JP2014021434A - Image display device, image display system, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve convenience by combining a plurality of devices to arrange the devices.SOLUTION: An image display device 100A comprises: a display part 110A that electronically displays an image; a power generation part 120A that generates power from light and outputs the power; and a judgement part 192A that judges visibility of the image displayed by the display part 110A on the basis of an output value of the power generation part 120A.

Description

  The present invention relates to an image display device, an image display system, and a program.

Among image display devices typified by digital photo frames, some include a display unit and a solar battery. An image display device including a display unit and a solar cell displays a desired image or the like on the display unit using electric power generated by the solar cell.
In addition, a method has been devised in which a plurality of image display devices are arranged close to each other so that images displayed on the respective image display devices are displayed as a continuous and harmonious display as a whole. 1).

JP 2012-98835 A

However, when a plurality of image display devices are combined and arranged as desired by the user, for example, the image display device that is hidden behind other image display devices and the provided display unit cannot be seen, and the provided solar cell has sufficient power. There is a possibility that an image display device that cannot generate electricity is generated.
The present invention has been made to solve the above problems, and an object of the present invention is to provide an image display device, an image display system, and a program that enhance convenience by arranging a plurality of units in combination.

  The present invention has been made to solve the above-described problems. The present invention relates to a display unit that electronically displays an image, a power generation unit that generates and outputs power from light, and an output of the power generation unit. An image display device comprising: a determination unit that determines the visibility of an image displayed on the display unit based on a value.

  According to the present invention, a power receiving method between the plurality of image display devices is determined according to the plurality of image display devices described above and a determination result by the determination unit, and the power is determined according to the determined receiving method. And an electric power control unit for controlling the exchange of the image display system.

  Further, the present invention provides a computer provided in the image display device, wherein the display unit electronically displays an image, the power generation unit generates power from light, and the output value of the power generation unit, The program for performing the step which determines the visibility of the image which the display part displayed.

  According to the present invention, it is possible to provide an image display device, an image display system, and a program that enhance convenience by arranging a plurality of units in combination.

It is a figure which shows the image display system in this embodiment. It is a figure which shows the structure of the image display system in this embodiment. It is a figure which shows the structure of the image display apparatus in this embodiment, and the combination of two image display apparatuses. It is a figure which shows the structure of the image display apparatus in this embodiment, and the combination of two image display apparatuses. It is a figure which shows the combination of five image display apparatuses in this embodiment. It is a figure which shows the example of a setting of the priority which displays an image. It is a flowchart of the image display control process in this embodiment. It is a figure which shows the structure of the image display apparatus in this embodiment, and the combination of two image display apparatuses.

(First embodiment)
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
The image display system according to this embodiment generates power from light by a power generation unit, and the convenience of an image display device that electronically displays an image on the display unit using the generated power is provided with a plurality of image display devices. It is enhanced by arranging them in combination. In this image display system, a plurality of image display devices are arranged in combination by determining the visibility of an image displayed on the display unit based on the output value of the power generation unit that outputs the generated power. Increase convenience.

FIG. 1 is a diagram showing an image display system in the present embodiment.
The image display system 1 shown in FIG. 1 displays information (images) using a plurality of image display devices.
As a plurality of image display devices included in the image display system 1, image display devices 100A, 100B, and 100C (hereinafter simply referred to as “image display device 100” when collectively shown) are shown.

The housing 50A of the image display device 100A is provided with a display surface 11A of the display unit 110A (FIG. 3) and a light receiving surface 12A of the power generation unit 120A (FIG. 3) on the surface of the housing 50A. For example, the display surface 11A and the light receiving surface 12A are provided on the same surface (front surface 51A (FIG. 3)) of the housing 50A configured as a polyhedron, and the display surface 11A and the light receiving surface 12A are respectively modulo. The direction of the line is substantially the same. Each side of the display surface A is surrounded by the light receiving surface 12A. In short, the light receiving surface 12A becomes a frame portion surrounding the display surface 11A in the image display device 100A (photo frame).
Similar to the image display device 100A, the housing 50B of the image display device 100B is provided with a display surface 11B and a light receiving surface 12B on the surface of the housing 50B.
Similar to the image display device 100A, the housing 50C of the image display device 100C is provided with a display surface 11C and a light receiving surface 12C on the surface of the housing 50C.

  Such an image display apparatus 100 can be disposed at any position required by the user, and may be provided adjacent to each other. For example, as shown in the figure, the image display device 100A, the image display device 100B, and the image display device 100C are arranged while being shifted in the normal direction of the display surface 11C of the image display device 100C, and further the image display device 100A. The image display device 100B and the image display device 100C may be arranged so as to block part of the display surface and the light receiving surface. For example, a state in which a part of each display surface or light receiving surface of the image display device 100C is blocked is a plan view of the display surface 11C from the normal direction, and a part of the display surface 11C or the light receiving surface 12C is This means a state where the image display device 100A and the image display device 100B are arranged so as to overlap with the housing.

With reference to FIG. 2, the structure of the image display system in this embodiment is demonstrated.
FIG. 2 is a diagram showing a configuration of the image display system in the present embodiment.
The image display system 1 shown in FIG. 2 includes image display devices 100A, 100B, and 100C. Note that the image display apparatuses 100A, 100B, and 100C have the same configuration, and each configuration is distinguished by adding “A”, “B”, and “C” after the reference numerals. In the following description, the image display device 100A will be described as a representative, and the detailed description of the image display devices 100B and 100C common to the description of the image display device 100A will be omitted.

The image display apparatus 100A includes a display unit 110A, a power generation unit 120A, a power supply unit 130A, a detection unit 125A, a power storage unit 140A, a power exchange unit 150A, a communication unit 160A, an operation unit 170A, a storage unit 180A, and a control unit 190A.
Display unit 110A electronically displays a desired image on display surface 11A.
The display unit 110A in the present embodiment is so-called electronic paper. The electronic paper can reduce power consumption other than the period for updating the image, and thus is suitable for a case where power saving is required in the period for holding the displayed image. Note that a liquid crystal display panel, an LED display panel, an EL display panel, or the like can be applied to the display portion 110A. The desired image to be displayed on display unit 110A may be an image based on image information supplied from the outside of image display device 100A, or based on image information stored in advance in image display device 100A. It may be an image.

The power generation unit 120A generates electric power from the light received on the light receiving surface 12A and outputs it.
120 A of electric power generation parts in this embodiment are solar cells which have a several cell, for example, and electric power generation amount changes according to the illumination intensity of a light-receiving surface, and a light-receiving area. Note that the light that generates power may be light of a predetermined light amount that is emitted from the outside of the image display device 100A regardless of whether it is natural light or artificial light. The power generation unit 120A only needs to generate power from light, and is not limited to a solar cell.

The detection unit 125A detects the output value of the power generation unit 120A. The output value of the power generation unit 120A detected by the detection unit 125A is a value indicated by a physical quantity (information) that changes in accordance with the amount of power generated from light. For example, the output value of the power generation unit 120A may be a value indicating the amount of power generated from light, or may be a value indicating the voltage or current of power generated from light. The output value may not be the value of the electric energy, the voltage, and the current itself, but may be a value that changes according to the electric energy.
Alternatively, the output value of the power generation unit 120A detected by the detection unit 125A is the amount of power stored in the power storage unit 140A when the power generated from light by the power generation unit 120A is stored in the power storage unit 140A. It may be a value indicated by information according to. The output value may not be the value of the charged amount itself, but may be a value that changes according to the charged amount.

The power supply unit 130A receives the supply of power generated from light by the power generation unit 120A, or receives the supply of power from the other image display devices 100B and 100C via the power exchange unit 150A. The image data is supplied to each part of the image display device 100A. A part of the electric power supplied to each unit is stored in power storage unit 140A.
The power storage unit 140A stores the power generated by the power generation unit 120A from light or a part of the power supplied from the other image display devices 100B and 100C. For example, the power storage unit 140A is a variety of secondary batteries or capacitance elements (capacitors).
The power exchanging unit 150A exchanges power with another image display device different from the self-image display device among the plurality of image display devices.
For example, the power exchanging unit 150A receives an electromagnetic wave having a predetermined frequency and outputs an electromagnetic wave having a predetermined frequency, converts the energy supplied by the received electromagnetic wave into electric power, and outputs the electric power. A power conversion unit.
Alternatively, the power exchanging unit 150A receives the light having the predetermined wavelength and the light transmitting unit that outputs the light having the predetermined wavelength with the predetermined light intensity, and converts the energy supplied by the received light into electric power. An output power converter. Note that the power conversion unit in the power exchange unit 150A may be configured by switching some cells included in the power generation unit 120A. The predetermined wavelength can avoid unnecessary light irradiation in the vicinity of the image display device 100 by using light other than visible light (for example, infrared light).

  The communication unit 160A communicates with other image display devices 100B and 100C. For example, the communication unit 160A receives the output values of the power generation units 120B and 120C included in the other image display devices 100B and 100C, respectively, according to the communication processing by the communication processing unit 196A. In addition, the communication unit 160A transmits the output value of the power generation unit 120A to the other image display devices 100B, 100C, and the like according to the communication processing by the communication processing unit 196A. Note that the communication means of the communication unit 160A is preferably wireless communication that does not require wiring, and general means suitable for short-range communication such as wireless LAN, Bluetooth (registered trademark), infrared light communication, and the like. Conceivable.

Based on a user operation, the operation unit 170A detects registration information of various setting items in the image display device 100A, input information that specifies an operation state in the image display device 100A, and the like, and stores the detected information in the storage unit 180A. Remember me.
The storage unit 180A includes a storage area of a semiconductor memory in its configuration, and includes registration information of various setting items in the image display device 100A, input information for designating operations in the image display device 100A, configuration information in the image display system 1, and the like. Remember.

The control unit 190A includes a display control unit 191A, a determination unit 192A, a power control unit 193A, a combination display control unit 194A, and a communication processing unit 196A.
The display control unit 191A controls the display of an image on the display unit 110A according to the determination result by the determination unit 192A.
For example, the display control unit 191A controls the display of an image on the display unit 110A according to the priority order determined according to the determination result by the determination unit 192A.
Alternatively, the display control unit 191A may control the update of the image display on the display unit 110A according to the update frequency determined according to the determination result by the determination unit 192A.
As a more specific process, there is a case where display is performed according to a predetermined sequence. In other words, the process according to the predetermined sequence means a process of sequentially switching a plurality of images such as a slide show. If the image display device 100 is a device such as a photo frame intended for a general user, the displayed image is a photographed image taken by an individual, and uses commercial information such as signage. In the case of this apparatus, content images intended for advertisement are subject to slide show reproduction.

The determination unit 192A determines the visibility of the image displayed on the display unit 110A based on the output value of the power generation unit 120A detected by the detection unit 125A.
The visibility of the image displayed on the display unit 110A in the present embodiment indicates an index that indicates the visibility of the image displayed on the display unit 110A. For example, the state where the display area of the display unit 110A is not shielded. Make the state highly visible.
In the above-described visibility determination, when the output value of the power generation unit 120A is a value indicated by information that changes according to the amount of power generated from light, the determination unit 192A includes information that changes according to the amount of power. The visibility of the image displayed on the display unit 110A is determined based on the value indicated by.
As a more specific example, when the output value of the power generation unit 120A is a value indicating the amount of power generated from light, the determination unit 192A, based on the value indicating the amount of power generated from light, The visibility of the image displayed on the display unit 110A is determined.

The determination unit 192A is based on the output values of the power generation units 120B and 120C included in the image display devices 100B and 100C collected by the communication processing unit 196A and the output values of the power generation unit 120A. The combination state of each image display device is determined, and the visibility of the image displayed by the display unit 110A is determined based on the determination result.
Based on the output value of the power generation unit 120A detected by the detection unit 125A, the determination unit 192A uses at least a part of the light receiving surface 12A and at least a part of the display surface 11A by the housing 50A of the image display device other than its own device. Judged to be covered.
Note that the determination unit 192A determines that at least a part of the display surface 11A is covered with the casing 50A of the image display device other than its own device based on the output value of the power generation unit 120A detected by the detection unit 125A. May be.
The determination unit 192A displays the image displayed by the display unit 110A according to the state in which the fitting unit provided in the housing of the other image display devices 100B and 100C and the fitting unit provided in the housing 50A are fitted together. Visibility is determined. Details will be described later.

The power control unit 193A determines a power receiving method with another image display device according to the determination result by the determination unit 192A, and controls the power exchange according to the determined receiving method.
The combination display control unit 194A determines a display method of an image to be displayed on each display unit according to the determination result by the determination unit 192A.
For example, the combination display control unit 194A determines the priority order of images to be displayed on each display unit according to the determination result by the determination unit 192A.
Alternatively, the combination display control unit 194A determines the frequency at which the display of the image is updated in each display unit according to the determination result by the determination unit 192A.

  The communication processing unit 196A communicates with other image display devices 100B and 100C through the communication unit 160A. For example, the communication processing unit 196A requests the other image display devices 100B and 100C to transmit the output values of the power generation units 120B and 120C included in the other image display devices 100B and 100C, and displays other image displays. The output values of power generation units 120B and 120C included in devices 100B and 100C, respectively, are received. In addition, the communication processing unit 196A transmits the output value of the power generation unit 120A to the other image display devices 100B and 100C.

The image display device 100B includes a display unit 110B, a power generation unit 120B, a power supply unit 130B, a detection unit 125B, a power storage unit 140B, a power exchange unit 150B, a communication unit 160B, an operation unit 170B, a storage unit 180B, and a control unit 190B.
Description of the internal configuration of the image display device 100C is omitted.

Next, with reference to FIGS. 3-6, the structural feature of the image display apparatus in the present embodiment will be described, and a mode in which the image display apparatus is combined and arranged will be described.
[One implementation in the first embodiment]
With reference to FIG. 3, one implementation in this embodiment is shown.
FIG. 3 is a diagram showing the structure of the image display device and the combination of the two image display devices in the present embodiment.
FIG. 3 shows image display devices 100A and 100B.

3A is a diagram seen from the front surface 51A side of the housing 50A provided with the display surface 11A, and FIG. 3B is a diagram seen from the rear surface 52A side of the housing 50A. 3C is a cross-sectional view taken along YY ′ in FIG. 3A, and FIG. 3D is a diagram in which the state in which the image display devices 100A and 100B are combined is viewed from the front 51A side. It is.
With the housing 50A in this figure as a rectangular parallelepiped, the normal direction of the display surface 11A is defined as the X axis, and the Y axis and the Z axis are defined in directions along the orthogonal sides of the display surface 11A. The following description will be given on the basis of the orthogonal coordinate system based on the X, Y, and Z axes thus determined.
The image display devices 100A and 100B shown in this figure are arranged with the positions of the front surface 51A and the front surface 51B aligned in the X-axis direction, and the normal directions of the front surface 51A and the front surface 51B are the same as those of the X-axis. Is directed in the direction.

The display surface 11A and the light receiving surface 12A are provided on the front surface 51A of the housing 50A.
A plurality of convex portions 58A are provided on the upper surface 53A of the housing 50A at a predetermined interval (interval D).
A plurality of fitting holes 57A (not shown) are provided on the lower surface 54A of the housing 50A at a predetermined interval (interval D).
A plurality of fitting holes 57A are provided on the side surface 55A, which is one side surface of the housing 50A, at a predetermined interval (interval D).
A plurality of convex portions 58A are provided on the side surface 56A, which is the other side surface of the housing 50A, at a predetermined interval (interval D).
A base member 60A is provided at the center of the back surface 52A of the housing 50A, and the base member 60A is arranged so that the center of gravity G ′ of the base member 60A and the center of gravity G of the housing 50A are aligned in the X-axis direction. .

The base member 60A is a rectangular parallelepiped smaller than the housing 50A, and is arranged so that the direction of each side of the housing 50A is parallel to the direction of each side of the base member 60A.
A plurality of convex portions 68A are provided on the upper surface 63A of the base member 60A at a predetermined interval (interval D).
A plurality of fitting holes 67A (not shown) are provided on the lower surface 64A of the base member 60A at a predetermined interval (interval D).
A plurality of fitting holes 67A are provided on the side surface 65A, which is one side surface of the base member 60A, at a predetermined interval (interval D).
On the side surface 66A, which is the other side surface of the base member 60A, a plurality of convex portions 68A are provided at a predetermined interval (interval D).

The spacing between the fitting holes 57A, the spacing between the convex portions 58A, the spacing between the fitting holes 67A, and the spacing between the convex portions 68A are set to the same value (spacing D), and are arranged at equal intervals. Yes. Therefore, if two image display devices 100A are provided side by side in the Z-axis direction, the convex portion 58A provided on one upper surface 53A engages with the fitting hole 57A provided on the other lower surface 54A. Further, if two image display devices 100A are provided side by side in the Y-axis direction, the convex portion 58A provided on one side surface 56A engages with the fitting hole 57A provided on the other side surface 55A.
In short, the image display device 100B having the same configuration as the image display device 100A and the image display device 100A are arranged side by side in the Y-axis direction with the front 51A and the front 51B aligned in the same position in the X-axis direction. In the case (see FIGS. (C) and (d)), the convex portion 58A provided on the side surface 56A of the image display device 100A engages with the fitting hole 57B provided on the side surface 55B of the image display device 100B.
As described above, the display surface 11A is provided in the same direction as the direction in which the light receiving surface 12A is provided with respect to the housing 50A.

[First Modification of One Embodiment in First Embodiment]
With reference to FIG. 4, the 1st modification of one implementation in this embodiment is shown.
FIG. 4 is a diagram showing the structure of the image display device and the combination of two image display devices in the present embodiment.
FIG. 4 shows the image display devices 100A and 100B, and the image display devices 100A and 100B shown in the above-described drawings are arranged with the positions of the front surface 51A and the front surface 51B aligned in the X-axis direction. In contrast, the positions of the front surface 51A and the front surface 51B are shifted by a predetermined amount in the X-axis direction.

  4A is a view seen from the front 51A side of the housing 50A on which the display surface 11A is provided, and FIG. 4B is a cross-section taken along YY ′ in FIG. 4A. FIG. 4D is a diagram in which the state in which the image display devices 100A and 100B are combined is viewed from the front 51A side.

As described above, the intervals between the fitting holes 57A, the intervals between the convex portions 58A, the intervals between the fitting holes 67A, and the intervals between the convex portions 68A are all set to the same distance, and are arranged at equal intervals.
Therefore, if the two image display devices 100A are arranged side by side in the Z-axis direction after the positions of the front surface 51A and the front surface 51B are shifted by a predetermined amount in the X-axis direction, the protrusions provided on one upper surface 53A. The portion 58A is fitted into a fitting hole 67A provided on the other lower surface 64A. Further, if two image display devices 100A are provided side by side in the Y-axis direction, the convex portion 68A provided on one side surface 66A engages with the fitting hole 57A provided on the other side surface 55A.
In short, the image display device 100B having the same configuration as the image display device 100A and the image display device 100A are arranged side by side in the Y-axis direction after the positions of the front 51A and the front 51B are shifted by a predetermined amount in the X-axis direction. In the case (see FIGS. 4B and 4C), the convex portion 68A provided on the side surface 66A of the image display device 100A engages with the fitting hole 57B provided on the side surface 55B of the image display device 100B.
Thus, even if the positions of the front surface 51A and the front surface 51B are shifted by a predetermined amount in the X-axis direction, the image display devices 100A and 100B are provided by providing the base member 60A at the center of the back surface 52A of the housing 50A. Can be easily formed.

However, since the position of the side surface 66A is provided in the negative direction of the Y-axis so as to be separated from the position of the side surface 56A, the front surface 51B of the image display device 100B is placed on the image display device 100A as shown in the region Z1. The housing 50A is disposed so as to cover it. As a result, the area where the light receiving surface 12B can receive light decreases. Further, as the size of the base member 60A is reduced, the position of the side surface 66A is provided further away from the position of the side surface 56A in the negative direction of the Y axis, and as shown in the region Z2, the image display is performed. The display surface 11B provided on the front surface 51B of the device 100B is also disposed so as to be covered by the housing 50A of the image display device 100A.
As described above, since the size of the housing 50A and the size of the base member 60A are determined in advance, the widths of the regions Z1 and Z2 when the image display devices 100A and 100B are arranged in combination are easily calculated. It becomes possible to do.
In other words, if the illuminance at the front of the image display devices 100A and 100B arranged side by side is equal, a difference in the amount of power generation occurs according to the difference in the light receiving area. It becomes possible to detect the arrangement relationship between the devices 100A and 100B.

[Second Modification of One Embodiment in First Embodiment]
With reference to FIGS. 5-6, the 2nd modification of one implementation in this embodiment is shown.
FIG. 5 is a diagram showing a combination of five image display devices in the present embodiment.
FIG. 5 shows image display devices 100A, 100B, 100C, 100D, and 100E. Like the image display devices 100A and 100B shown in the above-described drawings, the front surface 51A and the front surface 51B in the X-axis direction are shown. The positions of 51C, 51D, and 51E are shifted by a predetermined amount. Of the five image display devices 100, two of the image display devices 100B and 100D indicate a state in which the other three image display devices 100 are rotated 90 degrees with respect to the X axis.

Here, the case where the priority for displaying an image on each of the five image display devices is set will be described. Here, by setting the priority for displaying images, it is possible to limit the display when the amount of power that can be supplied to the five image display devices is reduced according to the set priority.
FIG. 6 is a diagram illustrating an example of setting the priority for displaying an image.
For example, the highest priority is set for the image display device 100A arranged in the center. The priority of the image display devices 100B and 100C arranged on the left and right of the image display device 100A is set next to the priority of the image display device 100A. The priority of the image display device 100D disposed above the image display device 100A is set to be the second highest after the priority of the image display devices 100B and 100C. The priority of the image display device 100E arranged below the image display device 100A is set to the next higher priority than the priority of the image display device 100D. In other words, the priority of the image display device 100E is the lowest priority among the five image display devices.
In the setting example shown in this figure, eight display states are defined according to the priority set as described above. The state where the display is performed is indicated by “circle”, the state where the display is continued while reducing power consumption is indicated by “triangular mark”, and the state where the display is interrupted and no power consumption occurs is indicated by “square”. Indicated by. This setting example indicates that as the number indicated as the display state increases, it is necessary to increase the amount of power consumption reduction.

With reference to FIG. 7, the procedure of image display control in the present embodiment will be described.
FIG. 7 is a flowchart of the image display control process in the present embodiment.

First, the control unit 190A causes the power generation unit 120A to generate power.
The detection unit 125A detects the amount of power generation in the power generation unit 120A (step S10).
Next, the determination unit 192A determines the visibility of the image displayed on the display unit 110A based on the output value of the power generation unit 120A detected by the detection unit 125A (step S20).
Next, the determination unit 192A collects the output values of the power generation units 120B and 120C included in the image display devices 100B and 100C, respectively, and the visibility determination results based on the output values via the communication processing unit 196A ( Step S30).
The determination unit 192A determines the combination state of the image display devices in the plurality of image display devices based on the output values of the power generation units 120B and 120C and the output value of the power generation unit 120A. The combination display control unit 194A calculates the priority order of the images displayed on each display unit or the frequency of updating the display of the images according to the determination result of determining the combination state of each image display device by the determination unit 192A. To do. The combination display control unit 194A stores the calculated result in the storage unit 180A, transmits the result to another image display device, and stores the result in each storage unit.
In addition, the power control unit 193A determines a method of receiving power with another image display device according to the above-described determination result by the determination unit 192A. The power control unit 193A stores the determined result in the storage unit 180A, transmits the result to another image display device, and stores the result in each storage unit (step S40).
Next, the power control unit 193A controls the power exchange according to the determined receiving method (step S50).
Next, the display control unit 191A controls display of an image on the display unit 110A according to the result calculated by the combination display control unit 194A (step S60).

  The image display system 1 in the present embodiment described above can detect a state in which a plurality of image display devices 100 are arranged in combination according to the power generated by each power generation unit. As a result, the image display system 1 can avoid the display stop due to insufficient power generation by sharing the generated power among the image display devices, and can control the display method according to the power generation. Thereby, the convenience at the time of displaying combining the several image display apparatus 100 can be improved.

(Second Embodiment)
Next, with reference to FIG. 8, a structural feature of the image display apparatus according to the present embodiment will be described, and a mode in which the image display apparatus is combined and arranged will be described. The configuration in the image display system in this embodiment and the electrical configuration and processing in the image display apparatus are the same as those in the first embodiment described above, and the description of the first embodiment is referred to.
FIG. 8 is a diagram showing the structure of the image display device and the combination of two image display devices in the present embodiment.
FIG. 8 shows image display apparatuses 101A and 101B. The image display devices 101A and 101B correspond to the above-described image display devices 100A and 100B, and refer to the description of the electrical configuration and processing of the image display devices 100A and 100B.

Fig.8 (a) is the figure which looked down from the front 51A side of the housing | casing 50A in which the display surface 11A is provided, FIG.8 (b) is a cross section along YY 'in Fig.8 (a). FIG. 6C is a view of the state in which the image display devices 101A and 101B are combined as seen from the front 51A side.
The image display device 101A is different from the image display device 100A described above in that the display surface 11A and the light receiving surface 12A are provided.
In addition to the housing 50A and the base member 60A, the image display device 101A includes a display member 70A and a support member 75A that supports the display member 70A with reference to the front surface 51A of the housing 50A.
A display member 70A is provided at a central portion of the front surface 51A of the housing 50A at a predetermined distance from the front surface 51A in the X-axis direction.
The display member 70A is a rectangular parallelepiped smaller than the housing 50A, and is arranged so that the direction of each side of the housing 50A is parallel to the direction of each side of the display member 70A.
The display member 70A has a display surface 11A on a surface parallel to the front surface 51A.
If the shape of the display member 70A is a rectangular parallelepiped, the normal direction of the display surface 11A is the X-axis direction, and the directions along the orthogonal sides of the display surface 11A are the Y-axis direction and the Z-axis direction.
As described above, the display member 70A is provided in the same direction as the direction in which the light receiving surface 12A is provided with respect to the housing 50A. In short, the display surface 11A is provided in the same direction as the direction in which the light receiving surface 12A is provided with respect to the housing 50A.

A support member 75A is provided on the front surface 51A of the housing 50A of the present embodiment so as to be convex in the X-axis direction with respect to the light receiving surface 12A and the front surface 51A.
The support member 75A supports the display member 70A described above with respect to the front surface 51A of the housing 50A.
In the present embodiment, the position of the display surface 11A provided on the display member 70A is provided apart from the position of the light receiving surface 12A provided on the front surface 51A of the housing 50A in the X-axis direction.
Thus, by disposing them in the X-axis direction, the area of the light receiving surface 12A can be increased, and the display surface 11A and the light receiving surface 12A can be made difficult to be shielded.

In particular, in the configuration in which the image display device 101A and the image display device 101B are combined, the housing 50A and the housing 50B are arranged so as to have the same positional relationship as that of FIG. c).
As shown in FIG. 8, the region indicated by the region Z3 indicates a region where the light receiving surface 12B is shielded. Thus, even if the region Z3 occurs, the display surfaces 11A and 11B can be prevented from being shielded. In addition, the light-receiving area on the light receiving surfaces 12A and 12B is clearly wider than the configuration shown in FIG.
The shape of the image display device 101A only has an effect on the design aspect that the display surface 11A can be arranged and displayed at a predetermined distance from the wall surface to the vertical direction from the wall surface to which the image display device 101A is attached. In addition, the visibility of the display surface 11A can be improved and the light receiving surface 12A can be widened.

  The image display system 1 in the present embodiment described above can detect a state in which a plurality of image display apparatuses 101 are arranged in combination according to the power generated by each power generation unit. As a result, the image display system 1 can avoid the display stop due to insufficient power generation by sharing the generated power among the image display devices, and can control the display method according to the power generation. Thereby, the convenience at the time of displaying combining the several image display apparatus 101 can be improved.

Note that the image display device 100A according to the present embodiment is connected to other image display devices 100B, 100C, and the like at the end of the side surface of the housing 50A and the end of the base member 60A provided on the back surface 52A. A convex portion and a fitting hole for fitting into the convex portion are provided. A plurality of image display devices are combined within a range in which the plurality of convex portions and the fitting holes can be fitted.
The convex portions (for example, convex portions 58A and 68A) of one image display device and the fitting holes (for example, fitting holes 57A and 67A) of the other image display device are provided at the ends of the parts that can be fitted. You may combine things. For example, the spacing between the fitting holes 57A, the spacing between the convex portions 58A, the spacing between the fitting holes 67A, and the spacing between the convex portions 68A are all the same distance (spacing D). The limitation can be reduced, and a combination that can be fitted even if the directions of the image display apparatus 100 are not aligned can be prepared.

In the image display device 100A in the present embodiment, when the power generation unit 120A is a solar cell panel including a plurality of cells, which part of the power generation unit 120A is hidden or not hidden is determined. This can be determined from the output state of each cell of the solar battery.
Further, from the output state of each cell of the solar battery, according to the state (combination state) of the image display device 100 and the determination result of whether or not the display unit of each image display device 100 is visible to the user. The display unit of which image display device 100 is used and which display unit of the image display device 100 is not used is determined.

Specifically, the display unit of the image display apparatus 100 having a display unit that is almost or completely invisible to the user is set not to be used, or is set to reduce the frequency of image switching. To do.
For example, the combination display control unit (for example, the combination display control unit 194 </ b> A) in the specific image display device 100 among the plurality of image display devices 100 is configured to store the image display system 1. You may generate on behalf. By transmitting the setting content generated from the specific image display device 100 via the communication means, each image display device 100 other than the specific image display device 100 can share the setting content. In accordance with the contents, the control unit 190 of each image display device 100 executes an image display sequence.
Alternatively, each setting content for each image display device 100 may be generated by a combination display control unit (for example, combination display control unit 194A) in each image display device 100. . Each image display device 100 transmits the setting content generated by each image display device 100 via the communication unit, so that each image display device 100 can share the setting content from information transmitted to each other. it can.
Each image display device 100 executes an image display sequence according to the setting content generated by itself. In addition, according to the setting information shared among the image display devices 100, the image display devices 100 may correct the setting content generated by itself. Based on the shared setting information, it is possible to determine the power generation status and the power consumption status together, and it is possible to improve the convenience of the image display system by correcting the setting content generated by itself.

  The state determination of each image display device 100 may be performed immediately after the image display devices 100 are connected to each other, or after a certain time has elapsed since the image display devices 100 are connected to each other, You may go with. In the former method, even after the image display apparatuses 100 are connected to each other, the state determination is performed while the unconnected image display apparatus 100 remains or when the remaining image display apparatuses 100 are connected. There is a possibility that it will be. Therefore, in the former method, the determination result depends on the determined situation, but in the latter case, after the connection work is completed, the state between the image display apparatuses 100 is stable (= highly accurate). Can be determined.

In addition, when it is set as the structure which can exchange electric power between image display apparatuses 100, for example, although a power generation part (solar cell) is hidden and sufficient power generation cannot be performed, a display part (display panel) is exposed to the front direction. Thus, the image display apparatus 100 that is visible to the user can be supplied with power (conversation) from another image display apparatus 100 to display an image.
In this case, power can be supplied (flexible) by a power supply / reception method of wired connection or non-contact wireless connection (electromagnetic induction or the like). In the former case, there is a merit that the power supply loss can be relatively reduced, but there is a demerit that the degree of freedom of the shape and combination of the image display device 100 is lowered by an electrical connector or cable for wired connection. . On the other hand, in the latter case, the degree of freedom of the shape and combination of the image display device 100 can be increased, and the amount of power supply and demand loss that is relatively large can be eliminated by reducing power consumption.
A typical case of supplying (accommodating) power in the above will be described below.
(1) The power generation unit 120B (solar cell) included in the image display device 100B is almost or entirely shielded by another image display device 100 (for example, the image display device 100A), and the display unit 110B (display panel). Is determined to be visible to the user, power is supplied from another connected image display device 100 (for example, image display device 100A).
(2) Almost or all of the power generation unit 120A (solar cell) included in the image display device 100A is not shielded by another image display device 100 (for example, the image display device 100B), and the display unit 110A (display panel) ) Is determined to be invisible to the user, power is supplied to another connected image display apparatus 100 (for example, image display apparatus 100B).

  This setting content is similarly shared by each device by the wireless communication means, and each device performs power interchange according to the content.

  Note that the requirements of the above-described embodiment can be changed as appropriate without departing from the technical characteristics of the invention. Some components may not be used.

  Note that each unit included in the image display apparatus 100 in the above embodiment may be realized by dedicated hardware, or may be realized by a memory and a microprocessor.

  Each unit included in the image display device 100 includes a memory and a CPU (arithmetic processing device), and a program for realizing the function of each unit included in the image display device 100 is loaded into the memory and executed. A function may be realized.

  In addition, a program for realizing the function of each unit included in the image display apparatus 100 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read by a computer system and executed. You may perform the process by. Here, the “computer system” includes an OS and hardware such as peripheral devices.

Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, it also includes those that hold a program for a certain period of time, such as a volatile memory inside a computer system serving as a server or client in that case. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

1 image display system 100, 100A, 100B, 100C, 100D, 100E image display device,
110A, 110B display unit,
120A, 120B power generation unit,
192A, 192B determination unit,
11A, 11B, 11C light receiving surface,
12A, 12B, 12C Display surface,
50A, 50B housing,
60A, 60B Base part

Claims (11)

A display unit for electronically displaying images;
A power generation unit that generates and outputs electric power from light; and
An image display device comprising: a determination unit that determines the visibility of an image displayed on the display unit based on an output value of the power generation unit. The determination unit
An image displayed on the display unit based on a determination result of the determination based on a determination result of the determination based on an output value of a power generation unit included in each of the plurality of image display devices. The image display device according to claim 1, wherein the visibility of the image is determined. The image display apparatus according to claim 2, further comprising: a display control unit configured to control display of an image on the display unit according to a determination result by the determination unit. The display control unit
The image display device according to claim 3, wherein display of an image on the display unit is controlled in accordance with a priority order determined according to a determination result by the determination unit. The display control unit
5. The image display device according to claim 3, wherein update of display of an image on the display unit is controlled according to an update frequency determined according to a determination result by the determination unit. A power exchanging unit that exchanges power with another image display device different from the self-image display device among the plurality of image display devices;
A power control unit that determines a method of receiving power with the other image display device according to a determination result by the determination unit, and controls the exchange of power according to the determined reception method. The image display device according to any one of claims 2 to 5. The electric power generated from the light is stored in a power storage unit, and the output value of the power generation unit is a value that changes according to the amount of power stored in the power storage unit,
The determination unit
The visibility of the image displayed by the display unit is determined based on a value that changes in accordance with the amount of power stored in the power storage unit. The image display device described in 1. The determination unit
From the output value of the said power generation part, it determines with at least one part of the light-receiving surface with which the said power generation part is provided being covered with the housing | casing of image display apparatuses other than a self-image display apparatus. The image display device according to claim 7. The display unit
The image display device according to claim 8, further comprising: a display surface that electronically displays the image and is provided on the same surface as the surface on which the light receiving surface is provided. A plurality of image display devices according to claim 1;
A power control unit that determines a method of receiving power between the plurality of image display devices according to a determination result by the determination unit, and controls power exchange according to the determined reception method. Display system. In the computer provided in the image display device,
A display unit electronically displaying the image;
A power generation unit generating power from light;
And a step of determining the visibility of the image displayed by the display unit based on an output value of the power generation unit.

Images