JP2011048473A - Display device and control program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device and a control program for displaying on a screen the number of times which allows an image to be rewritten, only when the number of times hardly fluctuates. <P>SOLUTION: The voltage of a battery is detected (S11), and when the detected voltage of the battery is not equal to or less than 3.5 V (S12: NO), the number of times which allows the image to be rewritten is not displayed on a display panel even when the rewriting instruction of a screen is input. Whereas, when the voltage of the battery is equal to or less than 3.5 V (S12: YES), the temperature of the battery is detected (S17). Then, the number of times which allows the image to be rewritten is determined based on the voltage of the battery and the temperature of the battery (S19), and displayed on a display panel (S21). Then, when the rewriting instruction of the screen is input (S23: YES), the rewritable number of times is updated (S33 or S36). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a display device and a control program. Specifically, the present invention relates to a display device and a control program for displaying the number of times that an image can be rewritten.

  Conventionally, a display device that detects the remaining battery level and displays the number of times that an image can be rewritten is known. For example, in the display device described in Patent Document 1, the voltage of the battery is detected, and the usable remaining amount is specified from the detected voltage. Then, the number of times that the image can be rewritten is calculated and displayed on the screen based on the specified usable remaining amount.

Japanese Patent Laying-Open No. 2005-164672

  Generally, when the remaining battery charge is sufficiently large, the amount of decrease in battery voltage that is reduced when an image is rewritten is much smaller than when the remaining battery charge is small. In the display device described in Patent Document 1, the remaining battery charge is specified by detecting the battery voltage. When the remaining battery charge is sufficiently large, the amount of decrease in the battery voltage that decreases when the image is rewritten is very small, and it is difficult to accurately specify the number of times that the image can be rewritten. For this reason, the number of times displayed in the image often fluctuates, and there is a problem that the user may be confused.

  The present invention has been made to solve the above problems, and a display device and a control capable of displaying the number of times on a screen only when the number of times that an image can be rewritten is small. The purpose is to provide a program.

  In order to achieve the above object, the display device according to claim 1 requires power when rewriting an image being displayed, and is non-volatile capable of retaining the image even when power supply is cut off. A display device that operates using a battery as a power source, the display control unit controlling the display unit and displaying the image on the display unit, and the remaining amount detection detecting the remaining amount of the battery And a remaining number detection means for determining a rewrite count that is the number of times that the image can be rewritten based on the remaining battery level detected by the remaining charge detection means. When the remaining amount of the battery detected by the means is less than or equal to a predetermined remaining amount, the rewrite count determination means starts determining the rewritable count, and the display control means When the remaining amount of the battery detected by the remaining amount detecting unit is larger than the predetermined remaining amount, the rewrite number determining unit does not start determining the rewriteable number. Features.

  According to a second aspect of the present invention, in addition to the configuration of the first aspect of the invention, the display device has an input means for inputting the image rewrite instruction, and the image rewrite instruction via the input means. After the input, the first determination means for determining whether or not the image rewriting instruction is input again within the first threshold which is a time threshold, and the first determination means via the input means When it is determined that the image rewriting instruction is input again within the first threshold after the image rewriting instruction is input, the first rewriting number determined by the rewriting number determining means is subtracted by 1 Calculating means, and the display control means causes the display means to display the subtracted number of rewrites when the number of rewrites is decremented by 1 by the first calculation means. And wherein the door.

  In addition to the configuration of the invention described in claim 1 or 2, the display device according to claim 3 has a temperature detecting unit whose characteristics change according to the temperature of the battery, and the characteristics of the temperature detecting unit. Temperature detecting means for detecting the temperature of the battery by detecting a change of the battery, wherein the rewrite count determining means is detected by the battery remaining amount detected by the remaining amount detecting means and the temperature detecting means. The number of rewritable times is determined based on the temperature of the battery, and when the remaining amount of the battery detected by the remaining amount detecting unit is equal to or less than the predetermined remaining amount, the temperature detecting unit The rewritable determining means starts determining the rewritable number of times, and the display control means displays the rewritable number of times on the display means, and the remaining amount detecting means When the remaining amount of the discharged battery is larger than the predetermined remaining amount, the temperature detection unit does not detect the temperature of the battery, and the rewrite number determination unit does not start determination of the rewriteable number. It is characterized by.

According to a fourth aspect of the present invention, in addition to the configuration according to any one of the first to third aspects, the remaining amount of the battery is based on the remaining amount of the battery detected by the remaining amount detecting means. Battery remaining amount determining means for determining battery remaining amount information that is information representing
The display control means further causes the display means to display a battery remaining amount display that is a display indicating the battery remaining amount information determined by the battery remaining amount determining means, and to display the battery remaining amount display as the number of rewritable times It is displayed next to.

  According to a fifth aspect of the present invention, in addition to the configuration of the invention according to any of the first to fourth aspects, the remaining amount of the battery detected by the remaining amount detecting means is less than or equal to the predetermined remaining amount. In this case, the display control means further causes the display means to display a battery outer shape part representing the outer shape of the battery, and displays the rewritable number of times inside the battery outer shape part.

  In addition to the configuration of the invention described in claim 4, the display device according to claim 6 displays the battery remaining amount display on a battery outer shape portion representing the shape of the outer shape of the battery and the battery remaining amount information. Accordingly, a meter portion in which the number of lump portions displayed on the inner side of the battery outer shape portion is provided is provided.

  In addition to the configuration of the invention described in claim 6, the display device according to claim 7 is configured so that, when the remaining amount of the battery detected by the remaining amount detecting unit is equal to or less than the predetermined remaining amount, Instead of the meter unit, the display control unit causes the display unit to display the rewritable number at the same position as the meter unit.

  The control program according to claim 8 includes non-volatile display means that requires power when rewriting an image being displayed and can retain the image even when power supply is cut off. A control program executed in a display device that operates using a battery as a power source, wherein the computer controls the display unit, and displays the image on the display unit, and detects the remaining battery level A remaining amount detection step, and a rewrite count determination step for determining a rewritable count, which is the number of times the image can be rewritten, based on the remaining battery level detected by the remaining charge detection step, When the remaining amount of the battery detected by the remaining amount detecting step is less than or equal to a predetermined remaining amount, the rewrite count determining step includes the rewriting possible The display control step displays the number of rewritable times on the display means, and when the remaining amount of the battery detected by the remaining amount detecting step is larger than the predetermined remaining amount, The step of determining the number of rewrites does not start the determination of the number of rewrites.

  According to the display device of the first aspect of the invention, when the remaining amount of the battery is larger than the predetermined remaining amount, the rewritable determination means does not start determination of the number of rewritable times. For this reason, the rewritable number of times is not displayed on the display means. When the remaining amount of the battery is equal to or less than the predetermined remaining amount, the number of possible rewrites is displayed. For this reason, only when the number of times that the image can be rewritten hardly fluctuates, the number of times that the image can be rewritten can be displayed on the display means.

  According to the display device of the second aspect, each time an image rewriting instruction is input within the first threshold, the number of rewriting times is decremented by one and displayed. For this reason, in addition to the effect of the invention described in claim 1, when the rewrite instruction is input within the first threshold, it is not necessary to detect the remaining battery level.

  According to the display device of the invention according to claim 3, since the number of times of rewriting can be determined in consideration of the temperature of the battery, rewriting can be performed with higher accuracy in addition to the effect of the invention of claim 1 or 2. The possible number of times can be determined.

  According to the display device of the invention according to claim 4, in addition to displaying the number of rewritable times when the remaining battery level is low, the remaining battery level display is displayed regardless of the remaining battery level. Therefore, in addition to the effect of the invention according to any one of claims 1 to 3, the user can check the remaining battery level even when the remaining battery level is sufficient.

  According to the display device of the fifth aspect of the present invention, when the remaining amount of the battery is equal to or less than the predetermined remaining amount, the number of rewritable times can be displayed inside the outer shape of the battery. Since the battery outline portion is displayed, the user can easily determine that the remaining amount of the battery is small and the number of rewrites is small. For this reason, in addition to the effects of the invention according to claims 1 to 4, the user can easily confirm that the remaining battery level is low and the number of rewrites is possible.

  According to the display device of the sixth aspect, the meter portion is displayed inside the outer shape portion of the battery. Since the battery outline portion is displayed, the user can easily recognize that the display shows the remaining amount of the battery. For this reason, in addition to the effect of the invention which concerns on Claim 4, the user can confirm the remaining amount of a battery easily.

  According to the display device of the invention according to claim 7, when the remaining amount of the battery is larger than the predetermined remaining amount, the remaining battery amount display including the battery outer shape portion and the meter portion is displayed, and the remaining battery amount is displayed. When the amount is less than the predetermined remaining amount, the rewritable number is displayed instead of the meter portion. Therefore, in addition to the effect of the invention according to claim 6, the display area can be reduced as compared with the case where the battery remaining amount display and the number of rewritable times are displayed at different positions.

  According to the control program of the eighth aspect, when the remaining amount of the battery is larger than the predetermined remaining amount, the rewritable determination step does not start the determination of the number of rewritable times. For this reason, the rewritable number of times is not displayed on the display means. When the remaining amount of the battery is equal to or less than the predetermined remaining amount, the number of possible rewrites is displayed. For this reason, only when the number of times that the image can be rewritten hardly fluctuates, the number of times that the image can be rewritten can be displayed on the display means.

3 is a front view illustrating an outline of the display device 1. FIG. 3 is a block diagram showing an electrical configuration of the display device 1. FIG. It is a graph which shows the relationship between residual capacity and voltage. It is a schematic diagram which shows the rewritable frequency table 41. It is a schematic diagram which shows the battery remaining amount table 51. FIG. It is a figure which shows the battery remaining amount display 61 displayed on the display panel. It is a flowchart which shows a main process. 4 is a front view of the display device 1 showing an example of a state in which a first remaining amount display 616 is displayed on the display panel 22. FIG. 7 is a front view of the display device 1 showing an example of a state in which a third remaining amount display 618 and the number of rewritable times are displayed on the display panel 22. FIG. It is a figure which shows the battery outer shape part 611 displayed on the display panel 22, and the rewritable number of times displayed on the inner side of the battery outer shape part 611.

  Hereinafter, a display device 1 embodying a display device and a control program according to the present invention will be described with reference to the drawings. These drawings are used to explain the technical features that can be adopted by the present invention, and the configuration of the display device and the flowcharts of various processes described are not intended to be limited thereto. This is just an illustrative example.

  An overview of the display device 1 will be described with reference to FIG. The display device 1 has a substantially rectangular shape when viewed from the front. The display device 1 includes a substantially rectangular display panel 22 on the front side. The display panel 22 is composed of a nonvolatile display element. A non-volatile display element has a characteristic that power is required only when an image being displayed is rewritten, and an image being displayed can be retained even when power supply is cut off. Various conventionally known non-volatile display elements can be used as the display panel 22. For example, a non-volatile display element such as a microcapsule method or an electrophoretic method can be used.

  The display device 1 includes a plurality of selection buttons 15 arranged in a line in the vertical direction on the right side of the display panel 22. The selection button 15 is used when selecting one of the selection menus displayed on the left side of the selection button 15 in the display panel 22.

  The display device 1 includes a power switch 33, a setting button 13, and an operation button 14 on the right side of the selection button 15. From the top, the power switch 33, the setting button 13, and the operation button 14 are arranged in this order. The power switch 33 is pressed by the user when switching the power of the display device 1 on and off. The setting button 13 and the operation button 14 are pressed by the user when setting or operating the display data displayed on the display panel 22.

  The display device 1 includes a battery 31 (see FIG. 2) inside. The display device 1 operates using the battery 31 as a power source. As the battery 31, for example, a conventionally known lithium ion battery or nickel metal hydride battery can be used. In the present embodiment, it is assumed that the thermistor 37 (see FIG. 2) for detecting the temperature t of the battery 31 is built in the battery 31. The position of the thermistor 37 is merely an example, and is not necessarily built in the battery 31. For example, the thermistor 37 may be disposed outside the battery 31. In addition, detecting the temperature using the thermistor 37 is merely an example, and other temperature detection methods may be used.

  Next, the electrical configuration of the display device 1 will be described with reference to FIG. The display device 1 includes a CPU 21, a ROM 24, and a RAM 25. The CPU 21 manages display control of the display panel 22 and the like. The ROM 24 includes at least a program storage area 241, a remaining battery level table storage area 242, a rewritable number table storage area 243, and other information storage areas 244. The program storage area 241 stores program data necessary for the CPU 21 to execute various processes. The battery remaining amount table storage area 242 stores a battery remaining amount table 51 (see FIG. 5) described later. The rewritable number storage area 252 stores a rewritable number table 41 (see FIG. 4) described later. The CPU 21 is electrically connected to the ROM 24. The CPU 21 can access the storage area of the ROM 24.

  The RAM 25 includes at least a battery remaining amount display storage area 251, a rewritable number storage area 252, a counter storage area 253, and other information storage areas 254. The battery remaining amount display storage area 251 stores battery remaining amount information to be described later. The rewritable count storage area 252 stores a rewritable count described later. The counter storage area 253 stores a counter value described later. The CPU 21 is electrically connected to the RAM 25. The CPU 21 can access the storage area of the RAM 25.

  The display device 1 includes a memory card slot 26. A memory card 35 is inserted into the memory card slot 26. The memory card 35 includes at least a display data storage area 351. Display data to be displayed on the display panel 22 is stored in the display data storage area 351. The CPU 21 is electrically connected to the memory card 35 via the memory card slot 26. The CPU 21 can access the storage area of the memory card 35.

  The display device 1 includes a display panel 22 and a display control unit 23. The display control unit 23 performs drive control of the display panel 22. The CPU 21 is electrically connected to the display control unit 23. The display control unit 23 is connected to the display panel 22. The CPU 21 can display a desired image on the display panel 22 via the display control unit 23.

  The display device 1 includes a power switch 33. The CPU 21 is electrically connected to the power switch 33. The CPU 21 can detect that the power switch 33 has been pressed by the user. The display device 1 includes a selection button 15, a setting button 13, and an operation button 14 (hereinafter collectively referred to as “input unit 34”). The CPU 21 is electrically connected to the input unit 34. The CPU 21 can detect that the input unit 34 has been operated by the user.

  The display device 1 includes a battery 31 and a power supply control unit 30. The battery 31 includes a thermistor 37. The CPU 21 is connected to the power control unit 30. The battery 31 is connected to the power supply control unit 30. Thereby, power is supplied from the battery 31 to the CPU 21 via the power supply control unit 30. Although not shown, the display device 1 is provided with a USB connector to which a USB (Universal Serial Bus) cable is connected and an AC connector to which an AC adapter is connected. Further, a charging circuit for charging the battery 31 is provided. The charging circuit can charge the battery 31 with the current supplied from the USB connector or the AC connector.

  The display device 1 includes a voltage detection circuit 32. The voltage detection circuit 32 detects the voltage V <b> 1 of the battery 31. In the voltage detection circuit 32, the voltage V1 of the battery 31 is divided by a resistor or the like. The divided voltage is converted into a digital signal by the A / D converter. The CPU 21 detects the voltage V1 of the battery 31 by detecting the digital signal converted by the A / D converter. The voltage detection circuit 32 is electrically connected to the CPU 21. The battery 31 is connected to the voltage detection circuit 32.

  The display device 1 includes a temperature detection circuit 36. The resistance value of the thermistor 37 changes due to the change in the temperature t of the battery 31. In the temperature detection circuit 36, a change in resistance value of the thermistor 37 is converted into a change in voltage, and this voltage is converted into a digital signal by an A / D converter. The CPU 21 detects the temperature t of the battery 31 by detecting the digital signal converted by the A / D converter. The temperature detection circuit 36 is electrically connected to the CPU 21. The thermistor 37 is connected to the temperature detection circuit 36.

  The display device 1 includes a counter 38. The CPU 21 is connected to the counter 38. The counter 38 measures time, and the measured time is recognized by the CPU 21.

  Next, the relationship between the remaining capacity of the battery 31 and the voltage will be described with reference to FIG. The capacity remaining in the battery 31 (hereinafter referred to as “remaining capacity”) and the voltage V1 of the battery 31 indicate the relationship between the curve 311 and the curve 312 in FIG. As shown by a curve 311 and a curve 312, the remaining capacity can be obtained from the voltage of the battery 31, and the voltage can be obtained from the remaining capacity. For this reason, the so-called “remaining capacity” of the battery 31 can be expressed by, for example, the voltage or remaining capacity of the battery 31. A curve 311 indicates a case where the temperature t of the battery 31 is 20 ° C., and a curve 312 indicates a case where the temperature t of the battery 31 is 40 ° C. As shown in FIG. 3, the relationship between the remaining capacity of the battery 31 and the voltage V <b> 1 of the battery 31 varies depending on the temperature t of the battery 31. As shown by the curve 311 and the curve 312, when the remaining capacity of the battery 31 remains sufficiently (for example, when the voltage V1 of the battery 31 is greater than 3.5V), the remaining capacity of the battery 31 is small (for example, When the capacity of the battery 31 is consumed, the amount of change in the voltage V1 of the battery 31 is small compared to the case where the voltage V1 of the battery 31 is 3.5 V or less. For this reason, when the remaining capacity of the battery 31 is sufficient when determining the rewritable number of times that is the remaining number of times that the image displayed on the display panel 22 can be rewritten based on the voltage V1 of the battery 31. Thus, it is difficult to accurately determine the number of rewritable times compared to the case where the remaining capacity of the battery 31 is small. For this reason, when the remaining capacity of the battery 31 is sufficient (for example, when the voltage V1 of the battery 31 is greater than 3.5 V), the number of rewritable times displayed on the display panel 22 often varies. In the present embodiment, the number of rewritable times often fluctuates, and when the remaining capacity of the battery 31 remains sufficiently, the number of rewritable times is not displayed on the display panel 22. When the number of rewritable times hardly fluctuates and the remaining capacity of the battery 31 is small, the number of rewritable times is displayed on the display panel 22.

  Next, the rewritable number table 41 will be described with reference to FIG. The rewritable times table 41 is stored in the rewritable times table storage area 243 (see FIG. 2) of the ROM 24. In the rewritable frequency table 41, the temperature t of the battery 31, the voltage V1 of the battery 31, and the rewritable frequency are stored in association with each other. The temperature t of the battery 31 is divided into t> 30 ° C. and t ≦ 30 ° C. Further, the voltage V1 of the battery 31 is V1 ≦ 3.0V, 3.0V <V1 ≦ 3.1V, 3.1V <V1 ≦ 3.2V, 3.2V <V1 ≦ 3.3V, 3 .3V <V1 ≦ 3.4V and 3.4V <V1 ≦ 3.5V. The voltage V1 of the partitioned battery 31 is associated with the temperature t partitioned into t> 30 ° C. and t ≦ 30 ° C. The number of rewritable times is associated with the temperature t of the battery 31 and the voltage V1 of the battery 31. When t> 30 ° C., the voltage V1 of the battery 31 is associated with the number of rewritable times as follows. That is, V1 ≦ 3.0V is associated with the number of rewritable times “0”. Further, 3.0V <V1 ≦ 3.1V is associated with the number of rewritable times “10 times”. Further, 3.1V <V1 ≦ 3.2V is associated with the number of rewritable times “20”. Further, 3.2V <V1 ≦ 3.3V is associated with the number of rewritable times “30 times”. Further, 3.3V <V1 ≦ 3.4V is associated with the number of rewritable times “40 times”. Further, 3.4V <V1 ≦ 3.5V is associated with the number of rewritable times “50 times”. When t ≦ 30 ° C., V1 of the battery 31 is associated with the number of rewritable times as follows. That is, V1 ≦ 3.0V is associated with the number of rewritable times “0”. Further, 3.0V <V1 ≦ 3.1V is associated with the number of rewritable times “40 times”. Further, 3.1V <V1 ≦ 3.2V is associated with the number of rewritable times “75 times”. Further, 3.2V <V1 ≦ 3.3V is associated with the number of rewritable times “110 times”. Further, 3.3V <V1 ≦ 3.4V is associated with the rewritable number of times “145 times”. Further, 3.4V <V1 ≦ 3.5V is associated with the number of rewritable times “180 times”.

  In the rewritable frequency table 41 of FIG. 4, the rewritable frequency is associated only when the voltage V1 of the battery 31 is 3.5 V or less. This is because the number of rewritable times is associated only when the remaining capacity of the battery 31 is small. The case where the remaining capacity is small is set to “3.5 V or less”, and can be arbitrarily changed.

  Note that the number of rewritable times for each voltage when the temperature t of the battery 31 in the rewritable number table 41 is t> 30 ° C. is shown using a curve 312 (curve when the temperature t of the battery 31 is 40 ° C.). After calculating the number of rewritable times, the number of rewritable times is determined by performing an experiment or the like. In addition, the number of rewritable times for each voltage when the temperature t of the battery 31 is t ≦ 30 ° C. was calculated using the curve 311 shown in FIG. 3 (the curve when the temperature t of the battery 31 is 20 ° C.). Later, the number of rewritable times is determined through experiments and the like.

  The numerical values in the rewritable number table 41 of FIG. 4 are examples, and various changes can be made. For example, the temperature t of the battery 31 is only described when t> 30 ° C. or t ≦ 30 ° C., but the range of the temperature 31 of the battery 31 may be set more finely. For example, the relationship between the voltage V1 of the battery 31 and the number of rewritable times may be associated at intervals of 1 ° C. Moreover, although the interval of the voltage V1 of the battery 31 is divided every 0.1V, it is not limited to this. For example, the interval of the voltage V1 of the battery 31 may be further finely divided so that the number of rewritable times decreases by one. In this way, the number of rewritable times can be determined more accurately in the processing of S19 and S31 of FIG.

  Next, the remaining battery level table 51 will be described with reference to FIG. The remaining battery level table 51 is stored in the remaining battery level table storage area 242 of the ROM 24 (see FIG. 2). In the battery remaining amount table 51, the voltage V1 of the battery 31 and battery remaining amount information that is information indicating the remaining amount of the battery 31 are stored in association with each other. A battery remaining amount display 61 is displayed on the display panel 22 based on the battery remaining amount information. The battery remaining amount display 61 is a display for informing the user of the remaining capacity of the battery 31.

  Here, the battery remaining amount display 61 will be described with reference to FIG. The battery remaining amount display 61 is displayed on the display panel 22. As shown in FIG. 6, the battery remaining amount display 61 changes the number of battery outer parts 611 schematically showing the outer shape of the battery and the number of mass parts 614 displayed on the inner side of the battery outer part 611. Meter section 615. The battery outer shape portion 611 includes a horizontally-long rectangular first component 612 and a second component 613 that is rectangular and smaller than the first component 612. The second component 613 is displayed connected to the first component 612 on the right side of the first component 612 (the right side of the drawing in FIG. 6). Three lump portions 614 are displayed inside the battery outer shape portion 611, more specifically, inside the first component portion 612. The lump portion 614 has a vertically long rectangular shape, and the meter portion 615 is formed by arranging three lump portions 614 in the left-right direction. The meter unit 615 uses the battery remaining amount table 51 shown in FIG. 5 to vary the number of lump portions 614 between 0 and 3 according to the remaining battery amount information determined from the voltage V1 of the battery 31. To do. Thereby, the remaining capacity of the battery 31 can be communicated to the user.

  The battery remaining amount display 61 when three lump portions 614 are displayed is referred to as a first remaining amount display 616. Further, the battery remaining amount display 61 when two lump portions 614 are displayed is referred to as a second remaining amount display 617. In addition, the battery remaining amount display 61 when one lump portion 614 is displayed is referred to as a third remaining amount display 618. Further, the battery remaining amount display 61 in which the number of the batteries 31 is zero and only the battery outer shape portion 611 is displayed is referred to as a fourth remaining amount display 619.

  As shown in FIG. 5, the battery remaining amount table 51 is associated with battery remaining amount information for displaying the first remaining amount display 616 when the voltage V1 of the battery 31 is V1> 4.0V. ing. Further, when the voltage V1 of the battery 31 is 3.5V <V1 ≦ 4.0V, battery remaining amount information for displaying the second remaining amount display 617 is associated. Further, when the voltage V1 of the battery 31 is 3.1V <V1 ≦ 3.5V, the battery remaining amount information for displaying the third remaining amount display 618 is associated. Further, when the voltage V1 of the battery 31 is V1 ≦ 3.1V, the battery remaining amount information for displaying the fourth remaining amount display 619 is associated. FIG. 5 shows the shapes of the first remaining amount display 616, the second remaining amount display 617, the third remaining amount display 618, and the fourth remaining amount display 619 displayed on the display panel 22. Actually, battery remaining amount information for displaying the first remaining amount display 616, the second remaining amount display 617, the third remaining amount display 618, and the fourth remaining amount display 619 on the display panel 22 is stored. Yes.

  Next, the operation of the display device 1 of the present embodiment will be described with reference to the flowchart shown in FIG.

  As shown in FIG. 7, in the main process by the CPU 21 of the present embodiment, first, the voltage V1 of the battery 31 is detected via the voltage detection circuit 32 (see FIG. 2) (S11). Next, it is determined whether or not the voltage V1 of the battery 31 detected by the process of S11 is 3.5 V or less (S12). If the voltage V1 of the battery 31 detected in the process of S11 is greater than 3.5V (S12: NO), it is subsequently determined whether or not a screen rewrite instruction has been input (S13). In the process of S13, it is determined whether or not the input unit 34 (see FIG. 2) has been pressed by the user. If a screen rewrite instruction is not input (S13: NO), it is then determined whether a power-off instruction is input (S16). In the process of S16, it is determined whether or not the power switch 33 of the input unit 34 has been pressed by the user. If the power-off instruction has not been input (S16: NO), the process returns to S11 and the process is repeated. That is, when the input unit 34 or the power switch 33 is not pressed by the user, the display device 1 stands by while detecting the voltage V1 of the battery 31. When a power-off instruction is input (S16: YES), the main process by the CPU 21 is terminated.

  When an instruction to rewrite the screen is input (S13: YES), the battery remaining amount table 51 (see FIG. 5) stored in the battery remaining amount table storage area 242 (see FIG. 2) of the ROM 24 is subsequently stored. The battery remaining amount information for reading and displaying the battery remaining amount display 61 is selected and determined, and stored in the remaining battery amount display storage area 251 (see FIG. 2) (S14). In the process of S14, the battery remaining amount information for displaying the battery remaining amount display 61 corresponding to the voltage V1 of the battery 31 detected by the process of S11 is selected with reference to the battery remaining amount table 51. To be determined. Then, the remaining battery level information for displaying the determined remaining battery level display 61 is stored in the remaining battery level display storage area 251 (S14). Next, the battery remaining amount display 61 is rewritten at the same time as the display panel 22 is rewritten (S15). In the process of S15, the CPU 21 controls the display control unit 23 to rewrite the display panel 22 in accordance with the input unit 34 pressed by the user in the process of S13, and at the same time, is determined by the process of S14 and is determined by the process of S14. Based on the remaining battery level information stored in the display storage area 251, the remaining battery level display 61 is displayed on the display panel 22. Next, it progresses to S16 and repeats a process.

  For example, when the detected voltage V1 of the battery 31 is 4.1 V (S11), it is determined that the voltage V1 of the battery 31 is not 3.5 V or less (S12: NO). When a screen rewrite instruction is input (S13: YES), the remaining battery level table 51 is read (S14). From the battery remaining amount table 51, battery remaining amount information for displaying on the display panel 22 the first remaining amount display 616 that is the remaining battery amount display 61 corresponding to the voltage V1 of the battery 31 of 4.1V is selected and determined. (S14). Then, the determined remaining battery level information is stored in the remaining battery level display storage area 251 (S14). Then, the first remaining amount display 616 is displayed on the display panel 22 based on the remaining battery amount information stored in the remaining battery amount display storage area 251 together with the rewritten image (S15). Thereby, as shown in FIG. 8, the first remaining amount display 616 is displayed on the display panel 22. Further, for example, when the detected voltage V1 of the battery 31 is 3.8V (S11), the second remaining amount that is the remaining battery amount display 61 corresponding to 3.8V is obtained from the remaining battery amount table 51. Battery remaining amount information for displaying the display 617 is selected (S14), and the second remaining amount display 617 is displayed on the display panel 22 (S15). When the image is rewritten, for example, display data stored in the display data storage area 351 of the memory card 35 inserted in the memory card slot 26 according to the input unit 34 pressed by the user. It is selected and displayed on the display panel 22. In FIG. 8, description of images other than the first remaining amount display 616 is omitted on the display panel 22. Similarly, the description of the image is omitted in FIG. 9 described later. For the sake of explanation, the size of the first remaining amount display 616 is displayed larger than the actual size.

  Next, when the battery 31 is consumed and the voltage V1 of the battery 31 detected by the process of S11 becomes 3.5 V or less (S12: YES), the temperature t of the battery 31 is subsequently detected. (S17). In the process of S17, the temperature t of the battery 31 is detected using the thermistor 37 and the temperature detection circuit 36 built in the battery 31 (S17). Subsequently, the rewritable number table 41 (see FIG. 4) stored in the rewritable number table storage area 243 (see FIG. 2) is read (S18). Next, the rewritable count is determined and stored in the rewritable count storage area 252 (see FIG. 2) (S19). In the process of S19, referring to the rewritable number table 41 read out in the process of S18, the temperature t of the battery 31 detected in the process of S17, and the voltage V1 of the battery 31 detected in the process of S11. The rewritable number of times corresponding to is selected and determined. The determined rewritable count is stored in the rewritable count storage area 252 (S19). Next, the battery level table 51 (see FIG. 5) stored in the battery level table storage area 242 (see FIG. 2) is read, and the battery for displaying the battery level display 61 on the display panel 22 is read. The remaining amount information is selected and determined and stored in the battery remaining amount display storage area 251 (see FIG. 2) (S20). The process of S20 is the same as the process of S14 described above. Next, the display panel 22 is rewritten, and the number of rewritable times and the remaining battery capacity display 61 are displayed on the display panel 22 (S21). In the process of S21, the rewritable count stored in the rewritable count storage area 252 by the process of S19 is displayed on the display panel 22. Furthermore, the battery remaining amount display 61 is displayed on the display panel 22 based on the display remaining amount information stored in the battery remaining amount display storage area 251 by the process of S20 (S21). Note that in the processing of S21, images other than the number of rewritable times and the battery remaining amount display 61 are retained before the display panel 22 is rewritten in S21. Further, the number of rewritable times is displayed next to the battery remaining amount display 61.

  For example, it is assumed that the voltage V1 of the battery 31 is 3.5V and the temperature t of the battery 31 is 20 ° C. In this case, 3.5V that is the voltage V1 of the battery 31 is detected (S11), and it is determined that the voltage V1 of the battery 31 is 3.5V or less (S12: YES). And 20 degreeC which is the temperature t of the battery 31 is detected (S17). Next, the rewritable number table 41 (see FIG. 4) stored in the rewritable number table storage area 243 (see FIG. 2) is read (S18). Then, the rewritable number table 41 is referred to, and “180 times” which is the rewritable number corresponding to 20 ° C. which is the temperature t of the battery 31 and 3.5 V which is the voltage V1 of the battery 31 is selected and determined. (S19). Then, “180 times” which is the determined rewritable count is stored in the rewritable count storage area 252 (S19). Next, the remaining battery level table 51 (see FIG. 5) stored in the remaining battery level table storage area 242 (see FIG. 2) is read (S20). Then, from the battery remaining amount table 51, the battery remaining amount information for causing the display panel 22 to display the third remaining amount display 618 that is the remaining battery amount display 61 corresponding to the voltage V1 of the battery 31 of 3.5V is selected. And is stored in the battery remaining amount display storage area 251 (S20). Next, the display panel 22 is rewritten, and the number of rewritable times and the third remaining amount display 618 are displayed on the display panel 22 (S21). As a result, as shown in FIG. 9, the third remaining amount display 618 and the number of rewritable times are displayed on the display panel 22. In FIG. 9, “remaining 180P” is displayed in order to express that the number of rewritable times is 180 times. As a result, the user can be informed that the remaining 180 pages can be rewritten. The display of the number of rewritable times can be arbitrarily changed, and may be displayed as “180”, “the remaining 180 times”, or the like. Further, the rewritable number is displayed next to the third remaining amount display 618 and above the third remaining amount display 618, but is not limited thereto, and may be displayed at an arbitrary position.

  When the number of rewritable times and the remaining battery capacity display 61 are displayed on the display panel 22 by the process of S21, time measurement is subsequently started (S22). In the process of S22, time measurement is started by the counter 38 (see FIG. 2) and recognized by the CPU 21. The time measured by the counter 38 is called a counter value. The counter value is stored in the counter storage area 253. Next, it is determined whether or not a screen rewrite instruction has been input (S23). The process of S23 is the same as the process of S13. If the screen rewrite instruction is not input (S23: NO), then the counter value stored in the counter storage area 253 is referred to and it is determined whether or not the counter value is 3 minutes or more. (S24). If the counter value is not 3 minutes or more (S24: NO), it is then determined whether or not a power-off instruction has been input (S25). In the process of S25, as in the process of S16, it is determined whether or not the power switch 33 of the input unit 34 has been pressed by the user. If the power-off instruction has not been input (S25: NO), the process returns to S23 and the process is repeated. That is, when the screen rewrite instruction is not input (S23: NO), the counter value is not 3 minutes or more (S24: NO), and the power-off instruction is not input (S25: NO), the display device 1 Waiting. When the power-off instruction is input (S25: YES), the processing by the CPU 21 of the display device 1 is ended.

  If no screen rewrite instruction is input (S23: NO) and the counter value is 3 minutes or more (S24: YES), then the time measurement by the counter 38 is stopped and the counter stored in the counter storage area 253 is displayed. The value is reset and set to 0 seconds (S26). Next, it progresses to S16 and a process is repeated. That is, when the voltage V1 of the battery 31 is 3.5 V or less (S12: YES), no screen rewriting instruction is input (S23: NO), and no power off instruction is input (S25: NO), the counter value Each time is 3 minutes or more (S24: YES), the number of rewritable times and the remaining battery capacity display 61 are updated (S21).

  When the voltage V1 of the battery 31 is 3.5 V or less (S12: YES), when a screen rewrite instruction is input (S23: YES), the counter value stored in the counter storage area 253 is subsequently referred to. Then, it is determined whether or not the counter value is 3 seconds or more (S27). This “3 seconds” corresponds to the “first threshold value” of the present invention. The first threshold value does not necessarily have to be 3 seconds, and can be set arbitrarily. When the counter value is 3 seconds or more (S27: YES), the voltage V1 of the battery 31 is subsequently detected (S28). The process of S28 is the same as the process of S11 described above. Next, the temperature t of the battery 31 is detected (S29). The process of S29 is the same as the process of S17 described above. Next, the rewritable number table 41 (see FIG. 4) stored in the rewritable number table storage area 243 (see FIG. 2) is read (S30). The process of S30 is the same as the process of S18 described above. Next, the rewritable count is determined and stored in the rewritable count storage area 252 (see FIG. 2) (S31). In the process of S31, referring to the rewritable number table 41 read out in the process of S30, the temperature t of the battery 31 detected in the process of S29, and the voltage V1 of the battery 31 detected in the process of S28. The rewritable number of times corresponding to is selected and determined. The determined rewritable count is stored in the rewritable count storage area 252 (S31).

  Next, the remaining battery level table 51 (see FIG. 5) stored in the remaining battery level table storage area 242 (see FIG. 2) is read, and the remaining battery level information for displaying the remaining battery level display 61 is displayed. It is determined and stored in the battery remaining amount display storage area 251 (see FIG. 2) (S32). In the process of S32, the remaining battery level information for displaying the remaining battery level display 61 corresponding to the voltage V1 of the battery 31 detected by the process of S28 is determined with reference to the remaining battery level table 51. Is done. Then, the determined remaining battery level information is stored in the remaining battery level display storage area 251 (S32). Next, the display panel 22 is rewritten, and the number of rewritable times and the remaining battery capacity display 61 displayed on the display panel 22 are updated (S33). In the process of S33, the CPU 21 rewrites the display panel 22 by controlling the display panel 22 in accordance with the input unit 34 pressed by the user in the process of S23. Further, the number of rewritable times stored in the rewritable number storage area 252 by the process of S31 is displayed on the display panel 22 (S33). Furthermore, the battery remaining amount display 61 is displayed on the display panel 22 based on the display remaining amount information stored in the battery remaining amount display storage area 251 by the process of S32 (S33). Next, the time measurement by the counter 38 is stopped, the counter value stored in the counter storage area 253 is reset, and is set to 0 second (S34). Next, the process returns to S22 and is repeated.

  For example, when the voltage V1 of the battery 31 is 3.4 V and the temperature t of the battery 31 is 20 ° C., the input unit 34 is pressed by the user 5 seconds after the time measurement is started by the process of S22. Is described. In this case, an image rewriting instruction is input 5 seconds after the time measurement is started by the process of S22 (S23: YES). For this reason, since the counter value is 5 seconds (S27: YES), 3.4 V which is the voltage V1 of the battery 31 is detected (S28). Next, 20 ° C., which is the temperature t of the battery 31, is detected (S29). Next, the rewritable number table 41 (see FIG. 4) stored in the rewritable number table storage area 243 (see FIG. 2) is read (S30). Then, the rewritable number table 41 is referred to, 145 times that is the rewritable number corresponding to 20 ° C. that is the temperature t of the battery 31 and 3.4 V that is the voltage V1 of the battery 31 are selected, and the rewritable number memory is stored. It is stored in the area 252 (S31). Next, the remaining battery level table 51 (see FIG. 5) stored in the remaining battery level table storage area 242 (see FIG. 2) is read, and is the voltage V1 of the battery 31 from the remaining battery level table 51. Battery remaining amount information for displaying the third remaining amount display 618 that is the remaining battery amount display 61 corresponding to 4V is selected and determined, and stored in the remaining battery amount display storage area 251 (S32). Next, the display panel 22 is rewritten, and the number of rewritable times and the third remaining amount display 618 are updated (S33). Then, the time measurement by the counter 38 is stopped, the counter value stored in the counter storage area 253 is reset, and is set to 0 second (S34). And it returns to S22 and a process is repeated.

  When the voltage V1 of the battery 31 is 3.5 V or less (S12: YES), when a screen rewrite instruction is input (S23: YES), the counter value stored in the counter storage area 253 is subsequently referred to. Then, it is determined whether or not the counter value is 3 seconds or more (S27). If the counter value is not 3 seconds or more (S27: NO), then, the rewritable count stored in the rewritable count storage area 252 is decremented by 1 and stored in the rewritable count storage area 252 ( S35). That is, the rewritable number of times is decremented. Next, the display panel 22 is rewritten, and the number of rewritable times and the remaining battery capacity display 61 are updated (S36). In the process of S36, the CPU 21 rewrites the display panel 22 by controlling the display panel 22 in accordance with the input unit 34 pressed by the user in the process of S23. Furthermore, the number of rewritable times decremented by the process of S35 and stored in the rewritable number storage area 252 is displayed on the display panel 22 (S36). Further, a battery level display 61 is displayed on the display panel 22 based on the battery level information stored in the battery level display storage area 251. The number of rewritable times stored in the rewritable number storage area 252 is updated by the process of S35, and the battery remaining amount information stored in the battery remaining amount display storage area 251 is not updated. For this reason, the battery remaining amount display 61 displayed on the display panel 22 does not change, and the decremented value is displayed as the number of possible rewrites (S36). Next, the time measurement by the counter 38 is stopped, the counter value stored in the counter storage area 253 is reset, and set to 0 second (S37). Next, the process returns to S22 and is repeated.

  For example, the number of rewritable times displayed on the display panel 22 is 145 times, and 1 second after the time measurement is started by the process of S22, the user continuously inputs the input unit 34 at intervals of 2 seconds. Will be described. In this case, an image rewriting instruction is input one second after the time measurement is started by the processing of S22 (S23: YES). Therefore, since the counter value is 1 second (S27: NO), the rewritable count stored in the rewritable count storage area 252 is decremented to 144 (S35). Then, it is displayed on the display panel 22 that the number of rewritable times is 144 (S36). Then, the time measurement by the counter 38 is stopped, the counter value stored in the counter storage area 253 is reset, and set to 0 second (S37). And time measurement is started again by the process of S22. Two seconds later, an image rewrite instruction is input (S23: YES). Therefore, since the counter value is 2 seconds (S27: NO), the rewritable count is decremented to 143 (S35), and the display panel 22 displays that the rewritable count is 143 (S36). . Then, the time measurement by the counter 38 is stopped, and the counter value is reset (S37). And time measurement is started again by the process of S22. Two more seconds later, an image rewriting instruction is input (S23: YES). Therefore, since the counter value is 2 seconds (S27: NO), the rewritable count is decremented to 142 (S35), and the display panel 22 displays that the rewritable count is 142 (S36). ). Then, the time measurement by the counter 38 is stopped, and the counter value is reset (S37).

  Thus, when the rewrite instruction is input at an interval smaller than the first threshold (3 seconds in the present embodiment), that is, when the rewrite instruction is input continuously, the voltage V1 of the battery 31 is set. And the temperature t of the battery 31 are not measured. For this reason, consumption of the remaining capacity of the battery 31 for measuring the voltage V1 of the battery 31 and the temperature t of the battery 31 can be suppressed.

  If the power switch 33 is pressed (S25: NO or S16: NO), the main process by the CPU 21 is terminated.

  As described above, the processing in the first embodiment is performed. In the present embodiment, when the voltage V1 of the battery 31 is 3.5 V or less, the number of rewritable times is displayed on the display panel 22, and when the voltage V1 of the battery 31 is greater than 3.5 V, the number of rewritable times is displayed. Not displayed on panel 22. Here, as shown in FIG. 3, when the voltage V1 of the battery 31 is larger than 3.5V, the remaining capacity of the battery 31 remains sufficiently. Further, when the voltage V1 of the battery 31 is 3.5 V or less, the remaining capacity of the battery 31 is small. As described above, when the remaining capacity of the battery 31 is sufficient, the amount of change in the voltage V1 of the battery 31 when the remaining capacity of the battery 31 is consumed is larger than when the remaining capacity of the battery 31 is small. small. For this reason, when the remaining capacity of the battery 31 is sufficient when determining the rewritable number of times that is the remaining number of times that the image displayed on the display panel 22 can be rewritten based on the voltage V1 of the battery 31. Thus, it is difficult to accurately determine the number of rewritable times compared to the case where the remaining capacity of the battery 31 is small. For this reason, when the remaining capacity of the battery 31 is sufficient, the number of rewritable times displayed on the display panel 22 often varies. For this reason, the user may be confused. In the present embodiment, the number of rewritable times often fluctuates, and when the remaining capacity of the battery 31 remains sufficiently, the number of rewritable times is not displayed on the display panel 22. When the number of rewritable times hardly fluctuates and the remaining capacity of the battery 31 is small, the number of rewritable times is displayed on the display panel 22. That is, only when the rewritable number can be determined with high accuracy, the rewritable number is displayed on the display panel 22. This can prevent the user from being confused. In the present embodiment, the case where the voltage V1 of the battery 31 is 3.5 V or less is assumed to be a case where the remaining capacity of the battery 31 is small, but this “3.5 V” is an example and can be arbitrarily set. it can. The threshold value of the voltage of the battery 31 that can be arbitrarily set corresponds to the “predetermined remaining amount” of the present invention. The predetermined remaining amount is not limited to being expressed by the voltage of the battery 31, and for example, the remaining capacity of the battery 31 may be the predetermined remaining amount.

  Further, in the present embodiment, when the remaining capacity of the battery 31 is sufficient, the number of rewritable times is not displayed on the display panel 22. For this reason, it is not necessary for the CPU 21 to perform processing for determining the number of times that the image can be rewritten. Therefore, consumption of the remaining capacity of the battery 31 can be suppressed.

  Further, although the remaining capacity of the battery 31 varies depending on the temperature t of the battery 31, in the present invention, since the number of rewrites is determined in consideration of the temperature t of the battery 31, the temperature t of the battery 31 is considered. The number of rewritable times can be determined with higher accuracy than when not.

  Further, since the battery remaining amount display 61 is displayed on the display panel regardless of the remaining capacity of the battery 31, even when the remaining capacity of the battery is sufficient, the user can check the remaining capacity of the battery.

  Further, since the battery outer shape portion 611 is displayed on the battery remaining amount display 61, the user can easily recognize that the display shows the remaining capacity of the battery 31. For this reason, the user can easily check the remaining capacity of the battery 31.

  Note that the display device 1 of the present invention is not limited to the above-described embodiment, and it is needless to say that various changes can be made without departing from the gist of the present invention.

  For example, the battery remaining amount table 51 of FIG. 5 stores the voltage V1 of the battery 31 and the battery remaining amount information, which is information indicating the remaining amount of the battery 31, in association with each other, but is not limited thereto. For example, the temperature t of the battery 31, the voltage V1 of the battery 31, and the remaining battery information may be associated with each other. In this way, the remaining battery level information can be determined in consideration of the temperature t of the battery 31. For this reason, the remaining battery level display 61 can be displayed with higher accuracy.

  Moreover, although the temperature t of the battery 31 was measured, it is not necessary to measure the temperature t. In this case, the rewritable frequency table 41 of FIG. 4 may be created so that the voltage V1 of the battery 31 and the rewritable frequency are associated with each other. As a result, the number of rewritable times can be determined only from the voltage V1 of the battery 31.

  Moreover, although the thermistor 37 was used in order to measure the temperature t of the battery 31, it is not limited to this. For example, a thermocouple or other temperature sensor may be used.

  Moreover, although the remaining capacity of the battery 31 was represented by the battery remaining amount display 61, it is not limited to this. For example, the remaining capacity of the battery 31 may be represented by a number. The lump portion 614 has a vertically long rectangular shape, but is not limited thereto, and may be, for example, a star shape or a circular shape. Moreover, although the number of the lump parts 614 was three, it is not limited to this, For example, four may be sufficient.

  Further, when displaying the rewritable number on the display panel 22, as shown in FIG. 10, instead of the meter unit 615 (see FIG. 6) of the battery remaining amount display 61, the same position as the meter unit 615 in FIG. The number of rewritable times may be displayed. As a result, the remaining number of rewritable times can be communicated to the user. Further, in this case, since there is no need to display the meter unit 615, the processing of S20 and the processing of S32 in the flowchart of FIG. 7 can be omitted. Thereby, consumption of the remaining capacity of the battery 31 can be suppressed. Further, the display area on the display panel 22 can be reduced as compared with the case where the battery remaining amount display 61 and the number of rewritable times are displayed at different positions (see FIG. 8).

  Moreover, although the battery remaining amount display 61 was displayed, it does not need to be displayed. In this case, when the remaining capacity of the battery is reduced, the number of possible rewrites is displayed. Even when the remaining battery capacity display 61 is not displayed and the number of rewritable times is displayed, the battery outline 611 is displayed on the display panel and rewritten inside the battery outline 611 as shown in FIG. The possible number of times may be displayed. In this case, since the battery outer shape portion 611 is displayed, the user can easily determine that the remaining capacity of the battery 31 is small and the number of rewritable times is small. For this reason, the user can easily confirm that the remaining capacity of the battery 31 is small and the number of rewritable times.

  Moreover, although the voltage V1 of the battery 31 was measured and the rewrite frequency of the battery 31 was determined, it is not limited to this. For example, the remaining capacity of the battery 31 may be detected to determine the number of possible rewrites.

  Further, the rewritable number table 41 is stored in advance and the rewritable number table 41 is used to determine the rewritable number. However, the present invention is not limited to this. For example, the once consumed capacity, which is the capacity of the battery 31 consumed for rewriting the display panel 22 once, and the data corresponding to the curves 311 and 312 shown in FIG. From the voltage V1 and the temperature t of the battery 31, the remaining capacity is calculated from data corresponding to the curve 311 or the curve 312 shown in FIG. Then, the number of rewritable times may be calculated and determined by dividing the calculated remaining capacity by the once consumed capacity.

  Further, as a battery remaining amount detection method, a current (charge) discharged from a battery such as a coulomb counter may be detected, and the method is not limited to voltage detection.

  In addition, when the voltage of the battery 31 is 3.5 V or less, the number of rewritable times is displayed. If a voltage greater than 3.5 V is detected, the number of rewritable times is not set, but the present invention is not limited to this. For example, after a voltage of 3.5 V or less is detected and the number of possible rewrites is displayed, the number of possible rewrites may be displayed until a voltage greater than “3.7 V” is detected. Further, after a voltage of 3.5 V or less is detected and the number of rewritable times is displayed, the number of rewritable times may be displayed even if a voltage of 3.5 V or more is detected. As a result, when the voltage of the battery 31 is in the vicinity of 3.5 V, it is possible to prevent the once displayed rewritable number from disappearing. Note that values such as “3.5 V” and “3.7 V” are examples, and may be set arbitrarily.

  In the above embodiment, the display panel 22 corresponds to the “display unit” of the present invention, and the CPU 21 that performs the processes of S15, S21, S33, and S36 in FIG. 7 corresponds to the “display control unit” of the present invention. . Further, the input unit 34 corresponds to the “input unit” of the present invention, and the CPU 21 that performs the processes of S11 and S28 in FIG. 7 corresponds to the “remaining amount detection unit” of the present invention. Further, the CPU 21 that performs the processes of S19 and S31 in FIG. 7 corresponds to the “rewrite count determining means” of the present invention. Further, the CPU 21 that performs the process of S27 in FIG. 7 corresponds to the “first determination unit” of the present invention, and the CPU 21 that performs the process of S35 of FIG. 7 corresponds to the “first calculation unit” of the present invention. 7 corresponds to the “temperature detecting means” of the present invention, and the CPU 21 performing the processes of S14, S20 and S32 of FIG. 7 “the remaining battery capacity determining means” of the present invention. It corresponds to. The thermistor 37 corresponds to the “temperature detection unit” of the present invention, and the resistance value of the thermistor 37 that changes in accordance with the change in the temperature t of the battery 31 corresponds to the “characteristic” of the present invention.

  Further, the processing of S15, S21, S33, and S36 in FIG. 7 corresponds to the “display control step” of the present invention, and the processing of S11 and S28 in FIG. 7 corresponds to the “remaining amount detection step” of the present invention. . 7 corresponds to the “rewrite count determination step” of the present invention.

DESCRIPTION OF SYMBOLS 1 Display device 13 Setting button 14 Operation button 15 Selection button 21 CPU
22 Display panel 23 Display control unit 31 Battery 32 Voltage detection circuit 33 Power switch 34 Input unit 36 Temperature detection circuit 37 Thermistor 38 Counter 41 Rewritable frequency table 51 Battery remaining amount table 61 Battery remaining amount display 611 Battery outer shape portion 614 Lump portion 615 Meter unit 616 First remaining amount display 617 Second remaining amount display 618 Third remaining amount display 619 Fourth remaining amount display t Temperature V1 Voltage

Claims (8)

A display device that requires electric power when rewriting an image being displayed, includes a non-volatile display unit capable of holding the image even when power supply is cut off, and operates using a battery as a power source,
Display control means for controlling the display means and displaying the image on the display means;
A remaining amount detecting means for detecting the remaining amount of the battery;
Rewriting number determination means for determining the number of times that the image can be rewritten, based on the remaining amount of the battery detected by the remaining amount detection means,
When the remaining amount of the battery detected by the remaining amount detecting means is below a predetermined remaining amount,
The rewrite count determining means starts determining the rewrite possible count,
The display control means displays the rewritable number on the display means,
When the remaining amount of the battery detected by the remaining amount detecting means is larger than the predetermined remaining amount,
The display device according to claim 1, wherein the rewrite count determining means does not start the determination of the rewriteable count. Input means for inputting an instruction to rewrite the image;
First determination means for determining whether or not the image rewriting instruction is input again within a first threshold which is a time threshold after the image rewriting instruction is input via the input means;
When the first determination means determines that the image rewrite instruction is input again within the first threshold after the image rewrite instruction is input via the input means, the rewrite count is determined. First calculating means for subtracting 1 from the number of rewrites determined by means,
The display control means includes
2. The display device according to claim 1, wherein when the number of rewrites is subtracted by 1 by the first calculation unit, the display unit displays the subtracted number of rewrites. A temperature detector whose characteristics change according to the temperature of the battery;
Temperature detecting means for detecting the temperature of the battery by detecting a change in the characteristic of the temperature detecting unit;
The rewrite count determining means includes
Determining the number of rewritable times based on the remaining amount of the battery detected by the remaining amount detecting means and the temperature of the battery detected by the temperature detecting means;
When the remaining amount of the battery detected by the remaining amount detecting means is less than or equal to the predetermined remaining amount,
The temperature detection means detects the temperature of the battery,
The rewritable determination means starts determining the rewritable number of times,
The display control means displays the rewritable number on the display means,
When the remaining amount of the battery detected by the remaining amount detecting means is larger than the predetermined remaining amount,
The temperature detection means does not detect the temperature of the battery,
The display device according to claim 1, wherein the rewrite frequency determination unit does not start determination of the rewriteable frequency. Battery remaining amount determining means for determining battery remaining amount information that is information representing the remaining amount of the battery based on the remaining amount of the battery detected by the remaining amount detecting unit;
The display control means includes
The display means further displays a battery remaining amount display that is a display indicating the battery remaining amount information determined by the battery remaining amount determining means, and displays the rewritable count next to the battery remaining amount display. The display device according to claim 1, wherein: When the remaining amount of the battery detected by the remaining amount detecting means is less than or equal to the predetermined remaining amount,
The display control means includes
The display according to any one of claims 1 to 4, wherein a battery outer shape representing a shape of an outer shape of the battery is further displayed on the display means, and the number of rewritable times is displayed inside the battery outer shape. apparatus. The battery level display is
A battery outer shape representing the outer shape of the battery;
The display device according to claim 4, further comprising: a meter unit that changes a number of lump portions displayed on the inner side of the battery outer shape portion according to the battery remaining amount information. When the remaining amount of the battery detected by the remaining amount detecting means is less than or equal to the predetermined remaining amount,
The display control means includes
The display device according to claim 6, wherein, instead of the meter unit, the display unit displays the rewritable number at the same position as the meter unit. Executed in a display device that includes a non-volatile display unit that requires power when rewriting an image being displayed and can retain the image even when power supply is cut off, and operates using a battery as a power source. A control program,
On the computer,
A display control step of controlling the display means and causing the display means to display the image;
A remaining amount detecting step for detecting the remaining amount of the battery;
Based on the remaining amount of the battery detected by the remaining amount detection step, to execute a rewrite count determination step that determines the number of possible rewrites, which is the number of times the image can be rewritten,
When the remaining amount of the battery detected by the remaining amount detecting step is less than a predetermined remaining amount,
The rewrite count determination step starts determination of the rewrite count,
The display control step displays the rewritable number on the display means,
When the remaining amount of the battery detected by the remaining amount detecting step is larger than the predetermined remaining amount,
The rewrite count determination step does not start determination of the rewrite enable count.

Images