JP2007147877A - Display device, method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily enlarge a display face by using a plurality of display devices. <P>SOLUTION: A display panel 101A and a display panel 101B are put one over the other to obtain a large display face on a display device 100. The display panel 101A receives light from a display part 103 of the lower display panel 101B by a light reception part 104. The display panel 101A detects an overlap state by a calculation part 105 to adjust a display size of image data to be displayed and displays image data after adjustment on the display part 103 by a display control part 106. Information relating to display of the image data after adjustment is transmitted to the display panel 101B. The display panel 101B displays the image data after adjustment on the basis of received information and stops display on an overlap part. Image data in the display part, of which the display is stopped, is sent to the display panel 101A through the light reception part 104 and is displayed on the overlap part. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a display device, a display method, and a display program that realize a large screen display by overlapping a plurality of display devices. However, use of the present invention is not limited to the above-described display device, display method, and display program.

  2. Description of the Related Art Conventionally, in order to display output information (image data) of a computer or AV (Audio-Visual) device, a display device suitable for the application is used. In order to enlarge the display surface of such a display device, it is necessary to use a display device having a larger display screen or display one image using a plurality of display devices. In recent years, various display devices such as a liquid crystal display, a plasma display, an EL (Electro Luminescence) display, and a projection display that realize display on a large screen have been developed and are beginning to spread to general users. When a display device having such a large display screen is used, display control is easy, but there is a problem that the price increases in proportion to the expansion of the display area. Further, the area of the display surface of the display screen is determined at the time of manufacturing the display device, and the area of the display surface cannot be changed for each use.

  On the other hand, a display device that performs large screen display using a plurality of display devices can form a display device having a display area of a desired size in accordance with a user's application. Moreover, since the area of the display surface of each display device does not matter, it can be manufactured at a relatively low cost. As a specific example, a projection type multi-display device that projects images for each display surface from the back side of a plurality of display surfaces and controls the brightness of the overlapping portions of adjacent display surfaces to be uniform (for example, the following patent document) 1), and a display device (for example, refer to Patent Document 2 below) that forms a sub-image that overlaps overlapping portions of adjacent display surfaces with overlapping pixels using a plurality of display surfaces. Yes.

JP 2001-268476 A JP-T-2001-525564

  However, since the multi-display device of Patent Document 1 described above is a projection-type display, a depth for connecting a projection image with a focus on the display device itself is indispensable, or an image can be projected when a display surface is formed. An example is the problem that the layout has to be arranged and the degree of freedom of the shape of the display surface is limited.

  In addition, the display device of Patent Document 2 described above can realize a flat display with no joint between the display surfaces using the formed sub-image when a plurality of display surfaces are arranged in an orderly manner. As an example, there is a problem in that the overlapping state of adjacent display surfaces changes and a large screen display in consideration of the overlapping portion cannot be performed. .

  In order to solve the above-described problems and achieve the object, a display device according to claim 1 is a display device having a plurality of display panels, and detects a display region in which the plurality of display panels overlap. Detecting means; calculating means for calculating a display area of the plurality of display panels excluding the display area detected by the detecting means; and a front display panel of the plurality of display panels; Display control means for displaying an image on a single display screen constituted by the display area calculated by the calculation means.

  According to a sixteenth aspect of the present invention, there is provided a display method using a plurality of display panels, wherein a detection step of detecting a display region where the plurality of display panels overlap with each other, A calculation process for calculating a display area excluding the display area detected by the detection process from the back display panel, and a display panel in front of the plurality of display panels and a display area calculated by the calculation process And a display control step of displaying an image on a single display screen configured.

  A display program according to claim 17 causes a computer to execute the display method according to claim 16.

  Exemplary embodiments of a display device, a display method, and a display program according to the present invention will be explained below in detail with reference to the accompanying drawings.

(Functional configuration of display device)
FIG. 1 is a block diagram showing a functional configuration of a display device according to this embodiment of the present invention. As shown in FIG. 1, the display device 100 forms a display surface by overlapping a plurality of display panels (101A and 101B in the illustrated example). Each of the display panels 101A and 101B includes a display unit 103, a detection unit 102 including a light receiving unit 104, a calculation unit 105, a display control unit 106, a communication unit 107, a reception unit 108, and a power supply unit (not shown). ).

  The detection unit 102 detects a display area in which display screens of a plurality of display panels (for example, the display panel 101A and the display panel 101B) overlap each other. Specifically, a display unit 103 and a light receiving unit 104 are provided. The display unit 103 displays display light for displaying an image on the surface of the display panel 101, and optical signals of image display position information and identification information of each display panel (in this case, identification information of the display panel 101A). The superimposed light is displayed. An image to be displayed on the display means may be read as image data by providing storage means, or may be sequentially acquired from the outside by providing data acquisition means regardless of wired or wireless. The display unit 103 displays not only display light for displaying an image but also display position information of the image and identification information of each display panel 101 as optical signals.

  The image display position information is information indicating at which position on the display panel 101 each display light constituting the image data displayed by the display unit 103 is emitted. As a specific example of the information, the display panel may be expressed by an XY address composed of an X axis and a Y axis, and information on the XY address corresponding to the display position of the display light may be included in the optical signal. The identification information of the display panel 101 may be unique information such as an arbitrarily defined ID.

  Since the superimposed light displayed by the display unit 103 is superimposed on the display light and the optical signal, if the light intensity of the optical signal is too high, the display surface becomes difficult to be seen by the user. The light signal is received by the light receiving unit 104 of another overlapping display panel 101 (for example, the display panel 101B). Therefore, the optical signal may be kept at the minimum necessary light intensity.

  When the display panels 101 overlap, the light receiving unit 104 receives superimposed light displayed from the display unit 103 of the display panel 101 (here, the display panel 101B) in the overlapping display area. The light receiving unit 104 is composed of a plurality of light receiving elements arranged in a grid pattern, detects the display shape from the display light out of the superimposed light, and outputs it to the calculation unit 105. At the same time, the optical signal of the superimposed light is converted into an electric signal, and the display element position and identification information of the image data of the display panel 101B are output to the calculation unit 105.

  The calculation unit 105 calculates a display area detected by the detection unit 102 from a display area of the back display panel 101 (here, the display panel 101B) among the plurality of display panels 101, that is, a display area excluding overlapping display areas. calculate. The calculation unit 105 is further determined by a determination unit (not shown) that determines the overlapping state of the display panel 101A and the display panel 101B based on the display light and the optical signal detected by the light receiving unit 104, and the determination unit. A display range calculation unit (not shown) that calculates a displayable range of the image from the overlapping state is provided.

  The display control unit 106 displays an image on a single display screen constituted by the display panel 101 (here, the display panel 101A) in front of the plurality of display panels 101 and the display area calculated by the calculation unit 105. Display. Further, when the display control unit 106 acquires the information on the overlapping state of the front display panel 101 that overlaps with each other via the communication unit 107, the display control unit 106 emits the display light of the display unit 103 in the display area in which the display panel 101 in the back overlaps. Stop. In addition, when a display operation of the display device 100 is input from the operator via the reception unit 108, the display control unit 106 performs display control on the display unit 103.

  In this embodiment, the display control unit 106 of the front display panel 101 (here, display panel 101A) plays a leading role, and the display control unit 106 of the rear display panel 101 (here, display panel 101B). Is configured to play an assistant role. That is, the flowchart of FIG. 2-1 described later is executed by the display control unit 106 of the display panel 101A. Further, the flowchart of FIG. 2-2 is executed by the display control unit 106 of the display panel 101B. Further, “back” and “front” here are defined with reference to the viewer who views the AV information on the display panel.

  The communication unit 107 uses the display position information of the image displayed by the display control unit 106 and the identification information of the front display panel 101 (here, the display panel 101A) as transmission information, and transmits the display panel 101 (here, the display panel 101B). ). Although communication using the communication unit 107 may be wired or wireless, a wireless communication unit is preferable when the number of display panels 101 used as the display device 100 is large or when the size of the display panel 101 is large. Further, when a transparent film-like antenna is provided, a display surface that can easily be viewed by the user can be realized without blocking the display light of the display unit 103.

  The receiving unit 108 receives an operation instruction from the operator. The display control unit 106 performs display control according to the operation instruction received by the reception unit 108. The operation instruction can be accepted regardless of whether it is wired or wireless. However, as a preferred example, it has a function of receiving a wireless signal and thus has a high degree of freedom for each of the browsing user and the operating operator. A display device 100 can be provided. When using a wireless signal, an existing standard may be used from a wireless LAN, for example.

  1 is provided in each display panel 101 and supplies power to each functional unit 102-108. Specifically, a thin battery may be used, or a thin film solar cell with high conversion efficiency may be disposed on the surface portion other than the display portion 103 of the display panel 101. When a thin battery is used, each display panel 101 is provided with a connector for connecting to an external power source such as an outlet. Further, a connector for connecting the display panels 101 to each other may be provided to charge the batteries. In such a configuration, any one of the display panels 101 included in the display device 100 may be provided with a connector connected to an external power source.

(Contents of display device processing)
Next, the processing contents of the display device will be described. FIGS. 2-1 and 2-2 are flowcharts illustrating a display procedure of the display device 100. FIG. In the flowchart of FIG. 2A, the display unit 103 first emits light by superimposing display light for displaying an image and an optical signal (step S201). The optical signal described here is the display position information of the image and the identification information of the display panel 101 described above. Next, it is determined whether or not the superimposed light from the overlapping display panel 101 has been received (step S202).

  If it is determined in step S202 that light from another display panel 101 is not received (step S202: No), there is no display panel 101 in the back and there is no need for display processing, and the current image is displayed. The data corresponding to can be displayed. Therefore, the process is terminated as it is. If the light from the other display panel 101 is received (step S202: Yes), the size of the image data that can be displayed on the display surface of the entire display device 100 from the received display light and the optical signal. Is adjusted (step S203).

  Next, the image of the size adjusted in step S203 is displayed on the display unit 103 (step S204). Finally, information on the adjusted image is transmitted to the overlapping display panel 101 (step S205). The information related to the image data transmitted in step S205 is display position information of the adjusted image data and identification information of the display panel 101. This completes the processes from the overlap detection when the plurality of display panels 101 overlap and the adjustment of the display size of the image data. In the subsequent steps described with reference to FIG. 2-2, the information transmitted in step S205 is referred to as transmission information.

  Next, a display processing procedure for an image after adjusting the display size will be described with reference to FIG. In the flowchart of FIG. 2-2, first, the communication unit 107 determines whether or not it has received transmission information from the front display panel 101 that overlaps (step S206). Here, it waits until the communication unit 107 receives transmission information from the other display panel 101 (step S206: No loop).

  When the transmission information is received in the determination of step S206 (step S206: Yes), the display light emission of the overlapping portion of the display panel 101 is stopped from the transmission information (step S207). The transmission information includes display position information of the image after adjustment and identification information of the display panel 101. Based on this information, an overlapping portion of the display unit 103 is determined, and the display light is stopped.

  Finally, an optical signal corresponding to the image of the light emission stop portion is displayed from the display unit 103 (step S208). Here, the light signal is emitted only in the portion where the image display is stopped in step S207. Since the portion where the display is stopped is positioned below the overlapping portion of the display panel 101, if the image is displayed as it is without stopping the display, the display light of the upper overlapping display unit 103 is affected. There is a risk. In particular, when the display panel 101 is formed of a thin substrate or a highly transmissive film, the influence is remarkable. Further, even when the display panel 101 is formed of a highly light-shielding substrate, it continues to emit display light that does not affect the user's vision, resulting in useless power consumption.

  Further, the optical signal emitted in step S208 is received by the light receiving unit 104 of the upper display panel 101, and the image data corresponding to the portion where the display light is stopped is displayed on the display panel 101 that has received the optical signal. Displayed on the display unit 103, the series of processing ends.

  As described above, the display device 100 detects an overlapping state by emitting an optical signal together with display light from the display unit 103 of the display panel 101 constituting the display surface, and receives light provided on the back surface of the display panel 101. This is realized by the unit 104 receiving superimposed light composed of display light and an optical signal. Further, the lower image data on which the display panel 101 overlaps is transmitted by an optical signal, and the upper display panel 101 on which the display panel 101 overlaps receives the image data by the light receiving unit 104. Therefore, the display device 100 having one display surface can be realized by the display panel 101 that is easily overlapped.

  As another example of the embodiment, light is emitted from the display unit 103 when a predetermined time has passed without receiving light from the other display panel 101 in the determination in step S202 of FIG. A functional unit for stopping the output of the optical signal may be added. With such a configuration, when the display device 100 is configured with a single display panel 101, it is possible to avoid a situation in which power consumption increases due to the continuous output of an optical signal.

  Examples of the present invention will be described below. In the present embodiment, for example, the display panels 101A and 101B described in the embodiment are realized as the display devices A and B (300A and 300B), and a display surface constituted by the plurality of display devices is used as the display surface of the display device 300. explain.

(Hardware configuration of display device)
FIG. 3 is a block diagram of a hardware configuration of the display device according to the present embodiment. As shown in FIG. 3, the display device 300 includes a display surface 301 as display means, an infrared light receiving element array 302 as receiving means, a transparent pattern antenna 303 as communication means, and a light receiving element matrix as light receiving means. A screen 304, a calculation unit 305 serving as a calculation unit and a display control unit, an image frame memory 306, and a power supply unit (not shown). The display device 300 forms each of the functional units 301 to 306 on a sheet-like substrate. The substrate may be made of any material as long as it has a predetermined strength, but a flexible substrate may be used as a more preferable example when the display device 300 is arranged on a surface with some unevenness or curvature.

  First, the display surface 301, the infrared light receiving element array 302, and the transparent pattern antenna 303 arranged on the surface of the display device A (300A) will be described with reference to FIG. In addition, although the structure of the display apparatus A (300A) is described as an example at the time of performing the description below, these are not limited to the display apparatus A (300A), and represent contents common to the display apparatus 300. FIG. 4 is an explanatory diagram showing the configuration of the surface of the display device A (300A). The display surface 301 is configured by a thin display such as an organic EL display, and displays the image data input from the image frame memory 306. The display surface 301 is processed with the transparent sealing end surface 307 on all sides. Furthermore, the outside of the transparent sealing end surface 307 is arranged so that the infrared light receiving element array 302 and the transparent pattern antenna 303 are bordered.

  The infrared light receiving element array 302 is a module in which infrared light receiving elements that receive an optical signal by infrared rays (light having a wavelength of about 1 mm to 700 nm), convert it into an electric signal, and output the electric signal are arranged in a line. The infrared light receiving element array 302 according to this embodiment is intended to receive an infrared optical signal output from an infrared remote controller or the like. The received optical signal is converted into an electrical signal and output to the calculation unit 305. The infrared light receiving element array 302 is arranged around the display surface 301 because even if a plurality of display devices 300 overlap each other in a complicated manner, the end surface of any one of the display devices 300 is exposed, and a remote control or the like is provided. This is because an infrared optical signal is received.

  Here, the infrared light receiving elements constituting the infrared light receiving element array 302 will be briefly described. Infrared light receiving elements are classified into two types: thermal forms that use the thermal action of infrared rays, and quantum forms that use the action of an energy block (photon or photon, photon) determined by the wavelength of infrared rays. Generally, a thermal infrared light receiving element has a low response because of its low sensitivity, but the sensitivity is constant regardless of the wavelength of infrared light. Therefore, it can be applied to the entire infrared region, and is particularly useful for measuring the total energy of light. The thermal infrared light receiving element is further classified into a thermal expansion type, a thermocouple type, a resistance type, and the like.

  On the other hand, the quantum infrared light receiving element has high sensitivity and high-speed response, but the sensitivity has wavelength dependency. Therefore, it has a characteristic that sensitivity is lost in a long wavelength region longer than the cutoff wavelength. Here again, the quantum infrared light receiving element is further classified into a phototube type, a junction type, and the like. In the case of receiving infrared light emitted from the display surface 301 as in this embodiment, a high-speed response is not required. Therefore, an appropriate infrared light receiving element may be selected in consideration of the use environment and cost.

  The transparent pattern antenna 303 realizes data communication between the display devices 300 by a wireless LAN (Local Area Network) method. Transmission information received from the other display device 300 received by the transparent pattern antenna 303 is output to the calculation unit 305. The transparent pattern antenna 303 is an antenna in which an antenna pattern is printed on a transparent film. Generally, a utilization method such as mounting on a glass surface of a vehicle as an in-vehicle antenna is known.

  As a specific material of the transparent pattern antenna 303, for example, there is a method of forming an antenna pattern by printing on a transparent PET (Polyethylene Terephthalate) film with a silver base ink. Further, by forming an antenna pattern using a metal for transparent electrodes such as ITO (Indium Tin Oxide), the transparent pattern antenna 303 having higher transparency can be finished.

  Next, the light receiving element matrix surface 304 constituting the back surface of the display device A (300A) will be described with reference to FIG. FIG. 5 is an explanatory diagram showing the configuration of the back surface of the display device A (300A). On the back surface of the display device A (300A), a light receiving element matrix surface 304 having the same area as the display surface 301 disposed on the front surface is disposed. The light receiving element matrix surface 304 detects the overlapping shape of the display devices 300. The detected overlap shape is output to the calculation unit 305.

  FIG. 5 shows an enlarged part of the light receiving element matrix surface 304. As can be seen from the enlarged view, the light receiving element matrix surface 304 is constituted by the light receiving elements 308 arranged in a lattice pattern. Further, the light receiving element matrix surface 304 is processed with the transparent sealing end surface 307 on all sides.

  Here, the light receiving elements 308 constituting the light receiving element matrix surface 304 will be described. The light receiving element 308 has the same basic configuration as the infrared light receiving elements forming the infrared light receiving element array 302, but has a different wavelength band of light to be detected. The light receiving element 308 detects visible light (light having a wavelength of about 360 nm to 830 nm) constituting an image displayed on the display surface, converts the light into an electric signal, and outputs the electric signal. The light receiving element matrix surface 304 outputs the detected visible light information to the calculation unit 305.

  Returning to FIG. 3, the calculation unit 305 and the image frame memory 306 will be described. Image data to be displayed on the display surface is input to the calculation unit 305 from the outside. The image data input to the calculation unit 305 is corrected for display and output to the image frame memory 306. Further, when an instruction from an infrared remote controller or the like is received by the infrared light receiving element array 302, or when the transparent pattern antenna 303 receives information on an overlapping portion from another display device 300 via the wireless LAN 700 (see FIG. 7), Alternatively, calculation for adjusting the display size of the image data to be displayed according to the information received by the light receiving element matrix surface 304 is performed.

  The image frame memory 306 adjusts and corrects the display size of the image data input from the calculation unit 305 and then stores it as display image data to be displayed on the display surface 301. The stored image data is output to the display surface 301.

  The power supply unit is formed as a rechargeable battery on a sheet-like substrate in the same manner as the functional units 301 to 306 described above. Of the power supply unit, the connection to the external power source used for charging is arranged at the end of the sheet-like substrate, but the battery main body is extremely thin, so the display surface 301, the light receiving element matrix surface 304, It is arranged between. However, the configuration is not limited to the above, and a suitable power supply unit may be configured according to the size and material of the display surface.

  FIG. 6 is a table for explaining the difference in display area between the conventional display device and the display device according to the present embodiment. In the chart 600, an example of normal arrangement is shown in the upper part, and an example of overlapping is shown in the lower part. Around the respective display surfaces 301 with the display devices A and B (300A and 300B), the transparent pattern antenna 303 is disposed so as to surround it. When the two display devices A and B (300A and 300B) are arranged in a normal arrangement, the connection portion 601 between the display device A (300A) and the display device B (300B) has a portion where image data is not displayed. The width is twice the width of the transparent pattern antenna 303.

  On the other hand, when the two display devices A and B (300A and 300B) are stacked as in this embodiment, the transparent pattern of either the display device A (300A) or the display device B (300B). Since the antenna 303 part is hidden behind the other transparent pattern antenna 303 part, the width of the transparent pattern antenna 303 of the part 602 where the image data is not displayed may be ½ the width of the normal arrangement, Even if one display surface 301 is formed in the display device 300, an easy-to-see screen can be realized.

(Data communication configuration between display devices)
FIG. 7 is a block diagram of the data communication configuration of the display device according to the present embodiment. As shown in FIG. 7, the display device A (300A) and the display device B (300B) are connected by a wireless LAN 700. Here, the wireless LAN 700 will be briefly described. The “wireless LAN” generally refers to a LAN that transmits and receives data by wireless communication, but in particular, often refers to a network composed of devices that comply with various IEEE 802.11 standards. Each terminal that performs data communication requires a wireless LAN card. When data is communicated via a relay device called a base station, terminals that do not have a base station and are equipped with a wireless LAN card do not receive data directly. There are also products that communicate.

  In the case of the display device 300 according to the present embodiment, each display device 300 corresponding to a terminal performs data communication with the wireless LAN 700 without providing a base station. In the example shown in FIG. 7, only two display devices 300, the display device A (300A) and the display device B (300B), perform data communication, but the display device 701 is newly added to the wireless LAN 700 network. The display area can be increased by adding 702. In addition, the wireless LAN 700 network is not used for communication between display devices, but the content to be displayed is used as a network for connecting to a home server provided in the home, and the content data is transmitted via the home server and the wireless LAN 700. Broadband connection may be used.

(Communication order of display device)
FIG. 8 is a sequence diagram showing a communication order between display devices. Here, as an example, the display device B (300B) is superimposed on the display device A (300A), and two display devices A and B (300A and 300B) display one image data. The communication order will be described. In the sequence diagram of FIG. 8, first, the display device A (300A) emits light by superimposing the display light of the image data and the optical signal of the information of the light emitting element position and the own device (display device A (300A) in this example) ID. (Step S801). The light emitting element position is address information of each pixel position constituting the display surface 301 and is expressed by an XY address. ID is identification information of each of the display devices A and B (300A and 300B).

  The display device B (300B) superimposed on the display device A (300A) receives the optical signal emitted from the display device A (300A) by the light receiving element 308 disposed on the back surface and the display light of the image data. (Step S802). Since the light receiving elements 308 are arranged on the back surface of the display device B (300B) at regular intervals in a grid pattern, only the light receiving elements 308 corresponding to the shape of the overlapping part receive the optical signal and the display light. be able to.

  Next, information on the overlapping shape is acquired from the display light received by the light receiving element 308 of the display device B (300B) (step S803), and the light emitting element position and the display device A (from the optical signal also received by the light receiving element 308 are displayed. 300A) ID information is acquired (step S804). Subsequently, the display device B (300B) overlaps the display device A (300A) and the display device B (300B) from the acquired information (information on the overlapping shape, information on the light emitting element position and the ID of the light emitting device A). The state is determined (step S805).

  Next, an image range that can be displayed is calculated from the overlapping state determined in step S805 (step S806). Specifically, the maximum display capable of correctly displaying image data by calculating the maximum vertical dimension and the maximum horizontal dimension of the entire display surface formed by the display device A (300A) and the display device B (300B). Find the size.

  Thereafter, the information on the element position and the self device ID is transmitted from the display device B (300B) to the display device that has received the display light (display device A (300A) in the example of the sequence diagram) (step S807). This element position refers to the light emitting element position of the display light when displaying the image data of the display size calculated in step S806. Note that the information on the element position and the own apparatus ID transmitted in step S807 is hereinafter referred to as transmission information.

  Next, the process proceeds to the processing of the display device A (300A), and the transmission information transmitted in step S807 is received by the transparent pattern antenna 303 (step S808). Subsequently, the information on the overlapping portion is transmitted from the transmission information received in step S808. Is acquired (step S809). Specifically, based on the information on the element position of the transmission information and the ID of the overlapping display device, information on the overlapping state of the own device (here, display device A (300A)) is obtained. At this time, whether or not the display size of the image data is changed is also determined from the information on the overlapping state. Therefore, when the display size of the image data is changed, the display size of the image data displayed on the display surface 301 of the display device A (300A) is changed.

  Thereafter, the display device A (300A) stops the display of the overlapping portion of the display surface 301 on its own device from the information on the overlapping portion acquired in step S809 (step S810). The display is stopped in step S810 in a portion where the display device A (300A) is hidden under the display device B (300B).

  Next, an optical signal is emitted from the display surface 301 of the display device A (300A) toward the light receiving element 308 of the display device B (300B) (step S811), and the processing of the display device A (300A) ends. The optical signal directed to the display device B (300B) is specifically the image data of the overlapping portion whose display is stopped in step S810. When transmitting an optical signal, it is transmitted to the display device B (300B) as an optical signal by light emission of the display constituting the display surface 301 in the same manner as in the process of step S801.

  The process proceeds to the display device B (300B). First, the light signal emitted from the display device A (300A) in step S811 is received by the light receiving element 308 on the back of the display surface 301 (step S812). Next, the image data acquired from the optical signal received in step S812 is displayed on the display surface 301 (step S813), and the series of processing ends. The image data displayed on the display surface 301 of the display device B (300B) in step S813 is image data of the overlapping portion of the display device A (300A) whose display is stopped in step S810. Accordingly, on one display surface 301 formed from the display surface 301 of the display device A (300A) and the display surface 301 of the display device B (300B), image data having a display size matching the display area is displayed.

(Example of overlapping pattern)
Hereinafter, the pattern of how to overlap the display device 300 according to the present embodiment will be exemplified with reference to FIGS. 9 to 17 are explanatory diagrams showing how to overlap when displaying image data using two display devices 300A and 300B (300A and 300B). 9 to 17, image data is displayed on the display surface 301 of the display device A (300A) and the display surface 301 of the display device B (300B) is displayed for easy understanding of the overlapping pattern. A lattice pattern is shown, and an overlapping portion (900 to 1700) of the display device A (300A) and the display device B (300B) is indicated by hatching.

  First, as shown in FIG. 9, when the display device A (300A) and the display device B (300B) are arranged vertically, an overlapping portion 900 is generated. Display device B (300B) calculates the display range of the image data displayed on display surface 301 of display device A (300A) from the information acquired by light receiving element 308 on the back surface of overlapping portion 900, and adjusts the display size. Is done. In the case of the example shown in FIG. 9, since the area of the display surface 301 on which image data is displayed is enlarged, the image data whose display size is enlarged by communication between the display device A (300A) and the display device B (300B). Is displayed.

  However, in the case of the overlapping pattern as shown in FIGS. 10 to 17, the maximum vertical dimension and the maximum horizontal dimension of the entire display surface 301 formed by the display device A (300A) and the display device B (300B) from the overlapping state are Since the display screens 301 of the display devices A and B (300A and 300B) are not different from each other, the image data of the display device A (300A) that is overlapped on the overlapping portions 1000 to 1700 is displayed as it is. The

  18-20 is explanatory drawing which shows the example which formed the display surface using the 2 or more display apparatus 300. Moreover, FIG. The examples shown in FIGS. 18 and 19 show only the display device A (300A) and the display device B (300B) among the plurality of display devices constituting the display surface.

  In the case of the example shown in FIG. 18, the display surface 1800 has a display size of image data obtained by calculation using a plurality of display devices 300. Display device A (300A) and display device B (300B) display image data corresponding to the display size of display surface 1800. On the other hand, in the case of the example shown in FIG. 19, the display surface 1900 has the display size of the image data obtained by calculation. In this case, a part of the display device B (300B) protrudes from the display size of the image data. Therefore, image data is displayed on the display surface 1901 of the display device B (300B) with the display surface 1900 as a boundary, and the display surface 1902 stops the display.

  In addition, as shown in the display example 2000 of FIG. 20, the display device 300 according to the example is composed of a thin film and can be used by being attached to a wall surface. In addition, it is possible to adjust the overlay of the display device 300 according to the area and shape of the wall surface to be pasted to form a display surface that is easy to view.

  When the display surface is formed from the two display devices 300 as in the embodiment shown in FIGS. 10 to 17, the display device B (300 </ b> B) in front of each other plays a leading role, The back display device A (300A) plays an assistant role. When the display surface is formed from two or more display devices 300 as in the embodiments shown in FIGS. 18 to 20, the display device 300 in the foreground takes the lead every time the display devices 300 overlap each other. The display device 300 in the back performs processing that plays an assistant role, and finally, display control of the entire display surface is performed.

  In addition, the present embodiment may be a display device including a polygonal display surface instead of the display device including a rectangular display surface as described above. Even when such polygonal display devices are neatly arranged to form a single display surface, the display area for displaying an image can be controlled to be maximized.

  As described above, according to the display device, the display method, and the display program, a large screen display can be easily realized. In addition, since the display surface is formed by a plurality of display devices in the present invention, even if a part of the display device breaks down, the display can be restarted immediately by preparing an alternative display device. Even when there is no alternative display device, a new display surface can be formed by an available display device, and the maximum display area by this new display surface can be calculated and used again.

  Further, as another embodiment of the present invention, a function unit in which the functions of the infrared light receiving element array 302 and the transparent pattern antenna 303 are integrated may be provided. Specifically, the data communication between the display devices 300 also uses infrared rays. For example, when conforming to various IEEE 802.11 standards, the DS (direct spreading) method, the FH (frequency hopping) method, and the infrared method using the 2.4 GHz frequency band are specified. By applying the infrared method, data communication between the display devices 300 can be realized.

  In the present embodiment, the overlapping state of the display devices 300 is detected by the correspondence between the light emitting element and the light receiving element 308. Alternatively, the overlapping state may be detected using electromagnetic induction. . In this case, a sheet-like coil pattern and a magnet may be used instead of the light emitting element and the light receiving element 308.

  The display method described in this embodiment can be realized by executing a program prepared in advance on a computer such as a personal computer or a workstation. This program is recorded on a computer-readable recording medium such as a hard disk, a flexible disk, a CD-ROM, an MO, and a DVD, and is executed by being read from the recording medium by the computer. The program may be a transmission medium that can be distributed via a network such as the Internet.

It is a block diagram which shows the functional structure of the display apparatus of this Embodiment of this invention. It is a flowchart (the 1) which shows the display procedure of a display apparatus. It is a flowchart (the 2) which shows the display procedure of a display apparatus. It is a block diagram which shows the hardware constitutions of the display apparatus concerning a present Example. It is explanatory drawing which shows the structure of the surface of a display apparatus. It is explanatory drawing which shows the structure of the back surface of a display apparatus. It is a graph explaining the difference of the display area of the conventional display apparatus and the display apparatus concerning a present Example. It is a block diagram which shows the data communication structure of the display apparatus concerning a present Example. It is a sequence diagram which shows the communication order between display apparatuses. It is explanatory drawing (the 1) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 2) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 3) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 4) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 5) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 6) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 7) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 8) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 9) which showed how to overlap when displaying image data using two display apparatuses. It is explanatory drawing (the 1) which shows the example which formed the display surface using the 2 or more display apparatuses 300. FIG. It is explanatory drawing (the 2) which shows the example which formed the display surface using the 2 or more display apparatuses 300. FIG. FIG. 12 is an explanatory diagram (part 3) illustrating an example in which a display surface is formed using two or more display devices 300;

Explanation of symbols

DESCRIPTION OF SYMBOLS 100,300 Display apparatus 101 (101A, 101B) Display panel 102 Detection part 103 Display part 104 Light receiving part 105 Calculation part 106 Display control part 107 Communication part 108 Reception part 301 Display surface 302 Infrared light receiving element row | line | column 303 Transparent pattern antenna 304 Light receiving element Matrix surface 305 Operation unit 306 Image frame memory 307 Transparent sealing end surface 308 Light receiving element

Claims (17)

A display device having a plurality of display panels,
Detecting means for detecting a display area where the plurality of display panels overlap;
Calculating means for calculating a display area excluding the display area detected by the detecting means from the back display panel among the plurality of display panels;
Display control means for displaying an image on a single display screen constituted by a front display panel of the plurality of display panels and a display area calculated by the calculation means;
A display device comprising: The detection means includes
Display means for displaying display light for displaying an image and light (hereinafter referred to as “superimposed light”) obtained by superimposing the display position information of the image and an optical signal of identification information of each display panel;
A light receiving means for receiving the superimposed light of the overlapped display area when the display panels overlap, and detecting the display area where the plurality of display panels overlap using the superimposed light, The display device according to claim 1. Each of the display panels is
3. The communication device according to claim 1, further comprising a communication unit configured to transmit the display position information of the image displayed by the display control unit and the identification information of the front display panel as transmission information to the back display panel. Display device. Each of the display panels is
When receiving the transmission information from the front display panel that is overlapping,
The display control means causes the display means to display the image based on the transmission information,
Stop the display light in the overlapping display area of the back display panel,
4. The display device according to claim 3, further comprising: displaying an optical signal corresponding to image data of the stopped portion on the display means in the display area where the display light is stopped. When the light receiving means receives an optical signal corresponding to the image data of the stopped portion from the back display panel,
The display device according to claim 4, wherein the display control unit causes the display unit to display an image corresponding to the optical signal received by the light receiving unit. The calculating means includes
Based on the superimposed light detected by the light receiving means, a determining means for determining an overlapping state of the overlapping display panel and the front display panel,
A display range calculation unit that calculates a range in which an image can be displayed from the overlapping state determined by the determination unit;
The display device according to claim 1, wherein the display size of the image is calculated based on the displayable range. Each of the display panels is
A receiving means for receiving an operation instruction from the operator;
The display device according to claim 1, wherein the display control unit performs display control according to the operation instruction received by the receiving unit. The operation instruction from the operator is a radio signal,
The receiving means receives a radio signal;
The display device according to claim 1, wherein the control unit performs display control according to the radio signal received by the receiving unit.   The display device according to claim 7, wherein the wireless signal is an infrared signal, and the receiving unit receives the infrared signal.   The display device according to claim 1, wherein the display panel is a film-like substrate.   The display device according to any one of claims 2 to 10, wherein the light receiving means includes light receiving elements arranged in a lattice shape in an area equal to a display range of the display means.   The display device according to claim 2, wherein the display position information is expressed by an XY address.   The display device according to claim 3, wherein the communication unit performs wireless communication using an antenna.   The display device according to claim 13, wherein the antenna has a metal antenna pattern printed on a transparent film.   The display device according to claim 13 or 14, wherein the antenna transmits and receives between the display devices via a wireless LAN (Local Area Network). A display method using a plurality of display panels,
A detection step of detecting a display area where the plurality of display panels overlap;
A calculation step of calculating a display area excluding the display area detected by the detection step from the back display panel among the plurality of display panels;
A display control step of displaying an image on a single display screen constituted by a front display panel of the plurality of display panels and a display region calculated by the calculation step;
A display method comprising: A display program for causing a computer to execute the display method according to claim 16.

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