JP2005107246A - Reflection type display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve easiness of viewing display when external light quantity is small while suppressing and preventing a feeling of physical disorder such that an image is displayed in a secluded place. <P>SOLUTION: This display device is provided with an electrophoretic panel 1 which has display screens capable of displaying specified images in both the front and back and a side light type lighting device 7 such that only the back-side display screen of the electrophoretic panel 1 is covered with a transparent light guide plate 8. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a reflective display device including a sidelight type illumination device that covers a display screen with a transparent light guide plate.

Conventionally, as such a technique, for example, a display medium having a display screen that can display a predetermined image only on the front surface, and a sidelight type illumination device that covers the display screen of the display medium with a transparent light guide plate, When the amount of external light that illuminates the display screen is small, light is incident on one end of the transparent light guide plate by the sidelight type illumination device, and the incident light is emitted to the transparent light guide plate from the back side and emitted. There is a reflective display device that illuminates a display screen with bright light (see, for example, Patent Document 1).
JP-A-10-142601

However, in the above-described conventional technology, the display screen of the display medium is covered with the transparent light guide plate, so that, for example, the amount of external light that illuminates the display screen is sufficiently large. When the display screen is not illuminated, there is a fear that the display of the image on the display screen is performed at a depth corresponding to the thickness of the transparent light guide plate.
The present invention aims to solve the above-mentioned unsolved problems of the prior art, and suppresses the uncomfortable feeling that the image display is performed in a deep place, while reducing the amount of external light. It is an object of the present invention to provide a reflective display device that can improve the visibility of display.

In order to solve the above-described problems, a reflective display device according to a first aspect of the present invention includes a display medium having a display screen capable of displaying a predetermined image on both the front surface and the back surface, and only one display screen of the display medium. And a sidelight type illumination device that covers the surface with a transparent light guide plate.
According to the first aspect of the invention, for example, when the amount of external light is sufficiently large and it is not necessary to illuminate the display screen with the sidelight type illumination device, the image of the other display screen without the transparent light guide plate covering the display screen Can prevent the user from feeling uncomfortable that the display is performed at the back of the display. For example, when the amount of external light that illuminates the display screen is small, the sidelight type illumination device The user can see the image of one of the display screens illuminated by the above, so that the visibility of the display can be improved.

In the reflective display device according to the second aspect of the invention, the display medium is an electrophoretic display in which a plurality of encapsulated regions enclosing charged particles of a predetermined color and a dispersion medium are visible from both the front surface and the back surface. It is characterized by being a medium.
According to the second aspect of the invention, for example, when the charged particles are of a single type, the charged particles are moved to one display screen side so that a predetermined image is displayed on one display screen of the display medium. Then, the dispersion medium moves to the other display screen side, and an image in which the gradation of the predetermined image is inverted and the left and right positions are inverted is displayed on the other display screen of the display medium. Therefore, compared with a method in which an image can be displayed on both the front surface and the back surface with one display medium, and the two single-sided display media for the front surface and the back surface are integrated into a single display medium. The structure can be simplified, and the thickness and weight of the apparatus can be reduced.

Furthermore, the reflective display device according to the third aspect of the invention includes a detecting means for detecting that the user is viewing the other display screen of the display medium, and the user is viewing the other display screen. And a gradation reversing means for reversing the gradation of the image displayed on the other display screen.
According to the third aspect of the invention, when the user is viewing the image displayed on the display screen on the front side of the display medium, the image displayed on the front side has a natural gradation, and the user can display the image. When viewing an image displayed on the display screen on the back side of the medium, the image displayed on the back side has a natural gradation, so that the user can use either the front side or the back side of the display medium. A natural gradation image can be seen.

According to a fourth aspect of the present invention, there is provided a reflective display device, wherein the detecting means detects that the user is viewing the other display screen of the display medium, and the user is viewing the other display screen. And a right / left reversing means for horizontally reversing the image displayed on the other display screen.
According to the fourth aspect of the invention, when the user is looking at the display screen on the front side of the display medium, the image displayed on the front side is a natural left-right arrangement, and the user can display the back side of the display medium. When viewing the image displayed on the screen, the image displayed on the back side is a natural left-right arrangement, so the user can select a natural left-right image from either the front side or the back side of the display medium. Can see.

Hereinafter, an embodiment of a reflective display device of the present invention will be described with reference to the drawings.
1A and 1B are diagrams illustrating a schematic configuration of a reflective display device according to an embodiment of the present invention, in which FIG. 1A is a front view, FIG. 1B is a right-side cross-sectional view, and FIG. It is. In FIG. 1, reference numeral 1 denotes an electrophoresis panel for displaying predetermined image data.
As shown in FIG. 2, which is an enlarged view of the main part of the electrophoresis panel 1 taken along line AA in FIG. 1, an electrophoresis dispersion liquid 2 composed of black charged particles 2a and a white dispersion medium 2b is provided. A plurality of microcapsules 3 are included in the central layer. A transparent common electrode 4 is disposed on the lower surface of the central layer, and a plurality of transparent pixel electrodes 5 are disposed on the upper surface in a matrix as shown in FIG. A plurality of pixels capable of displaying a predetermined image on both the front surface and the back surface are constituted by the microcapsule 3 sandwiched between the transparent common electrode 4 and the transparent common electrode 4, and the display screen of the electrophoretic panel 1 is constituted by the plurality of pixels. It is configured.

  A drive circuit 6 is disposed around the electrophoresis panel 1, and the drive circuit 6 displays a predetermined image on the front display screen of the electrophoresis panel 1 in accordance with a control signal output from a control device 10 described later. The transparent pixel electrode 5 is set to a predetermined potential so that each scanning line is drawn in a predetermined direction. Then, the potential of the predetermined transparent pixel electrode 5 is set to a high level so that a predetermined image is displayed on the display screen on the front side of the electrophoresis panel 1, and is sandwiched between the transparent pixel electrode 5 and the transparent common electrode 4. When the charged particles 2a of the microcapsule 3 are adsorbed on the transparent pixel electrode 5 side (front side) and the charged particles 2a are recognized from the pixels on the front side of the electrophoresis panel 1, a white dispersion medium is obtained. 2b is moved to the transparent common electrode 4 side (back side), and an image obtained by inverting the gradation of the predetermined image and inverting the left and right is displayed on the display screen on the back side of the electrophoresis panel 1.

As described above, in the reflective display device using the electrophoretic panel 1 of the present embodiment, images can be displayed on both the front surface and the back surface with one display medium, and two single-sided displays for the front surface and the back surface can be displayed. The structure of the apparatus can be simplified and the thickness and weight of the apparatus can be reduced as compared with a method in which the mold display media are integrated back to back into a single display medium.
Further, as shown in FIG. 2, a sidelight type illumination device 7 for illuminating a display screen on the back side of the electrophoresis panel 1 is disposed on the back side of the electrophoresis panel 1. This sidelight type illumination device 7 has a transparent light guide plate 8 that covers the display screen on the back side of the electrophoresis panel 1 and a light source 9 for making light incident on the end of the transparent light guide plate 8. Among these, the light source 9 controls the lighting state according to a control signal output from the control device 10 described later. Then, when the light source 9 is turned on and light is incident on the end portion of the transparent light guide plate 8 and the incident light is emitted from the back side of the transparent light guide plate 8, electrophoresis is performed by the emitted light. The display screen on the back side of the panel 1 is illuminated.

  As described above, according to the reflective display device of this embodiment, the sidelight type illumination device 7 that covers only the display screen on the back side of the electrophoresis panel 1 with the transparent light guide plate 8 is disposed. When the display screen does not need to be illuminated by the sidelight type illumination device 7, the user can view the display screen image on the front side without the transparent light guide plate covering the display screen. It is possible to suppress and prevent a sense of incongruity that the process is performed at a short time. Further, for example, when the amount of external light that illuminates the display screen is small, the user can see the image of the display screen on the back side illuminated by the sidelight type illumination device 7 to improve the visibility of the display. it can.

  Next, the control content performed by the control device 10 will be described with reference to the drawings. The control device 10 includes a microcomputer and its peripheral devices, and constitutes a control block shown in FIG. 4 in the form of a microcomputer software. The control block in FIG. 4 includes a display screen detection unit 11, a light source control unit 12, a gradation control unit 13, and a scanning control unit 14.

  Among these, the display screen detection unit 11 determines whether or not the display screen detection switch 15 is pressed, and when it is pressed, the user looks at the display screen on the back side of the electrophoresis panel 1. If the rear display flag F indicating that this is set to “1”, otherwise, the rear display flag F is reset to “0”, that is, the user looks at the display screen on the front side of the electrophoresis panel 1. It is in the state which shows that it exists. Here, the display screen detection switch 15 is a switch protruding from the housing of the reflective display device to the front side.

Further, the light source control unit 12 determines whether or not the rear display flag F is set to “1”, and when it is in the set state, the lighting control signal for lighting the light source 9 of the sidelight type illumination device 7. If not, a turn-off control signal for turning off the light source 9 of the sidelight type illumination device 7 is outputted.
Further, the gradation control unit 13 first reads raster data of a predetermined image stored in the storage device 16 one by one from the left in plan view for each scanning line, and then sets the rear display flag F to “1”. It is determined whether or not the read raster data is in a set state, and if it is in the set state, the read raster data is corrected and output so that the gradation of the image corresponding to the read raster data is inverted. In this case, the read raster data is output as it is. As a method of correcting the raster data so that the gradation of the image is inverted, for example, when the gradation of the image is represented by numerical values “0” to “255” of the raster data, the numerical value is “255”. And subtracting the result of the subtraction into new raster data.

  The scanning control unit 14 first determines whether or not the back display flag F is set to “1”. If the back display flag F is in the set state, the scanning direction is the left direction in plan view (hereinafter also referred to as the reverse direction). If not, the scanning direction is set to the right in the plan view (hereinafter also referred to as the forward direction). Next, a drive control signal for setting the transparent pixel electrode 5 to a predetermined potential so that an image corresponding to the raster data sequentially output from the gradation control unit 13 is drawn for each scanning line in the set scanning direction. Is output.

Next, the operation of the reflective display device of this embodiment will be described based on specific conditions.
First, it is assumed that the control block shown in FIG. 4 is executed by the control device 10 when the reflective display device is placed on the desk with the front side facing upward and the back side facing downward. Then, the display screen detection unit 11 resets the rear display flag F to “0”, the light source control unit 12 outputs a turn-off control signal, and the gradation control unit 13 stores it in the storage device 16. The raster data of the predetermined image is sequentially read one by one from the left in the plan view for each scanning line, and the read raster data is output as it is, and the scanning control unit 14 responds to the output raster data. A drive control signal for setting the transparent pixel electrode 5 to a predetermined potential is output to the drive circuit 6 so that the image is drawn in the forward direction for each scan line.

Then, the light source 9 is turned off in accordance with the outputted turn-off control signal, and a predetermined image is drawn in the forward direction one scanning line at a time on the display screen on the front side of the electrophoresis panel 1 in accordance with the drive control signal. The gradation and left-right arrangement of the image displayed on the front side of 1 are natural, and the user can see an image with natural gradation and left-right arrangement.
On the other hand, it is assumed that the control block shown in FIG. 4 is executed by the control device 10 when the reflective display device is placed on the desk with the back side facing upward and the front side facing downward. Then, the display screen detection unit 11 sets the rear display flag F to “1”, the light source control unit 12 outputs a lighting control signal, and the gradation control unit 13 stores the lighting control signal. Raster data of a predetermined image is read out one by one from the left in plan view for each scanning line, and the read raster data is read so that the gradation of the image corresponding to the read raster data is inverted. A drive control signal for setting the transparent pixel electrode 5 to a predetermined potential so that an image corresponding to the corrected raster data is drawn in the left direction, that is, in the reverse direction by the scan control unit 14 in the scan direction. Is output to the drive circuit 6.

  The light source 9 is turned on according to the output lighting control signal, the display screen on the front side of the electrophoresis panel 1 is illuminated, and a predetermined image is displayed on the display screen on the front side of the electrophoresis panel 1 according to the drive control signal. Is drawn in the reverse direction for each scanning line, the gradation and the left / right arrangement of the image displayed on the front display screen are reversed, and the gradation and the left / right arrangement of the image displayed on the rear display screen are reversed. It becomes natural and the user can see an image with natural gradation and left and right arrangement from the back side of the electrophoresis panel 1.

  As described above, according to the present embodiment, when the user is viewing the display screen on the front side of the electrophoresis panel 1, the image displayed on the front side is a natural left-right arrangement. When viewing the image displayed on the display screen on the back side of the display, the image displayed on the back side is a natural left and right arrangement, so that the user can view the image from either the front side or the back side of the display medium. You can see the right and left images.

In the above embodiment, the electrophoretic panel 1 forms a display medium, and similarly, the microcapsule 3 forms an encapsulated region, the display screen detection unit 11 forms detection means, and the gradation control unit 13 A gradation reversing unit is configured, and the scanning control unit 14 configures a left / right reversing unit.
Moreover, the said embodiment shows an example of the reflective display apparatus which concerns on this invention, The structure etc. are not limited.

  For example, an example in which a display screen is formed using the electrophoresis panel 1 has been shown, but the present invention is not limited to this. An apparatus using what can be used may be used.

It is a block diagram which shows one Embodiment of the reflection type display apparatus of this invention. It is a principal part enlarged view fractured | ruptured and shown in the AA cross section of FIG. It is a block diagram which fractures | ruptures and shows the electrophoresis panel of FIG. It is a block diagram which shows the arithmetic processing performed with the control apparatus of FIG.

Explanation of symbols

1 is an electrophoretic panel, 2 is an electrophoretic dispersion liquid, 3 is a microcapsule, 4 is a transparent common electrode, 5 is a transparent pixel electrode, 6 is a drive circuit, 7 is a sidelight illumination device, 8 is a transparent light guide plate, and 9 is Light source, 10 is a control device, 11 is a display screen detection unit, 12 is a light source control unit, 13 is a gradation control unit, 14 is a scanning control unit, and 15 is a display screen detection switch.

Claims (4)

  A display medium having a display screen capable of displaying a predetermined image on both the front surface and the back surface, and a sidelight type illumination device that covers only one display screen of the display medium with a transparent light guide plate. Reflective display device.   2. The electrophoretic display medium according to claim 1, wherein the display medium is an electrophoretic display medium in which a plurality of encapsulated regions enclosing charged particles of a predetermined color and a dispersion medium are visible from both the front surface and the back surface. Reflective display device.   Detection means for detecting that the user is looking at the other display screen of the display medium, and when it is detected that the user is looking at the other display screen, display on the other display screen The reflection type display device according to claim 2, further comprising a gradation inversion unit that inverts the gradation of the image being displayed.   Detection means for detecting that the user is looking at the other display screen of the display medium, and when it is detected that the user is looking at the other display screen, display on the other display screen 4. The reflection type display device according to claim 2, further comprising a left / right reversing unit for reversing a displayed image.

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