JP2004037705A - Electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic apparatus capable of displaying information which is necessitated for a user even when its power source is turned off. <P>SOLUTION: An information display part of the electronic instrument is constituted of a display element which has memory properties and can maintain display contents even when power source is suspended and when the power source is to be suspended, a prescribed information is displayed on the display element having memory properties just before the power source is suspended and then the power source is suspended. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device having a display for displaying information, and more particularly to an electronic device capable of displaying information required by a user even when the power is turned off. .
[0002]
2. Description of the Related Art In electronic devices such as a mobile phone, a PDA (Personal Digital Assistant), and an electronic camera, information (text information, image information, and the like) required by a user is provided by electronic display means such as an LCD (liquid crystal display device). it's shown. For example, in an electronic camera, information such as a battery remaining amount display, a free space of a memory card for storing image data, a date and time display, and the like are displayed on a liquid crystal screen or the like as necessary.
[0003]
In such an electronic device, the user wants to check specific information (remaining battery display, memory card free space, date and time display, etc.) while the electronic device is turned off. In this case, it is necessary to operate the power switch of the electronic device to turn on the power supply and display the information on an electronic display means such as an LCD for confirmation.
[0004]
There are also electronic devices that display information using a low-power-consumption electronic display device such as an LCD even when the power switch of the electronic device is OFF, but in a portable electronic device that uses a battery having a relatively small energy capacity as a power source. If the power switch is turned off for a long period of time, the display of the power switch being turned off consumes battery energy. There is a problem that the electronic device cannot be used for a short time, or in the worst case, the electronic device cannot be used because the battery has run out.
[0005]
Therefore, an object of the present invention is to provide an electronic device that consumes no or almost no power even while the power is off and that can continue to display information required by a user.
[0006]
In order to achieve the above object, in an electronic apparatus according to the present invention, a memory display means capable of maintaining display contents without applying power is provided in the electronic apparatus. When the power is turned off, the information at that time is displayed on the memory display means, and then the power of the electronic device is turned off.
[0007]
The electronic device according to the present invention is further characterized in that information to be displayed by the memory display means when the power is turned off can be manually selected in advance.
The electronic device according to the present invention is further characterized in that the information displayed by the memory display means can be switched to other information while the power is off while the power is off.
[0008]
The electronic device according to the present invention is further characterized in that the information displayed by the memory display means is updated at a predetermined timing while the power is off.
[0009]
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a conceptual diagram of the operation of an electronic device to which the present invention is applied. The electronic device 110 includes a memory display unit 120 that can maintain the display content when the power is turned off even when no power is applied. When the power is turned on (the upper part of FIG. 1), the electronic device 110 is used for the purpose of use. The corresponding text information or image information is displayed by the memory display unit 120. For example, image data 130 of a person is displayed in the upper part of FIG.
[0010]
When the power of the electronic device 110 is turned off, the electronic device 110 displays information of a predetermined type among the plurality of types of information by the memory display unit 120, and then turns off the power of the electronic device 110. Therefore, while the power is off (the middle part of FIG. 1), for example, the remaining battery amount information 140 and the memory card free space information 150 are continuously displayed.
[0011]
When the power of the electronic device 110 is turned on again (the lower part of FIG. 1), the electronic device 110 deletes the information displayed by the memory display unit 120 while the power is off, and the electronic device 110 is used in accordance with the purpose of use of the electronic device 110. The text information or the image information is displayed by the memory display unit 120. For example, in the lower part of FIG. 1, image data 160 of a person is displayed.
[0012]
Also, the power of the electronic device 110 is turned on for a moment according to a predetermined timing or operation while the power is off, and the information displayed by the memory display unit 120 is updated and displayed during the power-on period. Or the type of information being displayed is switched and displayed. For example, in the middle part of FIG. 1, the remaining battery amount information 140 and the memory card free space information 150 are switched and displayed while the power is off.
[0013]
2 and 3 are external views (front view and rear view) of an embodiment of an electronic camera 100 as an example of an electronic device to which the present invention is applied. As shown in FIG. 2, a photographing lens 10 for forming a subject image, an optical finder 11 for confirming a photographing screen, a strobe 12 for illuminating the subject at the time of photographing, a brightness of the subject on the front of the electronic camera 100. A photometric circuit 13 is provided for detecting an image. A release button 16 for instructing photographing and a power switch 17 for performing ON / OFF control of the power of the electronic camera 100 are provided on the upper surface. A battery slot 120 for loading a battery for power supply is provided on the side surface.
[0014]
As shown in FIG. 3, on the back of the electronic camera 100, an eyepiece 19 of an optical viewfinder 11, an LCD (left screen) 21 which is a liquid crystal display element having a substantially square screen for displaying text and images, and a text display. A memory display unit (right screen) 22 having a substantially square screen for displaying images and images is arranged, and an upper button 23 and a lower button used for selecting a reproduced image and the like are provided below the right screen 22. 24, a left direction button 25, a right direction button 26, and a decision button 27 are arranged. A lower part of the LCD 21 is a shooting mode button 28 for setting the electronic camera 100 to a shooting mode, and the electronic camera 100 is set to a reproduction mode. And a setting button 31 used to set the type of information displayed on the memory display unit 22 while the power is off. On the left side of the CD 21, a wide button 32 (a function for zooming to the wide side) for operating an optical zoom function (a function for optically zooming the photographing lens 10) and a tele button 33 (a function for zooming to the tele side) are arranged. Have been. On the side surface, a memory card slot 30 for mounting a memory card 77 (removable storage medium) for storing image data is provided.
[0015]
A release button 16, an up button 23, a down button 24, a left button 25, a right button 26, a reset button 27, a shooting mode button 28, a playback mode button 29, a setting button 31, a wide button 32, and a tele button 33 Are operation keys operated by the user.
[0016]
Note that on the surfaces of the left screen 21 and the right screen 22, a so-called touch screen 66 having a function of outputting contact position data corresponding to a position designated by a finger touch operation is arranged and displayed on the screen. It can be used for selecting selection items and image data. The touch screen 66 is made of a transparent material such as glass or resin, and a user can observe an image or text formed inside the touch screen 66 through the touch screen 66.
[0017]
FIG. 4 is a block diagram showing an example of an electric configuration inside the electronic camera 100 shown in FIGS. 2 and 3. Each component includes a data / control bus 51 for transmitting various information data and control data. Connected to each other. The electronic camera 100 includes a block mainly including a photographing control circuit 60 that performs a photographing operation of image data, a block of a memory card 77 that stores and stores an image file, and a screen control circuit that displays image data and related information. A block centered at 92, a block centered on a CPU 50 (central processing unit) that performs overall control of a user interface such as operation keys 65 and control circuits, and a power control circuit 64 that supplies power to each block. It is composed of blocks.
[0018]
The power supply of the electronic camera 100 is a main battery 63 (a primary battery such as an alkaline manganese battery, a nickel-metal hydride battery, a lithium ion battery, or the like) as a main power supply having a large power capacity for operating the electronic camera 100 while the power is on. A secondary battery, a fuel cell, etc.) and a backup battery 62 (lithium button battery, alkaline button battery, etc.) having a small power capacity to cope with processing with a small power load while the power is off. The CPU 50 detects the operation state of the power switch 17 and controls the power control circuit 64 to use the main battery 63 while the power is on and use the backup battery 62 while the power is off. The power is supplied from the backup battery 62 to the CPU 50 and the power control circuit 64 even when the power is off, and the CPU 50 is in the sleep mode (power consumption is reduced by lowering the operation clock or limiting functions) while the power is off. The operation mode is such that the operation key 65, the power switch 17, the card attachment / detachment detection SW80, the battery attachment / detachment detection SW81, and the timer 74 are input. The power supply control circuit 64 measures the voltage of the main battery 63, and when the voltage falls below a predetermined value, performs an interrupt (battery check interrupt) for turning off the power to the CPU 50. Further, the power supply control circuit 64 automatically switches the power supply to the backup battery 62 when the main battery 63 is removed.
[0019]
The CPU 50 is a unit that controls the entire electronic camera 100, and responds to input information from the operation keys 65, the touch screen 66, the power switch 17, the timer 74, the card detachment detection SW80, the battery detachment detection SW81, the photometry circuit 13, and the like. Various instructions are given to the photographing control circuit 60, the screen control circuit 92, the power supply control circuit 64 and the like. The photometric circuit 13 measures the luminance of the subject, and outputs photometric data as the measurement result to the CPU 50. The CPU 50 sets the exposure time and sensitivity of the CCD 55 by the CCD drive circuit 56 according to the photometric data, and controls the aperture value of the aperture 53 by the aperture control circuit 54 via the photographing control circuit 60 according to the set data.
[0020]
The CPU 50 controls the photographing operation via the photographing control circuit 60 in response to the operation of the release button 16 in the photographing mode. When the subject is dark based on the photometric data, the CPU 50 causes the strobe 12 to emit light via the strobe drive circuit 73 at the time of photographing. The timer 74 has a built-in clock circuit, detects date and time information corresponding to the current date and time, supplies shooting date and time information to the CPU 50 at the time of photographing, and performs periodic interruption (timer interruption) and power supply according to set data. An interrupt (power-off timer interrupt) for turning off the CPU is performed to the CPU 50. The CPU 50 controls each unit according to a control program stored in a ROM 67 (read only memory). The EEPROM 68 (electrically erasable and writable ROM) is a non-volatile memory, and stores setting information and the like necessary for the operation of the electronic camera 100. The RAM 70 is a volatile memory and is used as a temporary work area of the CPU 50.
[0021]
The photographing control circuit 60 performs focusing and zooming of the photographing lens 10 by the lens driving circuit 52, controls the aperture 53 by the diaphragm control circuit 54 to control the exposure amount of the CCD 55, and controls the operation of the CCD 55 by the CCD driving circuit 56. I do. The luminous flux from the subject is formed as a subject image on the CCD 55 by the photographing lens 10 through the diaphragm 53 for adjusting the light amount, and the subject image is picked up by the CCD 55. A CCD 55 (charge-coupled device) having a plurality of pixels is a charge accumulation type image sensor for picking up a subject image, and drives an electric image signal corresponding to the intensity of the subject image formed on the CCD 55 by CCD driving. The signal is output to the analog processing unit 57 according to the drive pulse supplied from the circuit 56. The analog processing unit 57 samples the image signal photoelectrically converted by the CCD 55 at a predetermined timing, and amplifies the sampled signal to a predetermined level. An A / D conversion circuit 58 (analog-to-digital conversion circuit) converts the image signal sampled by the analog processing section 57 into digital data by digitizing the image signal, and a photographing buffer memory 59 temporarily stores the digital data.
[0022]
The photographing control circuit 60 repeats the above operation during the photographing mode, and the screen control circuit 92 reads digital data sequentially stored in the photographing buffer memory 59 via the data / control bus 51 and temporarily stores the digital data in the frame memory 69. The through image display operation of converting the digital data into display image data, storing it again in the frame memory 69, and displaying the display image data on the left screen 21 is repeated. Further, the screen control circuit 92 obtains text display information from the CPU 50 as necessary, converts it into display text data, stores it in the frame memory 69, and displays the display text data on the right screen 22. The photographing control circuit 60 detects the focus adjustment state of the photographing lens 10 by analyzing the degree of the high frequency component of the digital data stored in the photographing buffer memory 59, and adjusts the focus of the photographing lens 10 by the lens driving circuit 52 according to the detection result. Do.
[0023]
Upon receiving a shooting instruction from the CPU 50 at the time of release, the shooting control circuit 60 causes the CCD 55 to shoot a subject image via the CCD driving circuit 56, and outputs an image signal generated by the shooting via the analog processing unit 57 and the A / D conversion circuit 58. Then, the image data is temporarily stored in the photographing buffer memory 59 as digital data (raw data). The photographing control circuit 60 converts or compresses the digital data once stored in the photographing buffer memory 59 into a predetermined recording format (such as JPEG) to form image data. The CPU 50 generates an image file by adding predetermined additional information data to the image data, and stores the image file in the memory card 77.
[0024]
In the reproduction mode, the CPU 50 reads out image data from the image file stored in the memory card 77, and the screen control circuit 92 converts the image data into display image data and stores it again in the frame memory 69. The data is reproduced and displayed on the left screen 21.
[0025]
The card attachment / detachment detection SW 80 generates a signal to the CPU 50 by detecting that the memory card 77 has been inserted into or removed from the memory card slot 30. The battery attachment / detachment detection switch 81 detects that the main battery 63 is attached to or detached from the battery slot 120 and generates a signal to the CPU 50.
[0026]
FIGS. 5 and 6 are examples of a memory display unit constituting the right screen 22, and are explanatory diagrams of a memory display unit employing a so-called microcapsule type electrophoresis system. The memory display unit includes a negatively charged black powder 43 (such as carbon particles) and a positively charged white powder 44 (between a transparent plate 41 having a transparent electrode surface and a back plate 40 having a back electrode surface). It has a structure in which a microcapsule 42 enclosing titanium oxide particles or the like is sandwiched, and the display is observed from the transparent plate 41 side. When a positive voltage is applied to the transparent electrode surface side of the transparent plate 41 and a negative voltage is applied to the rear electrode surface side of the back plate 40 as shown in FIG. Since the negatively charged carbon particles 43 attracted to the surface are attracted to the transparent electrode surface, a state where black is displayed is observed from the transparent plate 41 side. Conversely, as shown in FIG. 6, when a negative voltage is applied to the transparent electrode surface side of the transparent plate 41 and a positive voltage is applied to the rear electrode surface side of the back plate 40, the positively charged titanium oxide particles 44 in the microcapsules 42 are formed. Since the negatively charged carbon particles 43 attracted to the transparent electrode surface are attracted to the rear electrode surface, the white state is observed from the transparent plate 41 side. By forming the transparent electrode and the back electrode in a matrix, a two-dimensional display is possible. Further, the titanium oxide particles 44 and the carbon particles 43 in the microcapsules 42 are still adsorbed to the respective plate sides even after the application of the voltage to the transparent electrode surface and the back electrode surface. Will be maintained. Other display devices using a ferroelectric liquid crystal, a cholesteric liquid crystal, or a polymer dispersed liquid crystal, a twisting ball device developed by Xerox, and an In-Plane type developed by Canon Inc. A display element having a nonvolatile display function such as an electrophoretic display element can be used.
[0027]
FIG. 7 shows the data structure of an image file stored in the memory card 77. As shown in FIG. 7, each image file stored in the memory card 77 is composed of image data and additional information data. The additional information data includes image identification information (file name), shooting data indicating various settings at the time of shooting, and shooting date and time data. FIG. 8 is a diagram showing a configuration of information stored in the EEPROM 68, information for holding the power ON state and the OFF state of the electronic camera 100, information for specifying display contents when the power is off, and power supply such as battery voltage. The information includes information for holding a state, information for holding a cause of turning off the power, information for holding a state such as a data capacity and a free space of the memory card 77, and the like.
[0028]
FIG. 9 is a main flow showing the flow and relationship of the operation of the electronic camera 100 in the above-described embodiment. When the power switch 17 is operated to turn on the power, the photographing mode subroutine of S20 is executed and the photographing is enabled. When the release button 16 is operated in the shooting mode, a release interrupt processing subroutine in S30 is executed, and a shooting operation is performed. When the playback mode button 29 is operated during the shooting mode, the mode switching interrupt processing subroutine of S40 is executed, and the playback mode subroutine of S50 is executed, and the image file stored in the memory card 77 is read and displayed on the left screen 21. Is done. Conversely, when the photographing mode button 28 is operated during the reproduction mode, the mode switching interrupt processing subroutine of S40 is executed, and the process shifts to the photographing mode subroutine of S20. Further, when the setting button 31 is operated in the photographing mode or the reproduction mode, a setting interrupt processing subroutine for setting information to be displayed on the right screen 22 while the power is off is executed. The above is the processing operation during power-on.
[0029]
The power control interrupt processing subroutine of S70 is activated by power control factors (operation of the power switch 17, generation of a power-off timer interrupt, removal of a battery) during power-on and power-off, and includes power control factors including display processing during power-off. Is performed according to. In the timer interrupt processing subroutine of S80, the timer 74 is activated at predetermined time intervals during power ON and power OFF, and performs predetermined processing including display processing during power OFF. When the operation key 65 is operated while the power is on and the power is off, an operation key interrupt processing subroutine in S90 is executed, and predetermined processing including display processing while the power is off is performed.
[0030]
FIG. 10 is a detailed flowchart of the photographing mode subroutine. When activated in S20, the process of S201 is repeated. In S201, image data generated by the CCD 55 sequentially or manually or automatically under camera setting conditions is displayed as a through image on the left screen 21 as shown in FIG. 11, and the camera setting conditions and date / time information data (time data) at that time are displayed. Text is displayed on the right screen 22.
[0031]
FIG. 12 is a detailed flowchart of the release interrupt processing subroutine. When the camera is started in S30, it is checked in S301 whether the mode is the shooting mode. If not, the process proceeds to S304. In the case of the photographing mode, the photographing operation is executed under the photographing conditions set by the user or the camera in S302, and photographing data and time data are added to the image data obtained in S303 and stored in the memory card 77. In S304, the power-off timer is reset, and the process returns in S305. The power-off timer is a timer for realizing a function of automatically turning off the power when no operation is performed on the electronic camera 100 for a predetermined time while the power is on. The electronic camera 100 is started by counting time (counting up), and the power of the electronic camera 100 is automatically turned off. With this function, battery consumption can be prevented. Resetting the power-off timer in S304 means resetting the time measurement data for the power-off timer of the timer 74.
[0032]
FIG. 13 is a detailed flowchart of the mode switching interrupt processing subroutine. When the camera is started by operating the shooting mode button 28 or the playback mode button 29 in S40, the power OFF timer is reset in S401, and the button operated in S402 is changed to the shooting mode button. It is checked whether it is 28 or not. If it is the shooting mode button 28, the reproduction mode is ended, and the flow goes to the shooting mode subroutine of S20. If the operated button is not the photographing mode button 28, the photographing mode is ended, and the flow shifts to the reproduction mode subroutine of S50.
[0033]
FIG. 14 is a detailed flowchart of the reproduction mode subroutine, and when started in S50, the processing of S501 is repeated. In step S501, image data stored in the memory card 77 is selected and read out according to the operation of the left button 25 and the right button 26, and is reproduced and displayed on the left screen 21 as shown in FIG. Is displayed on the right screen 22. In the playback mode immediately after the power is turned on, the latest image data is displayed. Thereafter, the image data having the older time data is sequentially displayed according to the operation of the left button 25, and the time is sequentially displayed according to the operation of the right button 26. Display new image data of the data.
[0034]
FIG. 16 is a detailed flowchart of the setting interrupt processing subroutine activated by the operation of the setting button 31. When the subroutine is activated in S60, as shown in FIG. To be displayed. The display contents when the power is turned off are the contents of the information displayed on the right screen 22 even when the power of the electronic camera 100 is turned off. Here, the battery state (display of the remaining amount of the battery) and the memory card state (the empty state of the memory card) are used. Capacity) can be selected. In step S602, the display contents when the power of the EEPROM 68 is turned off are set according to the contents selected by the user. In step S603, the power-off timer is reset, and the process returns in step S604.
[0035]
FIG. 18 is a detailed flowchart of a power control interrupt processing subroutine that is started by the occurrence of a power control factor (operation of the power switch 17, generation of a power OFF timer interrupt, removal of a battery). When the subroutine is started in S70, the power is supplied from the EEPROM 68 in S701. It is checked whether the power is on. If the power is not on, that is, if the power is off, the process proceeds to the processing during power off shown in S720 and subsequent steps in FIG. If the power is ON in S701, it is checked in S702 whether the power control factor is a predetermined factor (operation of the power switch 17, count up of the power OFF timer, battery check, failure), and if it is the predetermined factor, The processing after S703 is performed to turn off the power. In step S703, the power supply state and the memory card state are detected, and the power supply OFF state information and the power supply OFF information are written into the EEPROM 68, and the power supply state is set according to the power supply OFF display information set in the EEPROM 68. The status or memory card status is displayed on the right screen 22. The display of the power supply state is differently displayed as follows depending on the cause of the power supply OFF.
[0036]
FIG. 20 shows an example in which a normal power supply state is displayed on the right screen 22, and the remaining battery level is graphically displayed in the battery mark. FIG. 21 is a display example of a power state when the power is turned off by a battery check. The memory card status is displayed as shown in FIGS. FIG. 22 is a display example of a normal memory card state, in which the total storage capacity and the free storage capacity are visually displayed by a pie chart. FIG. 23 shows a display when the memory card 77 has no free space. FIG. 24 is a display example when the memory card 77 is not inserted in the memory card slot 30. Even if the display content at the time of power OFF set in the EEPROM 68 is a memory card state, if the cause of the power OFF is a battery check, the display of FIG. 21 is performed. Further, regardless of the display contents at the time of power-off set in the EEPROM 68, when the cause of the power-off is a failure, the fact that the failure is present is displayed on the right screen 22 as shown in FIG.
[0037]
In step S704, an interrupt due to a predetermined factor (power OFF timer, release button, mode switching, setting, battery check, failure) is prohibited, and the power supply control circuit 64 is instructed to power off in step S705. Upon receiving the power-off instruction, the power control circuit 64 switches off the main battery 63 and switches to the backup battery 62. A sleep mode is entered in S709.
[0038]
If the power control factor is not a predetermined factor (operation of the power switch 17, count up of the power OFF timer, battery check, failure) in S702, it is checked whether the power control factor is the removal of the main battery 63, and the battery is not removed. In this case, the process returns in S707. If the battery is to be removed, the backup battery 62 is temporarily applied to the EEPROM 68, the memory card 77, and the right screen 22 by the power supply control circuit 64 in S708, the memory card state is read, and the memory card state, the power OFF factor, and the power supply The OFF information is written in the EEPROM 68, and the fact that the power is turned off by removing the power is displayed on the right screen 22 as shown in FIG. 26, and the backup battery for the EEPROM 68, the memory card 77 and the right screen 22 is displayed by the power control circuit 64. 62, the application is temporarily stopped, and a sleep mode is entered in S709. When the backup battery 62 is temporarily applied to the right screen 22, the backup battery 62 is also temporarily applied to the screen control circuit 92 and the frame memory 69.
[0039]
If it is determined in step S701 that the power is off, it is checked in step S720 in FIG. 19 whether the main battery 63 has been attached or detached or the memory card 77 has been attached or detached. In this case, in step S721, the backup battery 62 is temporarily applied to the EEPROM 68, the memory card 77, and the right screen 22 by the power supply control circuit 64, the memory card state and the power state are read, and the memory card state and the power state are written to the EEPROM 68. At the same time, the power supply state or the memory card state is displayed on the right screen 22 according to the display contents during power OFF set in the EEPROM 68, and the backup battery to the EEPROM 68, the memory card 77 and the right screen 22 is provided by the power supply control circuit 64. 62, the application is temporarily stopped. To return to the sleep mode.
[0040]
In S720, if both the main battery 63 and the memory card 77 are not attached or detached, it is checked in S722 whether the main battery 63 is attached and the battery voltage is equal to or higher than a predetermined value, and whether or not the main battery 63 is attached. Alternatively, if the battery voltage of the main battery 63 has not reached the predetermined value, the process returns to the sleep mode in S723 without turning on the power. If the main battery 63 is mounted and the battery voltage is equal to or higher than the predetermined value, an instruction to turn on the power is issued to the power control circuit 64 in S724. The power supply control circuit 64 receives the instruction to turn on the power supply, and switches the power supply from the backup battery 62 to the main battery 63. In step S725, the memory card state and the power state are read, and the memory card state, the power state, and the power-on information are written in the EEPROM 68. In step S726, the power-off timer is reset. In step S727, interrupts for all factors are permitted. To jump to the shooting mode subroutine of S20.
[0041]
FIG. 27 is a detailed flowchart of the timer interrupt processing subroutine. When the power is started at predetermined time intervals in S80, it is checked in step S801 whether the power is off based on the data in the EEPROM 68. When the current power state is detected, and the detected information has changed from the previous power state information stored in the EEPROM 68, the detected power state information is stored in the EEPROM 68. In step S803, a failure diagnosis of the electronic camera 100 is performed. In step S804, it is checked whether a failure has been found. If a failure has been found, the process jumps to power control interrupt processing in step S70. If no failure is found, the process returns in S811.
[0042]
If the power is off in S801, the current power state is detected in S805, the backup battery 62 is temporarily applied to the EEPROM 68 by the power control circuit 64, and the previous power state is read from the EEPROM 68. It is checked whether the power state detected in S806 has changed from the previous power state. If the power state has not changed, the process proceeds to S810. If the power state has changed, information on the detected power state is written in the EEPROM 68 in S807. In step S808, it is checked whether or not the display contents during power-off stored in the EEPROM 68 is the information of the power state. If the information is not the information of the power state, the process proceeds to step S810. If the information is the information of the power state, the process proceeds to step S809. 64, the backup battery 62 is temporarily applied to the right screen 22, information of the power state detected this time is displayed on the right screen 22, and the power supply control circuit 64 temporarily applies the backup battery 62 to the right screen 22. In step S810, the application of the backup battery 62 to the EEPROM 68 by the power supply control circuit 64 is temporarily stopped, and the process returns to the sleep mode in step S811.
[0043]
FIG. 28 is a detailed flowchart of the operation key interrupt processing subroutine. In S90, the operation of the up button 23, the down button 24, the left button 25, the right button 26, the enter button 27, the wide button 32, and the tele button 33 is performed. In step S901, it is checked whether the power is off based on the data in the EEPROM 68. If the power is off, it is checked whether the operation keys 65 operated in step S902 are the up button 23 and the down button 24. If the button is not the up button 23 or the down button 24, the process returns to the sleep mode in S914. If the button is the up button 23 or the down button 24, the backup battery 62 is stored in the EEPROM 68 and the right screen 22 by the power control circuit 64 in S903. Is temporarily applied, and the electric power stored in the EEPROM 68 is According to the status information or the memory card status information, the content of the information opposite to the content of the information currently displayed on the right screen 22 is displayed on the right screen 22 (for example, if the power supply status is currently displayed, the memory card status is displayed). Is displayed), the application of the backup battery 62 to the EEPROM 68 and the right screen 22 by the power supply control circuit 64 is temporarily stopped, and the process returns to the sleep mode in S914.
[0044]
If it is determined in step S901 that the power is not turned off based on the data in the EEPROM 68, that is, the power is turned on, the power-off timer is reset in step S904, and whether or not the camera is in the shooting mode is checked in step S905. It is checked whether the operated operation key 65 is the wide button 32. If the operation key 65 is the wide button 32, optical zooming is performed to the wide side by a predetermined amount in S907, and the process returns in S914. If it is not the wide button 32, it is checked whether or not the operation key 65 operated in S908 is the tele button 33. If it is not the tele button 33, the process returns in S914. If it is the tele button 33, it returns to the tele side by a predetermined amount in S909. Optical zooming is performed, and the process returns in S914.
[0045]
If it is determined in step S905 that the operation mode is not the shooting mode, that is, the playback mode, the operation key 65 operated in step S910 is checked to see if it is the left button 25. If the operation key 65 is the left button 25, it is displayed on the left screen 21 in step S911. The image data immediately before (ie, the image data in the shooting order immediately before) the read image data is read from the memory card 77, reproduced and displayed on the left screen 22, and the process returns in S914. If it is not the left button 25, it is checked whether the operation key 65 operated in S912 is the right button 26. If it is not the right button 26, the flow returns to S914. If it is the right button 26, it returns to the left screen 21 in S909. The next image data of the displayed image data (the image data whose shooting order is one after) is read from the memory card 77, reproduced and displayed on the left screen 22, and the process returns in S914.
[0046]
In the above-described embodiment (FIGS. 1 to 28), when a factor at the time of power OFF occurs, the electronic camera 100 displays the power state (remaining battery level) or memory card state (empty capacity) at that time in the memory display section. , The power is turned off after the display, so that the user can instantaneously check the power state (remaining battery level) or the memory card state (free space) without turning on the power even when the power is off.
[0047]
In the above embodiment (FIGS. 1 to 28), the setting button 31 is used to display either the power state (remaining battery level) or the memory card state (free capacity) on the memory display unit when the electronic camera 100 is turned off. Thus, even when the area of the display screen of the memory display unit is small, necessary information can be confirmed while the power is off.
[0048]
In the above-described embodiment (FIGS. 1 to 28), the contents (power state or memory card state) displayed by the memory display unit while the power of the electronic camera 100 is OFF are displayed using the up button 23 and the down button 23 during power OFF. By operating the direction button 24, the content can be switched to the other content and displayed on the memory display. Therefore, when the user switches the content displayed on the memory display while the power is off, the user turns on the power. There is no need to switch to the required information instantaneously for confirmation.
[0049]
In the above embodiment (FIGS. 1 to 28), the content (power state or memory card state) displayed by the memory display unit while the power of the electronic camera 100 is OFF is detected at a predetermined cycle even while the power is OFF. When the display contents change, the display contents are updated, so that the user does not need to turn on the power even when confirming the latest information of the contents displayed on the memory display unit.
[0050]
In the above embodiment (FIGS. 1 to 28), the electronic camera 100 displays the cause of the power OFF (battery voltage drop, failure, battery removal) on the memory display section while the power is OFF. Even when the power supply 100 does not start, the cause can be surely known.
[0051]
In the above embodiment (FIGS. 1 to 28), the electronic camera 100 detects the attachment / detachment of the main battery 63 and the attachment / detachment of the memory card 77 even when the power is turned off. Since the displayed content is updated, the user can confirm the latest information on the power supply state or the memory card state on the memory display unit without having to turn on the power supply.
[0052]
In the above embodiment (FIGS. 1 to 28), the electronic camera 100 does not have a memory function but has a high responsiveness on the left screen 21 (such as a liquid crystal display element). It has a right screen 22, displays image data on the left screen 21 (such as a liquid crystal display element), and displays two texts or icons on the right screen 22. Through images or moving images can be displayed, and text and icons can be displayed with low power consumption during power-on and power-off.
(Explanation of Modifications) The present invention is not limited to the embodiments described above, and various modifications and changes are possible.
[0053]
In the above-described embodiment (FIGS. 1 to 28), the power state or the memory card state is displayed by the memory display unit while the power is off. However, the information to be displayed while the power is off is not limited to this. Various information can be displayed. For example, specific image data (the last image data, the image data specified by the user, and the image data randomly determined when the power is turned off) are selected from the image data captured by the electronic camera 100 and stored in the memory card. The information may be displayed on the memory display unit while the power is off. By displaying the last captured image data while the power is off, the user can remember when the electronic camera was last used, and can replace the main battery and the memory card as necessary. If the image data specified by the user is displayed while the power is off, the screen of the memory display unit can be used for viewing like a photo stand while the power is off. In addition, calendar information is stored in the EEPROM 68, and when the power is turned off, the calendar information is read out from the EEPROM and displayed on the memory display unit. If the determined image data is displayed together with the calendar information while the power is off, a calendar in a unique format is displayed on the screen while the power is off, and can be used as a desk calendar. Further, the image data displayed at a predetermined period may be switched by a timer while the power is off. With this configuration, the user does not get bored even when the image data displayed by the memory display unit is used for viewing while the power is off.
[0054]
In addition to the image data, information about shooting may be displayed by the memory display unit while the power is off. For example, if the exposure calculation table indicating the relationship between the shutter speed and the aperture with respect to the luminance is displayed on the memory display unit while the power is off, the user frequently views the exposure calculation table. Then, the user becomes accustomed to using the electronic camera by manually determining the aperture value and the shutter speed value. In addition, if the photographing data (shutter speed, aperture, etc.) at the time of the last photographing by the electronic camera is displayed on the memory display unit while the power is off, the photographing data can be recorded the next time the same photographing is performed. You don't have to. If the electronic camera has a built-in positioning means such as a GPS, the data of the shooting location is detected by the positioning means at the time of shooting and added to the image data and stored. If the information on the place where the operation is performed is displayed on the memory display unit, the user can remember where the electronic camera was last used, and can replace the main battery and the memory card as necessary. By displaying the date and time of the last shooting or the date and time when the power was turned off on the memory display while the power is off, the user can remember when the electronic camera was last used. You can swap batteries and memory cards.
[0055]
If a list of identification information (file names) of the image data stored in the memory card is displayed on the memory display unit while the power is turned off, the user can switch the power on as needed based on the list before turning on the power. You can change the memory card. When the electronic camera can mount a plurality of types of storage media (for example, PC card, SD card, memory stick, smart media, etc.), the type of storage medium mounted on the electronic camera is detected, and If the type is displayed on the memory display section while the power is off, the user can change the storage medium as necessary before turning on the power. If information about the owner of the electronic camera (name, contact information, etc.) and identification information of the electronic camera (manufacturer name, model name, serial number) are displayed on the memory display while the power is off, the electronic camera can be used. Even if the electronic camera is lost, the electronic camera can be easily specified, and confusion can be easily prevented when a plurality of the same types of electronic cameras exist.
[0056]
In the above-described embodiment (FIGS. 1 to 28), the power state or the memory card state is switched and displayed by the memory display unit while the power is off, but as shown in FIG. The state of the memory card may be simultaneously displayed on the memory display unit. This eliminates the need for the user to set which of the power state and the memory card state is to be displayed on the memory display while the power is off.
[0057]
In the above embodiment (FIGS. 1 to 28), the power state or the memory card state is displayed on the memory display while the power is off, but nothing is displayed on the memory display while the power is off. A selection may be made. In this way, the user can more clearly confirm the power-off state of the electronic camera, and when the mode in which nothing is displayed is set, the power including the backup battery of the electronic camera is turned off while the power is off. If all are turned off, the backup battery can be prevented from being consumed when the electronic camera is stored without being used for a long time.
[0058]
In the above embodiment (FIGS. 1 to 28), the CPU enters the sleep mode while the power is off, and supplies power to the CPU and the like with the backup battery. The supply may be performed from the main battery. By doing so, there is no need to provide a backup battery, so that the system can be simplified and the electronic camera can be downsized.
[0059]
In the above embodiment (FIGS. 1 to 28), the CPU enters the sleep mode while the power is off, and supplies power to the CPU and the like with the backup battery. All of them may be turned off. With this configuration, since no power is consumed when the power is turned off, it is possible to prevent the backup battery from being consumed and to eliminate the need for mounting the backup battery.
[0060]
In the above embodiment (FIGS. 1 to 28), the electronic camera is turned on (photographing mode) by operating the power switch while the power is off, but is turned off by counting up the power off timer. In this case, the state of the electronic camera 100 immediately before the power is turned off (shooting mode / playback mode, shooting setting data / playback image data, etc.) is stored in the EEPROM, and the fact that the power is turned off by the power-off timer is indicated by the memory display unit. In addition to the display, it is also possible to return to the power-on state immediately before the power-off stored in the EEPROM in response to the operation of any of the operation keys. In this way, even if the power is turned off by the power-off timer regardless of the user's intention, the user can recognize that the power is turned off by the power-off timer and the electronic camera immediately before the power-off timer is activated. Can be returned to the state without trouble.
[0061]
In the above embodiment (FIGS. 1 to 28), various information is displayed on the memory display unit while the power of the electronic camera is turned off. However, the present invention is not limited to the electronic camera, and the memory display unit is not limited thereto. The present invention can be applied to any electronic device provided. For example, if the display screen of a mobile phone is configured by a memory display unit, and the reception state (such as the intensity of a received radio wave) is periodically updated and displayed by the memory display unit even when the power is off, the power is turned on. This makes it possible to check the reception state without power consumption and reduce power consumption.
[0062]
In the above embodiments (FIGS. 1 to 28), the electronic camera uses a battery as a main power supply. However, the present invention can be applied to an electronic device that supplies power from an external power supply via a power cable. For example, in an electronic device using an external power supply as a main power supply, if various information is displayed on the memory display unit while the power is off, various information can be confirmed without power consumption while the power is off, so that the power cost can be reduced. .
[0063]
In the above embodiment (FIGS. 1 to 28), the display of the microcapsule type electrophoresis system shown in FIGS. 5 and 6 is used as the memory display unit, but the power OFF state continues for a long time. Then, since the display quality of the information displayed on the memory display unit may be degraded while the power is off, the power is applied to the memory display unit at predetermined intervals, and the same as the information displayed at that time is applied. The display content may be displayed again on the memory display unit.
[0064]
In the above embodiment (FIGS. 1 to 28), the display element of the microcapsule type electrophoresis type shown in FIGS. 5 and 6 is used as the memory display section, but the positively charged white powder 44 (titanium oxide) is used. Instead of the particles, non-black particles having a luminous property and positively charged may be used. Non-black particles having luminous (luminous) properties include sulfide (zinc sulfide, copper sulfide, etc.), aluminate chloride (alkaline earth aluminate), aluminum oxide / strontium oxide (aluminum oxide) An afterglow phosphor such as strontium carbonate) can be used. In this way, the user can check the information on the memory display element during power-on and power-off without power consumption even at night. A positively charged microbead formed by kneading the luminous substance into plastic or glass of a desired color (including transparency) and forming it into microspheres is used instead of the microcapsule-type electrophoretic white powder 44. You may. In this way, the shape of the microbeads can be made uniform, so that the performance variation of the display device of the microcapsule type electrophoresis method can be suppressed.In addition, since the phosphorescent material is not directly exposed to the environment, the degradation of the phosphorescent material can be prevented. Can be prevented.
[0065]
As described above, in the electronic device according to the present invention, when the power is turned off, the information required by the user is displayed by the memory display means and then the power is turned off. Even when the power is off, desired information can be confirmed without the need to turn on the power supply, and necessary measures (battery replacement, memory card replacement, etc.) can be performed in advance according to the result of the confirmation. When the power is turned on, the battery runs out and the memory card runs out of space at the time of use. When the battery and the memory card are replaced in a hurry, the use timing of the electronic device is lost (for example, when an electronic camera is used. You won't miss a photo opportunity when shooting).
[0066]
Further, in the electronic device according to the present invention, since the content of the information displayed by the memory display means can be automatically selected by the user or automatically while the power is turned off, it is possible to cope with a case where there are a plurality of types of information required by the user. At the same time, since the display screen of the memory display means can be reduced, the size and cost of the electronic device can be reduced.
[0067]
Also, in the electronic device according to the present invention, the content of information displayed by the memory display means can be switched manually or automatically while the power is off, so that there are a plurality of types of information required by the user. And the display screen of the memory display means can be made smaller, so that the size and cost of the electronic device can be reduced.
[0068]
Further, in the electronic device according to the present invention, since the content of the information displayed by the memory display means is updated at a predetermined timing while the power is off, the user can surely know the change of the information which has occurred while the power is off. . For example, even when the remaining battery level is lower than the power-off time due to factors such as leak current or temperature change, the changed remaining battery level is displayed by the memory display means. Actions such as battery replacement can be taken.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram of the present invention.
FIG. 2 is an external view (front view) of the electronic camera.
FIG. 3 is an external view (a rear view) of the electronic camera.
FIG. 4 is a block diagram illustrating an electric configuration of the electronic camera.
FIG. 5 is an explanatory diagram of a memory display unit.
FIG. 6 is an explanatory diagram of a memory display unit.
FIG. 7 is a configuration diagram of data of an image file.
FIG. 8 is a configuration diagram of data in an EEPROM.
FIG. 9 is a main flowchart.
FIG. 10 is a flowchart of a subroutine.
FIG. 11 is a display example of a screen.
FIG. 12 is a flowchart of a subroutine.
FIG. 13 is a flowchart of a subroutine.
FIG. 14 is a flowchart of a subroutine.
FIG. 15 is a display example of a screen.
FIG. 16 is a flowchart of a subroutine.
FIG. 17 is a display example of a screen.
FIG. 18 is a flowchart of a subroutine.
FIG. 19 is a flowchart of a subroutine.
FIG. 20 is a display example of a screen.
FIG. 21 is a display example of a screen.
FIG. 22 is a display example of a screen.
FIG. 23 is a display example of a screen.
FIG. 24 is a display example of a screen.
FIG. 25 is a display example of a screen.
FIG. 26 is a display example of a screen.
FIG. 27 is a flowchart of a subroutine.
FIG. 28 is a flowchart of a subroutine.
FIG. 29 is a display example of a screen.
[Explanation of symbols]
10 Shooting lens
21 LCD (left screen)
22 Memory display (right screen)
50 CPU
55 CCD
62 Backup battery
63 Main Battery
64 Power supply control circuit
77 Memory Card
92 Screen control circuit
100 electronic camera
110 PDA

Claims (12)

A power supply that supplies power,
Power supply control means for controlling stop of power supply of the power supply,
A display means for displaying information, wherein the display information can be changed under the power supply of the power supply, and the memory display function can maintain the display information when the power supply is stopped without the power supply of the power supply. Display means having
An electronic apparatus, comprising: a display control unit that causes the display unit to display predetermined information immediately before stopping the power supply by the power control unit. 2. The electronic device according to claim 1, wherein the power source is a battery that is detachable from the electronic device, and the predetermined information is information on a remaining amount of the battery. 2. The electronic device according to claim 1, further comprising a storage unit for storing information, wherein the predetermined information is information on a free space of the storage unit. 2. The electronic device according to claim 1, further comprising: an imaging unit configured to generate image information by photographing; and a storage unit configured to store the image information, wherein the predetermined information is image information stored in the storage unit. Electronic equipment characterized. 2. The electronic device according to claim 1, wherein the predetermined information is information on a time at which the power supply control unit stops power supply. 2. The electronic device according to claim 1, wherein the predetermined information is personal information on an owner of the electronic device. 2. The electronic device according to claim 1, wherein the power supply control unit stops the power supply of the power supply based on an occurrence of any one of a plurality of power supply stop factors, and the predetermined information includes the power control unit. 3. An electronic device characterized in that the information is information for specifying a factor that caused the power supply to be stopped. 2. The electronic device according to claim 1, wherein the predetermined information is manually selectable. 2. The electronic device according to claim 1, wherein the display control unit switches the information displayed on the display unit when the power supply is stopped to another information during the power supply stop period of the power supply, and causes the display unit to display the information. Electronic equipment characterized by the above. 2. The electronic device according to claim 1, wherein the display control unit periodically updates the content of the information displayed on the display unit when the power supply is stopped during the power supply stop period of the power supply, and displays the information on the display unit. An electronic device characterized by displaying. 11. The electronic device according to claim 1, wherein the display control unit periodically displays the same information content as the information content displayed by the display unit during a power supply stop period of the power supply. An electronic device, wherein the electronic device is displayed again. The electronic device according to claim 1, wherein the display unit having the memory function has a light storing property.

Images