if a power failure occurs during startup of the voltage drop time measurement microcomputer 120 with the switching element 15 turned off, the voltage at the terminal ST of the voltage drop time measurement microcomputer 120 does not change while remaining sufficiently low. The voltage drop time measurement microcomputer 120 does not execute the voltage drop time measurement process. Since the initialization process is performed, the voltage drop time measurement microcomputer 120 maintains the output voltage Vout low.

  When the power is restored from the power failure, the power supply control microcomputer 13 is activated and executes the process shown in FIG. In step S <b> 1 shown in FIG. 5, the power supply control microcomputer 13 reads the determination result (output voltage Vout) input from the voltage drop time measurement microcomputer 120. The voltage drop time measurement microcomputer 120 executes the initialization process as described above at the rising edge of the voltage at the A part input to the terminal STP.

  In step S2 shown in FIG. 5, if the determination result indicates that the output voltage of the AC-DC converter 11 has risen (instantaneous interruption) before the time measured during measurement exceeds a predetermined threshold (step S2: YES), The process of the power supply control microcomputer 13 proceeds to step S3. On the other hand, if the determination result indicates that the output voltage of the AC-DC converter 11 has risen (long-term power failure) after the measured time exceeds a predetermined threshold (step S2: NO), the processing of the power supply control microcomputer 13 Goes to step S4. Since the process shown in FIG. 5 is the same as that of the first embodiment, a detailed description of the process shown in FIG. 5 is omitted.

  Although the relationship between the determination result and the output voltage Vout may be reversed, in that case, the voltage drop time measurement microcomputer 120 resets the output voltage Vout to high in the initialization process described above.

  In the above description, the output voltage of the second power supply circuit 12 is applied to the power supply input unit of the voltage drop time measurement microcomputer 120. Instead, a primary battery or a secondary battery may be used. That is, the voltage of the primary battery or the secondary battery may be applied to the power input unit of the voltage drop time measurement microcomputer 120, and the voltage drop time measurement microcomputer 120 may thereby operate. Then, the operation of the voltage drop time measurement microcomputer 120 continues even during a power failure. In this case, the primary battery or the secondary battery is a holding unit that holds the power supply voltage of the voltage drop time measurement microcomputer 120.

Also in the present embodiment, since the electronic device 1 is automatically turned on after the recovery from the momentary interruption, it is not necessary for the user to turn on the electronic device 1A after the momentary interruption.
Further, although there is a capacitor 122 as a backup power source, the power consumption of the voltage drop time measurement microcomputer 120 is low and the capacitor 122 does not continue the operation of the electronic device main body 50. Therefore, the capacity of the capacitor 122 can be minimized so as to continue the operation of the voltage drop time measurement microcomputer 120 at the moment of interruption.
Further, if the switching element 15 is turned off before the occurrence of the power failure, the electronic device main body 50 and the main microcomputer 30 are not activated even after the power failure is restored. (This is because the voltage drop time measurement microcomputer 120 starts counting due to the voltage drop of B on the electronic device main body 50 side of the switching element 15).
Therefore, it is possible to prevent sudden activation when the AC plug is removed and the AC plug is inserted.

[Third Embodiment]
FIG. 6 is a block diagram showing an electronic apparatus 1B according to the third embodiment of the present invention.
This electronic device 1B does not include the voltage drop time comparison unit 20 of the electronic device 1 according to the first embodiment. Further, the power input unit of the main microcomputer 30 and the power input unit of the electronic device main body unit 50 are connected to the power control microcomputer 213 so that the voltage of the B section shown in FIG. 6 is monitored by the power control microcomputer 213. . The program in the ROM of the power control microcomputer 213 of the third embodiment is different from the program in the ROM of the power control microcomputer 13 of the first embodiment, and the processing executed by the power control microcomputer 213 of the third embodiment is the first embodiment. This is different from the processing executed by the power control microcomputer 13 of the embodiment. Except for these points, an electronic device 1A and an electronic device 1 are provided in the same manner. Therefore, portions where the electronic device 1A and the electronic device 1 match are denoted by the same reference numerals, and redundant description is omitted.

  A rectifying element 221 and a capacitor 222 are provided to prevent the power supply control microcomputer 213 from being forcibly shut down immediately after a power failure. The power input part of the power control microcomputer 213 is connected to the cathode of the rectifier element 221, and the anode of the rectifier element 221 is connected to the power output part of the second power circuit 12. One terminal of the capacitor 222 is connected to the power input part of the power control microcomputer 213, and the other terminal of the capacitor 222 is connected to the ground. Even if the output voltage of the second power supply circuit 12 falls due to a power failure, the voltage of the power input part of the power supply control microcomputer 213 decreases with a delay due to the charging of the capacitor 222. Therefore, the power supply control microcomputer 213 for a certain time after the power failure. The power supply control microcomputer 213 operates. In addition, the voltage of a primary battery or a secondary battery may be applied to the power input part of the power supply control microcomputer 213, and the power supply control microcomputer 213 may operate | move by it. Then, the operation of the power supply control microcomputer 213 continues even during a power failure.

When the power supply control microcomputer 213 is activated regardless of the instantaneous interruption or the long-term power failure and the power supply control microcomputer 213 is activated, the power supply control microcomputer 213 executes the processes of steps S4, S5, and S6 shown in FIG. That is, first, the power supply control microcomputer 213 waits to respond to the ON output of the power switch 14 (step S4 (step S5: NO)). Therefore, the electronic device 1 is in a standby state.
Then, the user turns on the power switch 14. Then, a signal to that effect is output from the power switch 14 to the power supply control microcomputer 213 (step S5: YES), and the power supply control microcomputer 213 that has input it turns on the switching element 15 (step S6). If it does so, the electronic device main-body part 50 and the main microcomputer 30 will start, and the electronic device 1 will be in an ON state.

The processing of the power supply control microcomputer 213 when the switching element 15 is turned on and the electronic device main body 50 and the main microcomputer 30 are operating will be described.
The power supply control microcomputer 213 monitors the voltage of part B shown in FIG. When a power failure occurs, the output voltage of the AC-DC converter 11 falls, and the main microcomputer 30 and the electronic device main body 50 are forcibly shut down. Even so, the power supply control microcomputer 213 continues to operate by charging the capacitor 222, and the switching element 15 is maintained in the ON state.

  When the voltage at section B falls, the power supply control microcomputer 213 starts measuring time (start of time measuring process). Even if a power failure occurs while the switching element 15 is off, the voltage at the B section does not change while it is sufficiently low, so the power supply control microcomputer 213 does not execute the voltage drop time measurement process.

  If the power is restored from a power failure before the time measured exceeds a predetermined threshold during the voltage drop time measurement process, the output voltage of the AC-DC converter 11 rises and the voltage of the B section rises. Then, the power supply control microcomputer 213 maintains the ON state of the switching element 15. Further, the power supply control microcomputer 213 ends the time measurement and resets the time measurement. When the voltage of the B section rises, the electronic device main body section 50 and the main microcomputer 30 are activated. When the main microcomputer 30 is activated after recovery from a power failure, the main microcomputer 30 reads the state data from the nonvolatile memory 31 and controls the electronic device main body 50 according to the state data to perform the initial setting of the electronic device main body 50.

  On the other hand, if the measured time exceeds a predetermined threshold during the execution of the voltage drop time measurement process, the power supply control microcomputer 213 ends the measurement, and the power supply control microcomputer 213 turns off the switching element 15. Therefore, if the voltage drop time exceeds a predetermined threshold and the power failure is a long-term power failure, the main microcomputer 30 and the electronic device main body 50 will not be activated even if the power failure is restored after that.

  Also in this embodiment, since the operation of the power supply control microcomputer 213 continues even if a power failure occurs, the electronic device 1 is automatically turned on after returning from a momentary interruption. This eliminates the need for the user to turn on the electronic device 1B after a momentary interruption. In the case of a long-term power outage, the switching element 15 is turned off, so that it is possible to prevent sudden activation when the AC plug is removed and the AC plug is inserted. Even if a disturbance or the like occurs during a power failure, the electronic device main body 50 and the main microcomputer 30 are not subjected to excessive current and excessive voltage. Further, the capacitor 222 can be small in capacity.

Although the embodiment of the present invention has been described above, the technical scope of the present invention is not limited to the above-described embodiment, but is defined based on the description in the claims. Furthermore, the technical scope of the present invention also includes an equivalent range obtained by changing modifications not related to the essence of the present invention from the description in the claims.
The invention described in the scope of claims attached to the application of this application will be added below. The item numbers of the claims described in the appendix are as set forth in the claims attached to the application of this application.
[Appendix]
<Claim 1>
An electronic device body,
The voltage drop time from when the voltage of power supplied to the electronic device main body portion drops to when the voltage of power supplied to the electronic device main body portion rises is compared with a predetermined threshold, and the comparison result Voltage drop time comparison unit that outputs
A control unit that reads a comparison result of the voltage drop time comparison unit at the time of activation, and activates the electronic device main body when the comparison result is equal to or less than the threshold; and
An electronic device characterized by that.
<Claim 2>
When the comparison result exceeds the threshold value, the control unit does not activate the electronic device main body,
The electronic device according to claim 1.
<Claim 3>
An electronic device body,
The voltage drop time from when the voltage of power supplied to the electronic device main body portion drops to when the voltage of power supplied to the electronic device main body portion rises is compared with a predetermined threshold, and the comparison result Voltage drop time comparison unit that outputs
A control unit that reads a comparison result of the voltage drop time comparison unit at the time of startup and returns the electronic device main body to a power supply state before the voltage drops when the comparison result is equal to or less than the threshold value; ,
An electronic device characterized by that.
<Claim 4>
The control unit does not activate the electronic device main body when the comparison result exceeds the threshold,
The electronic device according to claim 3.
<Claim 5>
A power supply circuit for supplying power to the electronic device main body and the control unit;
A normally-off switching element provided between a power output unit of the power supply circuit and a power input unit of the electronic device main body;
When the comparison result is less than or equal to the threshold value, the control unit activates the electronic device main body by turning on the switching element,
The electronic apparatus according to claim 1, wherein the electronic apparatus is an electronic apparatus.
<Claim 6>
When the comparison result exceeds the threshold value, the control unit does not start the electronic device main unit by turning off the switching element,
The electronic device according to claim 5, wherein:
<Claim 7>
An electronic device body,
A delay unit that inputs a voltage of power supplied to the electronic device main body, and outputs a voltage that responds with delay to the input voltage;
A comparator that compares the output voltage of the delay unit with a predetermined threshold and outputs the comparison result;
A control unit that reads the comparison result of the comparator at the time of activation, and activates the electronic device main body when the comparison result is equal to or greater than the threshold; and
An electronic device characterized by that.
<Claim 8>
When the comparison result is less than the threshold value, the control unit does not activate the electronic device main body,
The electronic apparatus according to claim 7.
<Claim 9>
A power supply circuit for supplying power to the electronic device main body and the control unit;
A normally-off switching element provided between a power output unit of the power supply circuit and a power input unit of the electronic device main body;
When the comparison result is equal to or greater than the threshold, the control unit activates the electronic device main body by turning on the switching element.
The electronic device according to claim 7 or 8, characterized in that.
<Claim 10>
When the comparison result is less than the threshold value, the control unit does not start the electronic device main unit by turning off the switching element,
The electronic apparatus according to claim 9.
<Claim 11>
An electronic device body,
Whether or not the voltage of the electric power supplied to the electronic device main body has increased before the time counting exceeds a predetermined threshold when the voltage of the electric power supplied to the electronic device main body starts to decrease. A voltage drop time measurement unit that outputs the determination result,
A holding unit for holding the power supply voltage of the voltage drop time measuring unit;
A control unit that reads the determination result of the voltage drop time measurement unit at the time of activation, and activates the electronic device main body when the determination result is not negative,
An electronic device characterized by that.
<Claim 12>
An electronic device body,
A power supply circuit for supplying power to the electronic device main body,
Provided between the power output portion of the power supply circuit and the power input portion of the electronic device main body, a normally-off switching element;
The result of determining whether or not the voltage of the power output unit of the power supply circuit has started to rise before the timed time exceeds a predetermined threshold when the voltage of the power supply input unit of the electronic device main body has dropped. Voltage drop time measurement unit that outputs
A holding unit for holding the power supply voltage of the voltage drop time measuring unit;
A control unit that reads the determination result of the voltage drop time measurement unit at the time of activation, and activates the electronic device main body when the determination result is not negative,
An electronic device characterized by that.
<Claim 13>
When the determination result is NO, the control unit does not activate the electronic device main body,
The electronic device according to claim 11 or 12,
<Claim 14>
A non-volatile storage unit;
An electronic device control unit that records in the storage unit state data representing a state of the electronic device main body before a voltage drop of power supplied to the electronic device main body;
The control unit activates the electronic device control unit together with the electronic device main unit, and the electronic device control unit reads the state data from the storage unit at the time of activation, and the electronic device main unit according to the read state data. Make it work,
The electronic device according to claim 1, wherein the electronic device is an electronic device.
<Claim 15>
An electronic device body,
A power supply circuit for supplying power to the electronic device main body,
A switching element provided between a power output unit of the power supply circuit and a power input unit of the electronic device main body,
Input the voltage of the electric power supplied to the electronic device main body with the switching element turned on, start timing from when the input voltage drops, and after the measured time exceeds a predetermined threshold A control unit that turns off the switching element when the input voltage rises and keeps the switching element on when the input voltage of the power supply input unit of the electronic device main body rises before the timed time exceeds the threshold value When,
A holding unit that holds a power supply voltage of the control unit,
An electronic device characterized by that.
<Claim 16>
A non-volatile storage unit;
The power of the power supply circuit is input on the electronic device main body side with respect to the switching element, and the storage unit stores state data representing the state of the electronic device main body before a voltage drop of power supplied to the electronic device main body Further comprising an electronic device control unit for recording,
The electronic device control unit is activated by an increase in the output voltage of the power supply circuit, reads the state data from the storage unit at the time of activation, and operates the electronic device main body according to the read state data.
16. The electronic apparatus according to claim 15, wherein
<Claim 17>
The electronic device main body is a projection device main body for projecting an image;
The electronic device according to any one of claims 1 to 16, wherein
<Claim 18>
The voltage drop time from when the voltage of power supplied to the electronic device main body part drops to when the voltage of power supplied to the electronic equipment main body part rises is compared with a predetermined threshold, and the comparison result is Output step;
Reading the comparison result at startup, and starting the electronic device main body when the comparison result is equal to or less than the threshold,
A method for controlling an electronic device.
<Claim 19>
To electronic computer,
The voltage drop time from when the voltage of power supplied to the electronic device main body part drops to when the voltage of power supplied to the electronic equipment main body part rises is compared with a predetermined threshold, and the comparison result is A function to output,
Read the comparison result at startup,
A program for realizing the function of starting the electronic device main body when the comparison result is equal to or less than the threshold.

1, 1A, 1B Electronic equipment 11 First power circuit 13 Power control microcomputer (control unit)
DESCRIPTION OF SYMBOLS 15 Switching element 20 Voltage drop time comparison part 21 Rectifier 22 Capacitor 23-25 Resistor 26 Voltage detection IC (comparator)
30 Main microcomputer 31 Non-volatile memory (non-volatile storage unit)
50 Electronic equipment body 120 Voltage drop time measurement microcomputer (Voltage drop time measurement part, Voltage drop time comparison part)
122 Capacitor (holding part)
213 Power control microcomputer (control unit)
222 Capacitor (holding part)

Claims (19)

An electronic device body,
The voltage drop time from when the voltage of power supplied to the electronic device main body portion drops to when the voltage of power supplied to the electronic device main body portion rises is compared with a predetermined threshold, and the comparison result Voltage drop time comparison unit that outputs
A control unit that reads a comparison result of the voltage drop time comparison unit at the time of activation, and activates the electronic device main body when the comparison result is equal to or less than the threshold; and
An electronic device characterized by that. When the comparison result exceeds the threshold value, the control unit does not activate the electronic device main body,
The electronic device according to claim 1. An electronic device body,
The voltage drop time from when the voltage of power supplied to the electronic device main body portion drops to when the voltage of power supplied to the electronic device main body portion rises is compared with a predetermined threshold, and the comparison result Voltage drop time comparison unit that outputs
A control unit that reads a comparison result of the voltage drop time comparison unit at the time of startup and returns the electronic device main body to a power supply state before the voltage drops when the comparison result is equal to or less than the threshold value; ,
An electronic device characterized by that. The control unit does not activate the electronic device main body when the comparison result exceeds the threshold,
The electronic device according to claim 3. A power supply circuit for supplying power to the electronic device main body and the control unit;
A normally-off switching element provided between a power output unit of the power supply circuit and a power input unit of the electronic device main body;
When the comparison result is less than or equal to the threshold value, the control unit activates the electronic device main body by turning on the switching element,
The electronic apparatus according to claim 1, wherein the electronic apparatus is an electronic apparatus. When the comparison result exceeds the threshold value, the control unit does not start the electronic device main unit by turning off the switching element,
The electronic device according to claim 5, wherein: An electronic device body,
A delay unit that inputs a voltage of power supplied to the electronic device main body, and outputs a voltage that responds with delay to the input voltage;
A comparator that compares the output voltage of the delay unit with a predetermined threshold and outputs the comparison result;
A control unit that reads the comparison result of the comparator at the time of activation, and activates the electronic device main body when the comparison result is equal to or greater than the threshold; and
An electronic device characterized by that. When the comparison result is less than the threshold value, the control unit does not activate the electronic device main body,
The electronic apparatus according to claim 7. A power supply circuit for supplying power to the electronic device main body and the control unit;
A normally-off switching element provided between a power output unit of the power supply circuit and a power input unit of the electronic device main body;
When the comparison result is equal to or greater than the threshold, the control unit activates the electronic device main body by turning on the switching element.
The electronic device according to claim 7 or 8, characterized in that. When the comparison result is less than the threshold value, the control unit does not start the electronic device main unit by turning off the switching element,
The electronic apparatus according to claim 9. An electronic device body,
Whether or not the voltage of the electric power supplied to the electronic device main body has increased before the time counting exceeds a predetermined threshold when the voltage of the electric power supplied to the electronic device main body starts to decrease. A voltage drop time measurement unit that outputs the determination result,
A holding unit for holding the power supply voltage of the voltage drop time measuring unit;
A control unit that reads the determination result of the voltage drop time measurement unit at the time of activation, and activates the electronic device main body when the determination result is not negative,
An electronic device characterized by that. An electronic device body,
A power supply circuit for supplying power to the electronic device main body,
Provided between the power output portion of the power supply circuit and the power input portion of the electronic device main body, a normally-off switching element;
The result of determining whether or not the voltage of the power output unit of the power supply circuit has started to rise before the timed time exceeds a predetermined threshold when the voltage of the power supply input unit of the electronic device main body has dropped. Voltage drop time measurement unit that outputs
A holding unit for holding the power supply voltage of the voltage drop time measuring unit;
A control unit that reads the determination result of the voltage drop time measurement unit at the time of activation, and activates the electronic device main body when the determination result is not negative,
An electronic device characterized by that. When the determination result is NO, the control unit does not activate the electronic device main body,
The electronic device according to claim 11 or 12, A non-volatile storage unit;
An electronic device control unit that records in the storage unit state data representing a state of the electronic device main body before a voltage drop of power supplied to the electronic device main body;
The control unit activates the electronic device control unit together with the electronic device main unit, and the electronic device control unit reads the state data from the storage unit at the time of activation, and the electronic device main unit according to the read state data. Make it work,
The electronic device according to claim 1, wherein the electronic device is an electronic device. An electronic device body,
A power supply circuit for supplying power to the electronic device main body,
A switching element provided between a power output unit of the power supply circuit and a power input unit of the electronic device main body,
Input the voltage of the electric power supplied to the electronic device main body with the switching element turned on, start timing from when the input voltage drops, and after the measured time exceeds a predetermined threshold A control unit that turns off the switching element when the input voltage rises and keeps the switching element on when the input voltage of the power supply input unit of the electronic device main body rises before the timed time exceeds the threshold value When,
A holding unit that holds a power supply voltage of the control unit,
An electronic device characterized by that. A non-volatile storage unit;
The power of the power supply circuit is input on the electronic device main body side with respect to the switching element, and the storage unit stores state data representing the state of the electronic device main body before a voltage drop of power supplied to the electronic device main body Further comprising an electronic device control unit for recording,
The electronic device control unit is activated by an increase in the output voltage of the power supply circuit, reads the state data from the storage unit at the time of activation, and operates the electronic device main body according to the read state data.
16. The electronic apparatus according to claim 15, wherein The electronic device main body is a projection device main body for projecting an image;
The electronic device according to any one of claims 1 to 16, wherein The voltage drop time from when the voltage of power supplied to the electronic device main body part drops to when the voltage of power supplied to the electronic equipment main body part rises is compared with a predetermined threshold, and the comparison result is Output step;
Reading the comparison result at startup, and starting the electronic device main body when the comparison result is equal to or less than the threshold,
A method for controlling an electronic device. To electronic computer,
The voltage drop time from when the voltage of power supplied to the electronic device main body part drops to when the voltage of power supplied to the electronic equipment main body part rises is compared with a predetermined threshold, and the comparison result is A function to output,
Read the comparison result at startup,
A program for realizing the function of starting the electronic device main body when the comparison result is equal to or less than the threshold.

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