JP2006053206A - Reflection type display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To increase a power generating amount by a solar panel. <P>SOLUTION: When it is detected that a power input connector(not shown) of an external device(not shown) is inserted into a power supply connector 9, contents are displayed in pixels at a center section by making all the pixels of a circumferential section of a cholesteric liquid crystal panel 14 transparent. Thereby, a light amount transmitted through the cholesteric liquid crystal panel 14 is increased and an inputted light amount to the solar panel 15 is increased. As the power generating amount by the solar panel 15 is increased by increasing the inputted light amount, large power is stably supplied to the external device (not shown). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a reflective display device that performs display by reflecting incident light on the front side.

  Conventionally, as this type of reflective display device, a cholesteric liquid crystal panel that can switch between a focal conic state that transmits light and a planar state that reflects light for each pixel is arranged on the front side, and the cholesteric liquid crystal panel is transmitted through the front side. There is one in which a black solar cell panel that absorbs light is arranged on the back side. In such a reflective display device, the color of the solar cell panel (black) is displayed on a pixel that transmits light (transparent pixel), and the color of reflected light (white turbid color) is displayed on the pixel that reflects light. ) Is displayed, and as a result, an image including characters and the like is displayed on the front side.

Further, at that time, the light transmitted through the transparent pixels is incident on the solar cell panel, and the solar cell panel generates electric power by the incident light. As a result, the power source is used to drive the reflective display device. Electric energy is stored in the storage battery (for example, refer to Patent Document 1).
Special table 2003-513318

However, in the above-described conventional technology, the solar cell panel is configured to generate power with the light transmitted through the cholesteric liquid crystal panel, and thus the reflective display device includes black characters and a white background portion. When a black and white image is displayed, that is, when the number of pixels that transmit light is small, the amount of power generated by the solar cell panel may be reduced.
The present invention aims to solve the above-mentioned unsolved problems of the prior art, and is a reflective display device capable of increasing the power generation amount as required by the solar cell panel. It is an issue to provide.

  In order to solve the above-described problem, the reflective display device according to the first aspect of the present invention is configured such that a transmissive layer whose light transmittance can be set for each pixel is arranged on the front side, and light transmitted through the transmissive layer is transmitted to the back side. A reflection type display device that performs display by absorbing the solar cell panel disposed on the solar cell panel, a determination unit that determines whether or not the amount of power generated by the solar cell panel needs to be increased, and the determination unit Control means for controlling the light transmittance of the transmission layer based on the determination result. Examples of the transmissive layer include those having memory properties such as cholesteric liquid crystal panels and chiral nematic liquid crystal panels, and materials having no memory properties such as polymer dispersed liquid crystal panels. Furthermore, the necessity of increasing the amount of power generated by the solar cell panel includes, for example, one that is automatically generated when a predetermined condition is satisfied, and one that is manually generated by a user.

According to the first invention, when it is necessary to increase the amount of power generated by the solar cell panel, the amount of light transmitted through the transmission layer can be increased by increasing the light transmittance of the transmission layer. And the amount of electric power generated by the solar cell panel can be increased by increasing the amount of light incident on the solar cell panel and increasing the amount of incident light.
In the reflective display device according to the second aspect of the invention, when it is determined that the control means needs to increase the amount of power generated by the solar cell panel, the light transmission of all the pixels of the transmission layer is performed. It is characterized by maximizing the rate.

According to the second aspect of the invention, when it is necessary to increase the amount of power generated by the solar cell panel, the light incident from the front side is transmitted through the transmission layer and incident on the solar cell panel with almost the same intensity. The region (transparent region) can be expanded, and as a result, the amount of light incident on the solar cell panel can be increased.
Furthermore, in the reflective display device according to the third aspect of the invention, when it is determined that the control means needs to increase the amount of power generated by the solar battery panel, The light transmittance of the other pixels is controlled so that the light transmittance is maximized and the display is performed in the other pixels.

  According to the third aspect of the invention, when it is necessary to increase the amount of power generated by the solar cell panel, the light incident from the front side is transmitted through the transmission layer and transmitted to the solar cell panel with almost the same intensity. The area (transparent area) can be widened. As a result, the amount of light incident on the solar cell panel can be increased, and images such as characters and video can be displayed.

In the reflective display device according to the fourth aspect of the invention, when it is determined that the control means needs to increase the amount of power generated by the solar cell panel, the display is performed with gradation inversion. As described above, the light transmittance of the transmissive layer is controlled.
According to the fourth aspect of the invention, for example, when displaying a black and white image composed of black characters and a white background, that is, when the number of pixels (transparent pixels) that transmit light is small, By displaying in a reversed manner, the number of transparent pixels can be increased, and a region (transparent region) through which light incident on the transmissive layer is transmitted to the solar cell panel with almost the same intensity can be expanded.

Furthermore, in the reflective display device according to the fifth aspect of the present invention, the reflective display device includes a storage battery that stores the electrical energy generated by the solar battery panel, and the determination unit is configured to reduce a remaining battery capacity of the storage battery below a predetermined threshold value. It is determined that it is necessary to increase the amount of power generated by the solar cell panel.
According to the fifth aspect of the present invention, for example, when the battery remaining amount of the storage battery becomes smaller than a predetermined threshold, the amount of power generated by the solar battery panel can be increased, and the battery remaining amount of the storage battery can be increased beyond the predetermined threshold. Therefore, for example, when an external device or an internal circuit is electrically connected to the storage battery, power can be stably supplied to the connected external device or internal circuit.

In the reflective display device according to the sixth invention, the determination means determines that the amount of power generated by the solar cell panel needs to be increased when an external device is connected to the storage battery. It is characterized by.
According to the sixth aspect of the invention, for example, when an external device is connected to the storage battery, the amount of power generated by the solar cell panel can be increased, and a large amount of power can be stably supplied to the external device.

  Hereinafter, as an embodiment of the reflective display device of the present invention, an example applied to an electronic book reader for browsing a plurality of contents divided into predetermined pages will be described with reference to the drawings.

<First Embodiment>
This electronic book reader displays content including a black and white image composed of black characters and a white background, and is arranged on the front side to display content image data (characters and video included in the content). A cholesteric liquid crystal panel that makes a pixel (hereinafter, also referred to as “image data corresponding pixel”) that displays an image) transparent, and reflects incident light to a pixel that displays a background portion; And a content display unit including a solar cell panel that generates power by receiving light transmitted through the cholesteric liquid crystal panel. This electronic book reader uses a cholesteric liquid crystal panel when an external device is connected to a storage battery that stores electricity generated by a solar battery panel, and is used as an external power source having both portability and environmental performance (low environmental load). The amount of power generation can be increased by changing the light transmittance and changing the amount of light that passes through the cholesteric liquid crystal panel and enters the solar cell panel.

<Configuration of electronic book reader>
FIG. 1 is a schematic configuration diagram showing an appearance of the electronic book reader of the present embodiment. FIG. 2 is a block diagram showing the internal configuration of the present embodiment. As shown in FIG. 2, an electronic book reader 1 includes a page feed switch 2, an image data generation unit 3, an image data input I / F 4, a cholesteric LCD (Liquid Crystal Display) controller 5, a frame memory 6, a storage battery 7, a voltage The detection unit 8 includes a power supply connector 9, an insertion / extraction detection unit 10, a display changeover switch 11, a system controller 12, and a content display unit 13.

  As shown in FIG. 1, the page feed switch 2 is arranged in the lower right part of the front side in plan view and is formed in a round button shape that can be pushed by the user. Then, when the page feed switch 2 is pushed in, a command (hereinafter referred to as “page feed command”) for switching and displaying the content of the next page of the content that has been displayed on the content display unit 13 until then on the content display unit 13 is displayed. Is output to the image data generation unit 3.

Further, when a page feed command is output from the page feed switch 2, the image data generation unit 3 generates image data (raster data) of the content of the next page. Then, the image data generation unit 3 outputs the generated image data to the image data input I / F 4.
Further, when image data is output from the image data generation unit 3, the image data input I / F 4 inputs the output image data to the cholesteric LCD controller 5 and the frame memory 6.

  When the cholesteric LCD controller 5 outputs an all-pixel image display command (described later) from the system controller 12 or when image data is input from the image data input I / F 4, the content corresponding to the image data becomes the content. A command for driving a row driver 21 (described later) of the content display unit 13 (hereinafter also referred to as a “first row driver drive command”) and a column driver 22 ( A command (hereinafter also referred to as a “first column driver drive command”) for driving a later-described signal is generated. The cholesteric LCD controller 5 outputs the first row driver drive command and the first column driver drive command to the row driver 21 (described later) and the column driver 22 (described later) of the content display unit 13.

  Furthermore, when a reduced image display command (described later) is output from the system controller 12, the cholesteric LCD controller 5 displays the content corresponding to the image data input from the image data input I / F 4 in a reduced size on the central pixel. That is, an instruction to drive the row driver 21 (described later) of the content display unit 13 so that the outer peripheral pixel and the central image data corresponding pixel of the cholesteric liquid crystal panel 14 are transparent (maximum light transmittance). (Hereinafter also referred to as “second row driver drive command”) and a command for driving the column driver 22 (described later) (hereinafter also referred to as “second column driver drive command”). The cholesteric LCD controller 5 outputs the second row driver drive command and the second column driver drive command to the row driver 21 (described later) and the column driver 22 (described later) of the content display unit 13, respectively.

  Further, the cholesteric LCD controller 5 is configured so that when the all-pixel black display command (described later) is output from the system controller 12, black is displayed on all the pixels of the content display unit 13, that is, all the cholesteric liquid crystal panels 14 are displayed. A command for driving the row driver 21 (described later) of the content display unit 13 (hereinafter also referred to as “third row driver drive command”) and a column driver 22 (described later) are driven so that the pixels are transparent. A command (hereinafter also referred to as “third column driver drive command”) is generated. Then, the cholesteric LCD controller 5 outputs the third row driver drive command and the third column driver drive command to the row driver 21 (described later) and the column driver 22 (described later) of the content display unit 13, respectively.

Further, when image data is input from the image data I / F 4, the frame memory 6 stores the input image data (data for displaying an image included in one page of content). Then, the frame memory 6 causes the system controller 12 to read the stored image data in accordance with a read request from the system controller 12.
Furthermore, the storage battery 7 is a secondary battery such as a lithium ion battery, and stores electricity when supplied with electricity from a solar battery panel 15 (described later) of the content display unit 13. When the power input connector (not shown) of an external device (not shown) is connected to the power supply connector 9, the storage battery 7 is connected to the external device (not shown) via the power supply connector 9 or the power input connector (not shown). Electricity is supplied to (not shown). In addition, examples of the external device (not shown) include a device that uses a battery as a power source, such as a mobile phone terminal or other information terminal.

Further, the voltage detection unit 8 detects the output voltage of the storage battery 7. And the voltage detection part 8 outputs the detection result of the output voltage of the storage battery 7 to the system controller 12.
Further, as shown in FIG. 1, the power supply connector 9 is arranged at the lower part on the left side surface so that a power input connector (not shown) of an external device (not shown) can be inserted. Then, when the power input connector (not shown) of the external device (not shown) is inserted, the power supply connector 9 is connected to the external device (not shown) via the power input connector (not shown) as shown in FIG. ) Is electrically connected to the storage battery 7 of the electronic book reader 1.

The insertion / extraction detection unit 10 is a dedicated electrical contact that is short-circuited only when a power input connector (not shown) of an external device (not shown) is inserted, and the power input connector (not shown) supplies power. It is detected that the connector 9 is inserted or removed from the power supply connector 9. Then, the insertion / extraction detection unit 10 outputs the detection results to the system controller 12.
Further, as shown in FIG. 1, the display changeover switch 11 is arranged in the upper right part in a plan view on the front side, and is formed in a round button shape that can be pushed by the user. When the display changeover switch 11 is pushed in, the display changeover switch 11 outputs a command for switching between display and non-display of content (hereinafter also referred to as “display changeover command”) to the system controller 12.

  Further, when a display switching command is output from the display changeover switch 11, the system controller 12 executes a display area changing process (described later). The system controller 12 then displays the cholesteric of the content display unit 13 based on the detection result output from the insertion / extraction detection unit 10 and the display switching command output from the display changeover switch 11 by the display area changing process (described later). A command for changing the amount of light that passes through the liquid crystal panel 14 (described later) and enters the solar cell panel 15 (described later) is generated, and the generated command is output to the cholesteric LCD controller 5. In addition, as a command to change the amount of light incident on the solar cell panel 15 (described later), for example, the content is displayed on all the pixels of the content display unit 13 so that the amount of incident light (number of transparent pixels) is minimized. Voltage application command (all pixel image display command (described later)) to display the content, or to reduce the content to be displayed on the central pixel so that the amount of incident light is large (all the pixels on the outer periphery are transparent) Application command (reduced image display command (described later)), voltage application command (all pixel black display command (described later)) for displaying black on all pixels of the content display unit 13 so as to maximize the amount of incident light, etc. Can be mentioned.

  Furthermore, the content display part 13 is comprised including the cholesteric liquid crystal panel 14 and the solar cell panel 15, as shown to the side sectional drawing of FIG. As shown in FIG. 2, the cholesteric liquid crystal panel 14 is disposed in the central portion in plan view on the front side. As shown in FIG. 3, the cholesteric liquid crystal panel 14 includes a cholesteric liquid crystal layer 16 filled with cholesteric liquid crystal and a plurality of transparent electrodes (row electrodes 17 and column electrodes 18) sandwiching the upper and lower surfaces of the cholesteric liquid crystal layer 16. And glass plates 19 and 20 that encapsulate the cholesteric liquid crystal in the cholesteric liquid crystal layer 16 from the upper surface of the row electrode 17 and the lower surface of the column electrode 18. The row electrodes 17 are arranged in parallel with each other along the vertical direction in the plan view, and the column electrodes 18 are arranged in parallel with each other along the horizontal direction in the plan view. Pixels are formed.

  As shown in FIG. 2, the cholesteric liquid crystal panel 14 includes a row driver 21 disposed on the left side in plan view of the cholesteric liquid crystal layer 16 and a column driver 22 disposed on the upper side in plan view. The row driver 21 and the column driver 22 are connected to the first to third row driver driving commands and the first to third column driver driving outputs from the cholesteric LCD controller 5 via the row electrode 17 and the column electrode 18. A predetermined voltage is applied to an arbitrary pixel in accordance with the command.

  Furthermore, the solar cell panel 15 is disposed on the back side of the cholesteric liquid crystal panel 14 and generates power by receiving light incident through the cholesteric liquid crystal panel 14. The solar cell panel 15 supplies the generated electric energy to the storage battery 7. The solar cell panel 15 may be of any type as long as the front side is black, and examples thereof include a silicon type (single crystal, polycrystal, amorphous) and a dye sensitized type.

<Operation of system controller>
Next, the display area changing process executed by the system controller 12 will be described with reference to the flowchart of FIG. This display area changing process is a process that is executed when a display switching command is output from the display changeover switch 11. First, based on the detection result output from the insertion / extraction detection unit 10 in step S101, the display area changing process is performed. Whether the power input connector (not shown) of the device (not shown) has been inserted into or removed from the power supply connector 9, that is, whether the insertion / extraction state of the power input connector (not shown) has changed Determine whether or not. If the insertion / extraction state changes (Yes), the process proceeds to step S102. If not, that is, if the insertion / extraction state does not change (No), this step is repeatedly executed.

  In step S102, it is determined whether or not it is necessary to increase the amount of power generated by the solar battery panel 15. Specifically, based on the detection result output from the insertion / extraction detection unit 10, it is determined whether or not a power input connector (not shown) of an external device (not shown) is inserted into the power supply connector 9. If the power input connector (not shown) is inserted (Yes), the process proceeds to step S103. If not, that is, if the power input connector (not shown) is disconnected (No), the process proceeds to step S104. Transition.

In step S103, a command for reducing the content to be displayed on the center pixel of the content display unit 13 (hereinafter also referred to as “reduced image display command”) is output to the cholesteric LCD controller 5, and then the process proceeds to step S105.
On the other hand, in step S104, a command to display content on all the pixels of the content display unit 13 (hereinafter also referred to as “all pixel image display command”) is output to the cholesteric LCD controller 5, and then the process proceeds to step S105. To do.

In step S105, it is determined whether or not a display switching command is output from the display selector switch 11. When the display switching command is output (Yes), the process proceeds to step S106, and when it is not output (No), the process proceeds to step S101.
In step S106, a command for displaying black on all the pixels of the content display unit 13 (hereinafter, also referred to as “all pixel black display command”) is output to the cholesteric LCD controller 5, and the calculation process is terminated.

<Specific operation of electronic book reader>
Next, the operation of the electronic book reader 1 of the present embodiment will be described based on a specific situation.
First, it is assumed that after the display changeover switch 11 is pushed in, the page feed switch 2 is pushed down so that the electronic book reader 1 switches and displays the contents of the next page. Then, the display changeover switch 11 outputs a display change command to the system controller 12, and the system controller 12 executes the display area changing process. As shown in FIG. The determination is repeated.

Further, the page feed switch 2 outputs a page feed command to the image data generation unit 3, and the image data generation unit 3 generates image data of the content of the next page, and the image data is input to the image data input I / O. Output to F4. Then, the image data is input to the cholesteric LCD controller 5 by the image data input I / F 4.
Further, the cholesteric LCD controller 5 generates a first row driver drive command and a first column driver drive command based on the image data, and the first row driver drive command and the first column driver drive command. Are output to the row driver 21 and the column driver 22. Then, the row driver 21 and the column driver 22 apply a predetermined voltage to the image data corresponding pixels of the cholesteric liquid crystal panel 14 in accordance with the first row driver drive command and the first column driver drive command, as shown in FIG. As shown in the pixel a, the image data corresponding pixel is transparent, and as shown in the pixel b, the incident light is reflected by the pixel displaying the background portion. As a result, black is displayed on the transparent pixel, and the color of light reflected by the pixel (white turbid color) is displayed on the pixel for displaying the background portion, as shown in FIG. Content is displayed on all pixels of the content display unit 13.

  In addition, when content is displayed on all the pixels of the content display unit 13, light incident on the pixels that display the background portion of the content (pixels that occupy most of the area of the content display unit 13) is attenuated and transmitted. Light incident on the image data corresponding pixels (pixels occupying a small area of the content display unit 13) is transmitted with almost the same intensity, and the transmitted light is incident on the solar cell panel 15. Then, the solar cell panel 15 converts the incident light energy into electric energy, and the converted electric energy is stored in the storage battery 7.

  Here, it is assumed that the user inserts the power input connector (not shown) of the external device into the power supply connector 9 in order to charge the external device (not shown). Then, the insertion / extraction detection unit 10 detects that a power input connector (not shown) is inserted into the power supply connector 9, and the detection result is output to the system controller 12. Therefore, in the display area changing process, the determination in steps S101 and S102 is “Yes”, and a reduced image display command is output to the cholesteric LCD controller 5 in step S103. And determination of step S105 becomes "No" and the said flow is repeated from said step S101.

  The cholesteric LCD controller 5 generates a second row driver drive command and a second column driver drive command based on the image data input from the image data input I / F 4, and the generated second The row driver drive command and the second column driver drive command are output to the row driver 21 and the column driver 22. Then, according to the second row driver drive command and the second column driver drive command that are output by the row driver 21 and the column driver 22, the pixels on the outer peripheral portion of the cholesteric liquid crystal panel 14 correspond to the image data in the central portion. A predetermined voltage is applied to the pixel, the outer peripheral pixel and the central image data corresponding pixel are transparent (the light transmittance is maximized), and incident light is reflected by the pixel displaying the background ( Light transmission is minimized). As a result, black is displayed on the transparent pixel, and the color of light reflected by the pixel (white turbid color) is displayed on the pixel for displaying the background portion. As shown in FIG. The content is reduced and displayed on the central pixel of the section 13.

  When the content is displayed at the center pixel of the content display unit 13, the light incident on the pixel displaying the background portion of the content is attenuated and transmitted, and is incident on the outer peripheral pixel and the image data corresponding pixel. Light is transmitted with almost the same intensity, and light that has passed through them, that is, light that is stronger than when content is displayed on all the pixels of the content display unit 13 is incident on the solar cell panel 15. Then, the solar cell panel 15 converts the incident light energy into electric energy, and the converted electric energy is stored in the storage battery 7.

  As described above, in the electronic book reader 1 of the present embodiment, when it is detected that the power input connector (not shown) of the external device (not shown) is inserted into the power supply connector 9, the cholesteric liquid crystal panel. By increasing the light transmittance of 14, the amount of light transmitted through the cholesteric liquid crystal panel 14 can be increased. And by increasing the amount of light incident on the solar cell panel 15 and increasing the amount of incident light, the amount of power generated by the solar cell panel 15 can be increased. As a result, a large amount of power is supplied to an external device (not shown). Stable supply is possible.

  At that time, all the pixels on the outer periphery of the cholesteric liquid crystal panel 14 are made transparent (maximum light transmittance), and the light transmittance of the central pixel is controlled so that the content is displayed by the central pixel. I tried to do it. Therefore, it is possible to widen a transparent region on the outer peripheral portion, that is, a region where light incident on the cholesteric liquid crystal layer 16 is transmitted and incident on the solar cell panel 15 with almost the same intensity, and as a result, the solar cell panel The amount of light incident on 14 can be increased, and content including a black and white image can be displayed.

  Further, it is assumed that the display changeover switch 11 is pushed in while the above flow is repeated. Then, the display changeover command is output to the system controller 12 by the display changeover switch 11, the determination in the step S105 becomes "Yes", and after the all pixel black color display command is outputted in the step S106, this calculation process is finished. Is done. The cholesteric LCD controller 5 generates a third row driver drive command and a third column driver drive command. The third row driver drive command and the third column driver drive command are To the column driver 22. Then, the row driver 21 and the column driver 22 apply a predetermined voltage to all the pixels of the cholesteric liquid crystal panel 14 according to the third row driver drive command and the third column driver drive command, and all the pixels are transparent. Is done. As a result, black is displayed on the transparent pixels, and black is displayed on all the pixels of the content display unit 13 as shown in FIG.

  When black is displayed on all the pixels of the content display unit 13, the light incident on all the pixels is transmitted with almost the same intensity, and the transmitted light, that is, the content pixel is displayed on the central pixel of the content display unit 13. More intense light is incident on the solar cell panel 15 than when. Then, the solar cell panel 15 converts the incident strong light energy into large electric energy, and the converted large electric energy is sequentially stored in the storage battery 7.

  In the present embodiment, as shown in FIG. 4, after it is detected that the insertion / extraction state of the power input connector (not shown) has changed (step S101 “Yes”), the power input connector (not shown) is inserted. An example is shown in which it is determined whether or not it has been detected (step S102), and a reduced image display command (step S103) or an all-pixel image display command (step S104) is output. is not. For example, it is determined whether or not the remaining battery level of the storage battery 7 is smaller than a predetermined value (for example, an amount necessary to display all pages of the content), thereby reducing a reduced image display command (step S103) or displaying all pixel images. A command (step S104) may be output. Specifically, since the output voltage of the storage battery 7 decreases as the remaining battery level of the storage battery 7 decreases, detection of the output voltage of the storage battery 7 output from the voltage detection unit 8 as shown in step S101 ′ of FIG. It is determined whether the result is smaller than the threshold value Vth. If it is smaller than the threshold value Vth (Yes), the process proceeds to step S103, and if not, that is, if it is equal to or greater than the threshold value Vth (No), the process proceeds to step S104.

According to this modification, for example, when the battery remaining amount of the storage battery 7 becomes smaller than a predetermined value, the power generation amount by the solar battery panel 15 can be increased, and the battery remaining amount of the storage battery 7 can be increased from the predetermined value. . Therefore, for example, when an external device (not shown), an internal circuit, or the like is electrically connected to the storage battery 7, electric power can be stably supplied to the external device (not shown).
Furthermore, although an example in which content is reduced and displayed at the center of the content display unit 13 when it is detected that a power input connector (not shown) is inserted into the power supply connector 9, the present invention is limited to this. is not. For example, black may be displayed on all the pixels of the content display unit 13 (the light transmittance of all the pixels is maximized). By doing so, the incident light can be transmitted through the cholesteric liquid crystal panel 14, and the region (transparent region) that is incident on the solar cell panel 15 with almost the same intensity can be widened and incident on the solar cell panel 15. The amount of light can be increased.

In addition, although an example in which black is displayed on all the pixels of the content display unit 13 when the display switching switch 11 is pushed in and a display switching command is output has been shown, the present invention is not limited to this. For example, the content may be reduced and displayed on the center pixel of the content display unit 13, or the content may be displayed on all the pixels of the content display unit 13.
Furthermore, a state in which content is displayed on all the pixels of the content display unit 13, a state in which content is reduced and displayed on the center pixel of the content display unit 13, and a black color is displayed on all pixels of the content display unit 13 without displaying the content. Although an example in which one of three states having different states of pixels for displaying content is selected has been shown, the present invention is not limited to this. For example, a state having more stages can be taken. You may make it let.

  Furthermore, although the example which stores only the electrical energy generated with the solar cell panel 15 in the storage battery 7 was shown, it is not restricted to this. For example, in addition to the electricity generated by the solar cell panel 15, the power supplied from an external power source may be stored.

Second Embodiment
Next, a second embodiment of an electronic book reader to which the present invention is applied will be described.
The second embodiment differs from the first embodiment in that the display gradation is controlled instead of the content display area. Specifically, as shown in FIG. 8, steps S201 and S202 are arranged instead of step S103 of the display area changing process executed in the first embodiment, and step S203 is arranged instead of step S104. .
In addition, this 2nd Embodiment includes many structures and steps equivalent to the said 1st Embodiment, and attaches | subjects the same code | symbol to an equivalent structure etc., and abbreviate | omits the detailed description.

Further, when the normal gradation display command is output from the system controller 12, the cholesteric LCD controller 5 generates a first row driver drive command and a first column driver drive command. The cholesteric LCD controller 5 outputs the generated commands to the row driver 21 and the column driver 22, respectively.
Further, when the gradation reversal display command is output from the system controller 12, the cholesteric LCD controller 5 sets the light transmittance of the pixels having low light transmittance until then, and the pixels having high light transmittance. The light transmittance is set to be small. In other words, the cholesteric LCD controller 5 displays the black color on the pixels that had previously displayed white so that the content corresponding to the image data input from the image data I / F 4 is displayed in reverse video. A command for driving the row driver 21 (hereinafter, also referred to as “fourth row driver drive command”) and a column driver 22 so that white is displayed on the pixel to be displayed (so that brightness is displayed in reverse video). Is generated (hereinafter also referred to as a “fourth column driver drive command”). The cholesteric LCD controller 5 outputs the fourth row driver drive command and the fourth column driver drive command to the row driver 21 and the column driver 22, respectively.

  In step S201, the image data stored in the frame memory 6 is read, and the average brightness of all the pixels of the content displayed on the content display unit 13 is calculated based on the read image data. . Then, it is determined whether or not the calculated average value is equal to or greater than half the total number of gradations. If it is equal to or greater than half (Yes), the process proceeds to step S202, and if it is less than half. (No) Moves to step S105.

In step S202, a command for inverting the gradation on the content display unit 13 and displaying the content (hereinafter also referred to as “gradation reversal display command”) is output to the cholesteric LCD controller 5, and then in step S105. Transition.
On the other hand, in step S203, a command (hereinafter also referred to as “normal gradation display command”) for displaying content in the normal gradation on the content display unit 13 is output to the cholesteric LCD controller 5, and then in step S105. Migrate to

<Specific operation of electronic book reader>
Next, the operation of the electronic book reader 1 of the present embodiment will be described based on a specific situation.
First, the display area changing process is executed by the system controller 12, and the determination of step S101 is repeated as shown in FIG. 8, and as shown in FIG. Assume that the power input connector (not shown) of the external device is inserted into the power supply connector 9 in order to charge the external device (not shown) while the content is displayed. Then, the insertion / extraction detection unit 10 detects that a power input connector (not shown) is inserted into the power supply connector 9, and the detection result is output to the system controller 12.

  Therefore, in the display area changing process, the determination in steps S101 and S102 is “Yes”, and the average value of the brightness of all the pixels of the content displayed on the content display unit 13 is more than half the total number of gradations. If there is, that is, if the number of pixels displaying the background is greater than or equal to half the total number of pixels, the determination in step S201 is “Yes”, and in step S202, the gradation inversion display command is a cholesteric LCD. It is output to the controller 5, the determination in step S105 is "No", and the above flow is repeated from step S101. The cholesteric LCD controller 5 generates a fourth row driver drive command and a fourth column driver drive command based on the image data input from the image data input I / F 4, and the fourth row driver drive. The command and the fourth column driver drive command are output to the row driver 21 and the column driver 22. Then, according to the fourth row driver drive command and the fourth column driver drive command, the row driver 21 and the column driver 22 apply a predetermined voltage to the pixel that has displayed the background portion until then, and Is transparent, and the color of light reflected by the pixel (white turbid color) is displayed on the image data corresponding pixel. As a result, black is displayed on the transparent pixels, so that the content is displayed in reverse on the content display unit 13 as shown in FIG. 9B.

  Further, when the content is displayed in reverse on the content display unit 13, the light incident on the pixel that has been displaying the background portion of the content is transmitted with almost the same intensity, and the pixel corresponding to the image data up to that point is displayed. The light incident on the light is weakened and transmitted, and the light transmitted through the light, that is, the light that is stronger than the content displayed on the content display unit 13 at a normal gradation, enters the solar cell panel 15. Then, the solar cell panel 15 converts the incident light energy into electric energy, and the electric energy is stored in the storage battery 7.

  As described above, in the electronic book reader 1 of the present embodiment, for example, when displaying a black and white image composed of black characters and a white background, that is, a pixel that transmits light (transparent pixel). In the case where the number of light beams is small, the display is reversed in gradation, thereby increasing the number of transparent pixels, allowing incident light to pass through the transmission layer, and entering the solar cell panel 15 with almost the same intensity. The area to be made (transparent area) can be expanded. Therefore, when it is detected that a power input connector (not shown) of an external device (not shown) is inserted into the power supply connector 9, the amount of light transmitted through the cholesteric liquid crystal panel 14 can be increased, and the solar cell panel 15 The amount of power generated by the solar battery panel 15 can be increased by increasing the amount of incident light and the amount of incident light can be increased, and large power can be stably supplied to an external device (not shown).

  In the present embodiment, as shown in FIG. 8, after detecting that the insertion / extraction state of the power input connector (not shown) has changed (step S101 “Yes”), the power input connector (not shown) is inserted. Although an example in which a gradation inversion display command (step S202) or a normal gradation display command (step S203) is output by determining whether or not it has been detected (step S102) is shown. It is not a thing. For example, as in the first embodiment, the gradation reversal display command (step S202) or the normal gradation display command (step S203) is determined by determining whether or not the remaining battery level of the storage battery 7 is smaller than a predetermined value. You may make it output. Specifically, since the output voltage of the storage battery 7 decreases as the remaining battery level of the storage battery 7 decreases, detection of the output voltage of the storage battery 7 output from the voltage detection unit 8 as shown in step S101 ′ of FIG. It is determined whether the result is smaller than the threshold value Vth. If it is smaller than the threshold value Vth (Yes), the process proceeds to step S201. If not, that is, if it is equal to or greater than the threshold value Vth (No), the process proceeds to step S203.

  As described above, in the above-described embodiment, the cholesteric liquid crystal panel 14 in FIG. 3, the cholesteric liquid crystal layer 16, the row electrode 17, the column electrode 18, and the glass plates 19 and 20 in FIG. The cholesteric LCD controller 5, system controller 12, voltage detection unit 8 and insertion / extraction detection unit 10, row driver 21, column driver 22, step S103 in FIGS. 4 and 7 and step S202 in FIGS. Configure.

  The reflective display device of the present invention is not limited to the contents of the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.

It is a schematic structure figure showing the appearance of the electronic book reader of a 1st embodiment. It is a block diagram which shows the internal structure of an electronic book reader. It is side surface sectional drawing which fractures | ruptures and shows the side surface of a content display part. It is a flowchart of the display area change process of 1st Embodiment. It is explanatory drawing for demonstrating operation | movement of the electronic book reader of 1st Embodiment. It is explanatory drawing for demonstrating operation | movement of the electronic book reader of 1st Embodiment. It is a flowchart for demonstrating the modification of 1st Embodiment. It is a flowchart of the display area change process of 2nd Embodiment. It is explanatory drawing for demonstrating operation | movement of the electronic book reader of 2nd Embodiment. It is a flowchart for demonstrating the modification of 2nd Embodiment.

Explanation of symbols

1 is an electronic book reader, 2 is a page feed switch, 3 is an image data generation unit, 4 is an image data input I / F, 5 is a cholesteric LCD controller, 6 is a frame memory, 7 is a storage battery, 8 is a voltage detection unit, 9 Is a power supply connector, 10 is an insertion / extraction detection unit, 11 is a display changeover switch, 12 is a system controller, 13 is a content display unit, 14 is a cholesteric liquid crystal panel, 15 is a solar cell panel, 16 is a cholesteric liquid crystal layer, and 17 is a row electrode , 18 are column electrodes, 19 and 20 are glass plates, 21 is a row driver, and 22 is a column driver.

Claims (6)

  This is a reflective display device that has a transmissive layer that can set the light transmittance for each pixel on the front side and displays the light by transmitting the light transmitted through the transmissive layer to the solar cell panel that is arranged on the back side. And determining means for determining whether or not it is necessary to increase the amount of power generated by the solar cell panel, and control means for controlling the light transmittance of the transmissive layer based on the determination result by the determining means. A reflective display device characterized by that.   2. The reflection according to claim 1, wherein when it is determined that the amount of power generated by the solar cell panel needs to be increased, the control unit maximizes the light transmittance of all the pixels of the transmission layer. Type display device.   When it is determined that the amount of power generated by the solar cell panel needs to be increased, the control means maximizes the light transmittance of some pixels of the transmissive layer, and the display is performed at other pixels. The reflective display device according to claim 1, wherein the light transmittance of the other pixels is controlled.   When it is determined that the amount of power generated by the solar cell panel needs to be increased, the control means controls the light transmittance of the transmissive layer so that the display is performed with gradation inversion. The reflective display device according to claim 1.   A storage battery for storing electrical energy generated by the solar battery panel is provided, and the determination unit determines that the amount of power generated by the solar battery panel needs to be increased when a remaining battery capacity of the storage battery becomes smaller than a predetermined threshold value. The reflective display device according to claim 1, wherein the reflective display device is a reflective display device.   The said determination means determines that it is necessary to increase the electric power generation amount by the said solar cell panel, if an external apparatus is connected to the said storage battery, The any one of Claim 1 to 5 characterized by the above-mentioned. Reflective display device.

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