JP2009098581A - Display system and control method of display system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display system capable of quickly detecting the degradation and failure in a display unit and capable of easily responding to the degradation and the failure when constituting one large-size screen by arranging a plurality of display units. <P>SOLUTION: In the display system 1 provided with a display device 10 constituted by arranging master panel units 2 and panel units 3, current consumption of oneself is detected with respect to respective master panel unit 2 and panel units 3, and the abnormality of oneself is detected on the basis of the detected current consumption. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a display system configured by arranging a plurality of display units, and a display system control method.

Conventionally, a method of arranging a plurality of display units to form one large screen is known (for example, see Patent Document 1). In Patent Document 1, when a multi-display system device functioning as a large screen is configured by arranging a plurality of image display units side by side, display data is input to each image display unit. Is disclosed. Such display of a plurality of display devices arranged as a whole on one screen is generally referred to as tiling display.
JP 2001-275137 A

By the way, if some of the display units break down or deteriorate during tiling display, the hue and brightness may not match those of other display devices, resulting in a noticeable discomfort or a part of the image not being displayed. . For this reason, it is required to promptly detect deterioration or failure of each display unit that performs tiling display, but there is no suitable method.
Accordingly, an object of the present invention is to quickly detect deterioration and failure of a display unit and easily cope with it when a large screen is formed by arranging a plurality of display units.

In order to solve the above problems, the present invention provides a display system including a display device configured by arranging a plurality of display units having a display panel, wherein the display unit includes a current detection unit that detects its own current consumption; An abnormality detection unit that detects an abnormality based on the current consumption detected by the current detection unit; and a display adjustment unit that changes a display state of the display panel when an abnormality is detected by the abnormality detection unit; A display system characterized by comprising:
According to this configuration, the display unit itself detects an abnormality such as a failure or deterioration in the display unit constituting the display device based on the current consumption of the display unit, and the display unit itself displays the display state according to this abnormality. Change. For this reason, the display unit itself can detect an abnormality and perform processing corresponding to the abnormality without depending on an external device. Therefore, when an abnormality occurs in the display units constituting the display device, each display unit responds promptly, and the display state of the display device is kept good without special measures using an external device. be able to.

In the above configuration, the display unit includes a transmission unit that transmits information indicating its own abnormality when an abnormality is detected by the abnormality detection unit, and the display device displays the abnormality transmitted from the display unit. The display control unit that receives the information to be displayed and transmits an instruction to change the display state to the display unit, and the display adjustment unit that the display panel includes, according to the instruction transmitted from the display control unit, The display state on the display panel may be changed.
In this case, when the display unit detects its own abnormality, information indicating the abnormality is transmitted to the display control unit, the display control unit determines the response to the abnormality, and when this is indicated, the display unit follows the instruction to display the display panel. The display state at is changed. For this reason, the display unit itself can detect an abnormality and perform processing corresponding to the abnormality without depending on an external device. Furthermore, since the display control unit can determine how to respond to the abnormality, for example, complicated response processing such as cooperating a plurality of display units can be executed. Thereby, the occurrence of an abnormality can be quickly detected and easily dealt with, and the abnormality can be complicated and meticulously dealt with.

The said structure WHEREIN: The said display adjustment part is good also as what increases or reduces the brightness | luminance of the said display panel by increasing or decreasing the electric current which flows into the said display panel.
In this case, when an abnormality that decreases or increases the luminance of the display unit is detected, the abnormality of the display panel can be compensated by changing the luminance of the display panel. It can be detected and eliminated, and a good display state can be maintained.

In order to solve the above problems, the present invention provides a display system including a display device configured by arranging a plurality of display units having a display panel, wherein the display unit includes a current detection unit that detects current consumption; An anomaly detector that detects an anomaly based on the current consumption detected by the current detector; and a transmitter that transmits information indicating the anomaly when an anomaly is detected by the anomaly detector; The display device includes a display control unit that receives information indicating an abnormality transmitted from the display unit and changes a display state of the display device.
According to this configuration, each display unit constituting the display device detects its own abnormality, and when the abnormality is detected, information indicating the abnormality is transmitted, and the display control unit displays the display device according to this information. Change state. For this reason, the display unit itself can quickly detect an abnormality in the display unit. In addition, since the display control unit can receive and deal with information regarding abnormality of each display unit constituting the display device, the state of each display unit can be managed reliably. In addition, by changing the display state of the plurality of display units by the display control unit, it is possible to perform a complicated and effective response to the abnormality of the display units.

The said structure WHEREIN: The said display control part is good also as what performs the identification display for identifying the said display unit detected by the said abnormality detection part in the said display apparatus.
In this case, it is possible to clearly see which of the plurality of display units that make up the display device has an abnormality, so that in addition to checking the status of the display unit, work such as repair and replacement can be easily performed. It can be carried out.

In the configuration described above, the display control unit transmits the information indicating its own abnormality when the display device performs the identification display, or the display located around the display unit. The display state in the unit may be controlled so that the display unit detected by the abnormality detection unit can be identified.
In this case, it is possible to identify which display unit has an abnormality based on the display status of the display unit in which the abnormality has occurred or the display units located around the display unit. And replacement work can be easily performed.

The said structure WHEREIN: The said display control part is good also as what increases or reduces the brightness | luminance of the said display panel by correct | amending the image displayed on the said display unit detected by the said abnormality detection part.
In this case, by correcting the image displayed on the display unit, it is possible to compensate for an abnormality in the brightness of the display panel without using a configuration for adjusting the brightness of the display panel itself, and to cause display unevenness. Abnormal brightness can be eliminated.

Further, the present invention is a control method for controlling a display system including a display device configured by arranging a plurality of display units, the current consumption being detected in each of the display units, and the detected current consumption An abnormality is detected based on the information, and when there is an abnormality, information indicating its own abnormality is transmitted, and the display state of the display device is changed based on the information indicating the abnormality transmitted from the display unit. A display system control method is provided.
According to this method, each display unit constituting the display device detects its own abnormality, and when the abnormality is detected, information indicating the abnormality is transmitted, and the display control unit displays the display device according to this information. Change state. For this reason, the display unit itself can quickly detect an abnormality in the display unit. In addition, since the display control unit can receive and deal with information regarding abnormality of each display unit constituting the display device, the state of each display unit can be managed reliably. In addition, by changing the display state of the plurality of display units by the display control unit, it is possible to perform a complicated and effective response to the abnormality of the display units.

  A control program for realizing this control method includes a magnetic recording medium such as a flexible disk and a hard disk device, a magneto-optical recording medium such as an MO, a CD-R, a CD-RW, a DVD ± R, a DVD ± RW, and a DVD-RAM. It is good also as a form recorded on various recording media, such as a storage apparatus using the optical recording medium of this, and a semiconductor storage device, in the format which can be read by a computer.

  According to the present invention, each display unit constituting the display device can quickly detect its own abnormality based on current consumption, and can easily cope with this abnormality.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a schematic configuration of a display system 1 according to an embodiment to which the present invention is applied.
A display system 1 is configured by connecting a master panel unit 2 and a panel unit 3 as display units, and a display device 10 that functions as one display screen, and a host computer connected to the display device 10 via a communication line 11. 4.
The display device 10 is configured by connecting at least one master panel unit 2 and one or more panel units 3, and in the present embodiment, one master panel unit 2 and eight panel units 3 are arranged in three vertical rows. A case where a rectangular display device 10 is configured by connecting in a horizontal three rows is described as an example.

2 is an external view showing the configuration of the master panel unit 2 and the panel unit 3, FIG. 2 (A) shows the configuration of the master panel unit 2, FIG. 2 (B) shows the configuration of the panel unit 3, FIG. 2C shows a configuration of a connecting portion between the master panel unit 2 and the panel unit 3.
As shown in FIG. 2 (A), the master panel unit 2 includes a rectangular display panel 27 housed in a rectangular housing 28 having substantially the same size as the display panel 27, and the surface of the master panel unit 2. Is almost entirely covered with the display panel 27. As shown in FIG. 2B, the panel unit 3 is a rectangular display panel 37 that is housed in a rectangular casing 38 that is substantially the same size as the display panel 37. The surface of the panel unit 3 is The display panel 37 covers almost the whole. Since the outer shapes and sizes of the housing 28 and the housing 38 are aligned, the master panel unit 2 and the panel unit 3 can be connected side by side in the vertical and horizontal directions.

Further, as shown in FIGS. 2A to 2B, the master panel unit 2 includes four interfaces 26 that are arranged in the directions of the respective sides of the upper, lower, left, and right sides. Similarly, the panel unit 3 is provided with four interfaces 35 (connecting portions) arranged in the directions of the respective sides of the upper, lower, left and right sides. When the master panel unit 2 and the panel unit 3 are adjacent to each other, the interface 26 and the interface 35 are connected. When the panel units 3 are adjacent to each other, the interface 35 is connected to each other.
As a specific configuration of the interface 26 and the interface 35, for example, as shown in an enlarged view in FIG. 2C, a data bus, which will be described later, is provided by including a connector in which a concave portion and a convex portion are arranged. And the like are connected to each other. In the example of FIG. 2 (C), the connectors provided in the interfaces 26 and 35 have the same shape, and are arranged so that the concave portion is located on the right side and the convex portion is located on the left side. And the convex part always face each other. Although FIG. 2C shows an example in which the interfaces 26 and 35 are connected, the same applies when the interfaces 35 are connected.

  Examples of the display panels 27 and 37 include organic EL (Electro Luminescence) panels. Since the organic EL panel does not require a backlight or the like, the organic EL panel can be thinned and is particularly suitable for an application in which it is attached to a wall surface. The master panel unit 2 and the panel unit 3 include a liquid crystal display panel, a plasma display panel, an FED (Field Emission Display) panel (including a surface-conduction electron-emitter display panel), an LED (light emitting diode) display, and the like. Various flat panel displays, electronic paper, and the like can be used, and it is not impossible to use a CRT (Cathode Ray Tube).

Further, as shown in FIG. 2A, the master panel unit 2 includes host connection interfaces 25 at the four corners. The host connection interface 25 is an interface connected to the host computer 4 via the communication line 11 as shown in FIG. Although the master panel unit 2 includes four host connection interfaces 25, any one of the host connection interfaces 25 may be connected to the host computer 4. The host connection interface 25 that can easily connect the communication line 11 can be selected.
The communication line 11 is, for example, a wired or wireless communication line defined by IEEE standard 802.3, IEEE 802.11, or the like. Using this communication line 11, the host computer 4 and the master panel unit 2 are connected to a wired LAN (or wireless). LAN).

FIG. 3 is a functional block diagram showing configurations of the master panel unit 2 and the host computer 4. 4 is a diagram showing a configuration of the panel unit 3, FIG. 4A is a functional block diagram of the panel unit 3, and FIG. 4B is a configuration diagram of the interface 35.
As shown in FIG. 3, the installation directions of the four interfaces 26 included in the master panel unit 2 are designated, and are an upward interface 26A, a right interface 26B, a downward interface 26C, and a left interface 26D. . The master panel unit 2 needs to be installed such that the upward interface 26A is up, the right interface 26B is right, the down interface 26C is down, and the left interface 26D is left. Are attached with characters and symbols indicating the installation direction so that a contractor or the like can confirm the installation direction.
As shown in FIG. 4, the four interfaces 35 included in the panel unit 3 are arranged in directions corresponding to the four sides of the panel unit 3, and are respectively provided with an A direction interface 35 </ b> A, a B direction interface 35 </ b> B, and C. A direction interface 35C and a D direction interface 35D are provided. The direction at the time of installation of these four interfaces 35 is arbitrary. That is, the direction in which the directions A to D are actually directed is arbitrary, and for example, the panel unit 3 may be installed so that the A-direction interface 35A faces downward, as opposed to FIG.

The master panel unit 2 includes a control unit 20 that controls the entire display device 10 together with display processing on the display panel 27. The control unit 20 includes a CPU 21, a ROM 22 that stores various control programs executed by the CPU 21 and data related to these control programs, a RAM 23 that temporarily stores programs executed by the CPU 21, data to be processed, and the like. And a nonvolatile memory 24 that nonvolatilely stores data generated by the processing of the CPU 21.
The control unit 20 is individually connected to the upward interface 26A, the right interface 26B, the downward interface 26C, and the left interface 26D. The control unit 20 distinguishes these four interfaces 26 and inputs / outputs information to / from each interface 26. To do. Further, four host connection interfaces 25 arranged at the four corners of the master panel unit 2 are connected to the control unit 20. Further, the CPU 21 is connected to four host connection interfaces 25, and transmits / receives control information, image data, and the like to / from the host computer 4 via these host connection interfaces 25.
The nonvolatile memory 24 stores an ID as identification information unique to the master panel unit 2. In this embodiment, as an example, the master panel unit 2 is assigned a hexadecimal ID (= FF), and the CPU 21 is connected to the panel unit 3 connected to the interface 26 or the host connection interface 25. The ID (= FF) stored in the nonvolatile memory 24 is output to the host computer 4.
In addition, the control unit 20 detects a current consumption consumed by the master panel unit 2 and outputs a detected current amount to the CPU 21 and a display for adjusting the current flowing through the display panel 27 according to the control of the CPU 21. And a current adjustment circuit 65 as an adjustment unit. Detailed configurations of the current detection unit 60 and the current adjustment circuit 65 will be described later.

As shown in FIG. 4A, the panel unit 3 includes a control unit 30 that performs display processing on the display panel 37 and the like. The control unit 30 includes a CPU 31, various control programs executed by the CPU 31, a ROM 32 that stores data related to these control programs, a RAM 33 that temporarily stores programs executed by the CPU 31, data to be processed, and the like. And a nonvolatile memory 34 that stores data generated by the processing of the CPU 31 in a nonvolatile manner.
The control unit 30 is individually connected to the A-direction interface 35A, the B-direction interface 35B, the C-direction interface 35C, and the D-direction interface 35D, and distinguishes these four interfaces 35 to transmit / receive signals to / from the individual interfaces 35. Etc.
Further, the nonvolatile memory 34 stores an ID as unique identification information given to the panel unit 3 in the process described later. Different IDs are assigned to the respective panel units 3 constituting one display device 10, and the CPU 31 is nonvolatile in the master panel unit 2 and other panel units 3 connected to the interface 35 as necessary. The ID stored in the memory 34 is output.
Further, the control unit 30 detects a current consumed by the panel unit 3 and outputs the detected current amount to the CPU 31, and a current adjustment circuit that adjusts a current flowing through the display panel 37 according to the control of the CPU 31. 65. Detailed configurations of the current detection unit 60 and the current adjustment circuit 65 will be described later.

FIG. 4B shows a configuration common to all the interfaces 26 and 35 in the display device 10. As shown in FIG. 4B, the interfaces 26 and 35 are images displayed by the control information communication bus, the master panel unit 2 and the panel unit 3 in addition to the two power supply lines (Vcc). An image distribution bus for transmitting data is included. The control information communication bus includes a data line (data) for transmitting / receiving control information related to settings and the like between the master panel unit 2 and the panel unit 3 and between the panel units 3, and for synchronization. It is constituted by a clock signal line (CLK). In addition, the image distribution bus includes data lines (D +, D−) for transmitting and receiving image data of images to be displayed on the master panel unit 2 and the panel unit 3, and a clock signal line (CLK) for synchronization. Composed. A ground line (GND) is appropriately disposed between the power lines, data lines, and clock signal lines of the interfaces 26 and 35.
The control unit 20 performs input / output of control information via the control information communication bus of each interface 26 and input / output of image data via the image distribution bus. Similarly, the control unit 30 performs input / output of control information via the control information communication bus of each interface 35 and input / output of image data via the image distribution bus.

FIG. 5 is a diagram illustrating the configuration of the current detection unit 60 and the current adjustment circuit 65, FIG. 5A illustrates the configuration of the current detection unit 60, and FIG. 5B illustrates the configuration of the current adjustment circuit 65. .
The current detection unit 60 and the current adjustment circuit 65 are disposed in both the master panel unit 2 and the panel unit 3 and have the same configuration and function.
The current detection unit 60 shown in FIG. 5A includes a current measurement circuit 61 that measures the amount of input current, and an A / D converter 63 that outputs a measurement value in the current measurement circuit 61 as digital data. . The current measuring circuit 61 measures the total amount of supplied current and outputs the measured value to the A / D converter 63. Here, since the current measurement circuit 61 outputs a measurement value as an analog voltage value, a diode 62 is interposed between the output terminal of the current measurement circuit 61 and the input terminal of the A / D converter 63. The A / D converter 63 quantizes the measurement value as the analog voltage value output from the current measurement circuit 61 and outputs the result as digital data.
In the current detection unit 60 provided in the control unit 20, the current measurement circuit 61 includes a master panel unit 2 from two power supply lines (Vcc) provided in each of the four interfaces 26 as shown in FIG. The total of the amount of current supplied to is measured, and this measured value is converted into digital data by the A / D converter 63 and output to the CPU 21. Further, in the current detection unit 60 provided in the control unit 30, the total amount of current supplied to the panel unit 3 from the two power supply lines (Vcc) provided in each of the four interfaces 35 by the current measurement circuit 61. This measured value is converted into digital data by the A / D converter 63 and output to the CPU 31.

In addition, the current supplied to the display body 27A included in the display panel 27 or the display body 37A included in the display panel 37 is input to the current adjustment circuit 65 illustrated in FIG. The current adjustment circuit 65 functions as a variable resistor whose resistance value changes under the control of the CPU 21 or the CPU 31, and appropriately limits the current supplied to the display bodies 27A and 37A. With this current adjustment circuit 65, for example, in a certain panel unit 3, the current consumption of the display body 37 </ b> A of the display panel 37 can be increased more than usual, and the brightness of the display panel 37 can be increased.
Here, the display bodies 27A and 37A refer to elements or configurations that realize display on the display panels 27 and 37 by consuming current. For example, when the display panels 27 and 37 are configured by organic EL panels, An individual display element composed of an organic material.

  On the other hand, as shown in FIG. 3, the host computer 4 temporarily stores a CPU 41, various control programs executed by the CPU 41, a ROM 42 storing data related to these control programs, a program executed by the CPU 41, data to be processed, and the like. Display RAM 43, storage unit 44 for storing data generated by the processing of CPU 41, input unit 45 for accepting input operation by a user or operator, contents input by input unit 45, processing result by CPU 41, and the like are displayed. And a communication interface 47 that transmits and receives various information and control information to and from the master panel unit 2 via the communication line 11, and these units are connected to each other via a bus 48.

The storage unit 44 included in the host computer 4 is a storage device configured using a magnetic or optical recording medium or a semiconductor storage element, and includes an initial setting program 44A, panel arrangement information 44B, an image data division display program 44C, Various programs and data including the data distribution program 44D are stored.
The initial setting program 44A is used when the display device 10 is newly installed by connecting the master panel unit 2 and the panel unit 3, or when the configuration of the display device 10 is changed. This is a program executed to detect the arrangement state of the unit 3.
When the initial setting program 44A is executed by the CPU 41, a unique ID is assigned to each panel unit 3 in the display device 10 by the functions of the host computer 4, the master panel unit 2, and the panel unit 3, and the panel arrangement information 44B is displayed. Generated.
The image data division display program 44 </ b> C is a program executed to divide one image according to the configuration of the display device 10 and generate image data to be displayed on the master panel unit 2 and each panel unit 3. The data distribution program 44D is a program executed for individually transmitting image data, control information, and the like to the master panel unit 2 and the panel unit 3.

  For example, as illustrated in FIG. 6, the panel arrangement information 44 </ b> B is information that associates the positions of the master panel unit 2 and the panel unit 3 in the display device 10 with the IDs of the master panel unit 2 and the panel unit 3. Further, the panel arrangement information 44B includes information for associating the vertical and horizontal directions of the display device 10 with the configuration of the display device 10. Therefore, from the panel arrangement information 44B illustrated in FIG. 6, the master panel unit 2 is arranged at the lower end of the display device 10, the panel units 3 are arranged on the left and right of the master panel unit 2, and two rows of panel units are arranged thereon. 3 is arranged, and the display device 10 is composed of nine panel units arranged in a total of 3 columns × 3 columns.

7A and 7B are diagrams for explaining processing for displaying an image on the display device 10, FIG. 7A shows a state where an image is displayed on the display device 10, and FIG. 7B shows image data for display. It is a figure which shows a transmission state typically.
Image data of an image to be displayed on the display device 10 is generated for each master panel unit 2 and panel unit 3 by processing of the CPU 41 of the host computer 4. For example, as shown in FIG. 7A, the host computer 4 divides the display image P into, for example, nine parts according to the number of panel units constituting the display device 10, and each divided part. The image data for display is generated and transmitted. As a result, the divided images are displayed by the master panel unit 2 and the panel unit 3, and one image P is displayed using the entire display device 10. The ID of the panel unit that displays the image data is added to each image data.

Here, a transfer function executed by the master panel unit 2 and the panel unit 3 will be described. In the display device 10, since the host computer 4 is connected only to the master panel unit 2, image data is transmitted from the master panel unit 2 to each panel unit 3, and control information is transmitted from the panel unit 3 to the host computer 4. For example, control information and image data need to be relayed (transferred) by the master panel unit 2 and the panel unit 3. Therefore, the master panel unit 2 and the panel unit 3 have a function of transferring control information, image data, and the like.
When the master panel unit 2 receives control information, image data, or the like from the host computer 4 via the communication line 11, the master panel unit 2 refers to an ID added as a destination to the received control information, image data, or the like. If the destination ID is its own ID, the control information and the image data are temporarily stored in the RAM 23 and processed by the CPU 21, for example, a drawing process based on the received image data is executed to display the display panel. Display an image.

On the other hand, when the ID added as the destination to the control information or image data received via the communication line 11 is not its own ID, the master panel unit 2 is connected to all the interfaces 26 to which the panel unit 3 is connected. The control information and image data described above are output.
The master panel unit 2 has information that associates the ID assigned to the panel unit 3 with which interface 26 the panel unit 3 having the ID is connected to. When control information, image data, or the like to be transferred to the interface is received, it may be possible to specify from which interface 26 the control information, image data, or the like should be output.

The panel unit 3 has a function of transferring control information, image data and the like input from any one of the interfaces 35. Among the four interfaces 35, the panel unit 3 includes an interface 35 connected to the master panel unit 2 directly or via another panel unit 3, and an interface 35 connected to the panel unit 3 having the following ID. Information to be specified is stored in the nonvolatile memory 24.
When control information, image data, or the like is input from any of the interfaces 35, the panel unit 3 determines the destination ID. If the ID is an ID unique to the master panel unit 2 (for example, hexadecimal FF), the input control information, image data, and the like are output from the interface 35 connected to the master panel unit 2.
When the destination ID is an ID of a panel unit 3 other than itself, the panel unit 3 receives the input control information, image data, and the like from the interface 35 connected to the panel unit 3 having the next ID. Output. When the destination ID of the input control information or image data matches the own ID, the panel unit 3 stores the input control information or image data in the RAM 33 and processes it by the CPU 31.

In this way, control information, image data, etc. transmitted from the host computer 4 to the panel unit 3 are transferred from the master panel unit 2 to the panel unit 3 as shown in FIG. The data is sequentially transferred by each panel unit 3 and reaches the destination panel unit 3. Control information transmitted from the panel unit 3 to the host computer 4 or the master panel unit 2 is transferred by each panel unit 3 in the reverse order of the ID and received by the master panel unit 2. The
For example, the panel unit 3 (ID = 05) in FIG. 7B is not connected to the panel unit 3 having the next ID. Such a panel unit 3 is set to have no transfer destination at the time of the initial setting operation, and all control information and image data to which a destination different from its own ID is added are discarded without being transferred.

As described above, in the display device 10, by transferring control information and image data between the master panel unit 2 and the panel unit 3, the host computer 4, the master panel unit 2, and the panel unit 3 individually receive image data. And control information can be sent and received.
By the way, both the master panel unit 2 and the panel unit 3 which comprise the display apparatus 10 incorporate the electric current detection part 60, and can detect the electric current which self consumes. The master panel unit 2 and the panel unit 3 have a function of determining whether or not a failure or deterioration has occurred in itself based on the consumption current detected by the current detection unit 60.
Here, the deterioration of the master panel unit 2 and the panel unit 3 refers to a state in which the display state of the display panels 27 and 37 has changed from the normal time and needs to be corrected, and a failure causes a change that cannot be corrected. Refers to the state.
Hereinafter, the function of detecting deterioration / failure will be described in detail.

FIG. 8 is a diagram illustrating a configuration example of the consumption current value reference table 60A for failure diagnosis.
The consumption current value reference table 60A illustrated in FIG. 8 includes, for each consumption pattern measurement test pattern displayed on the display panels 27 and 37, the contents of the display image data and the standard when the test pattern is displayed. A standard current value indicating a current value and a failure reference value indicating a current value serving as a reference for determining a failure are set in association with each other. When determining the presence or absence of a failure using this consumption current value reference table 60A, for example, based on the image data for the test pattern, the test pattern is displayed on the display panels 27 and 37, and the current value during the display is measured. Then, the measured value may be compared with the failure reference value.
The consumption current value reference table 60A is stored in the ROM 22 included in the control unit 20 and the ROM 32 included in the control unit 30 and can be referred to by the CPUs 21 and 31.

  For example, when performing failure diagnosis of the display panel 27 in the master panel unit 2, the CPU 21 uses the image data (R, G, B) = (255, 255, 255) as the test pattern set in the current consumption value reference table 60A. ), White is displayed on the entire display panel 27, and the current amount at this time is measured by the current detection unit 60. Then, the CPU 21 determines whether or not the measured current value corresponds to the failure standard value (1200 mA (milliampere) or more and 800 mA or less) of the consumption current value reference table 60A, thereby determining whether or not the device itself has failed. Determine whether. Similarly, the CPU 21 displays each test pattern for displaying red, green, blue, and black on the entire surface of the display panel 27, causes the current detection unit 60 to measure the current value during the display, and consumes current. The presence or absence of a failure is determined by comparing and contrasting with the failure reference value in the value reference table 60A.

Various display panels such as an organic EL panel, a liquid crystal panel, and a plasma display panel display images by controlling display bodies corresponding to the three primary colors of red, blue, and green in order to perform full color display. Therefore, when current consumption is measured by the current detection unit 60 in a state where the entire surfaces of the display panels 27 and 37 are red, blue, green, and white, only the red display body is colored, and only the blue display body is colored. The current consumption in each of the state, the state where only the green display body is colored, and the state where all the display bodies are colored is measured.
For this reason, if the test pattern of the consumption current value reference table 60A is used, it is possible to reliably determine deterioration or failure based on the consumption current for each color of the display body.
Further, when a short-circuit type (short circuit) failure occurs in the internal circuit of the master panel unit 2 or the panel unit 3, the current consumption may exceed the amount of current necessary for display. This failure can be detected based on whether or not the current consumption is the lowest in the normal state, that is, whether or not the current consumption in the state where black is displayed on the entire surface of the display panels 27 and 37 is larger than the normal state. That is, a test pattern in which the entire screen set in the current consumption value reference table 60A is black is displayed, the current consumption is measured by the current detection unit 60, and the current consumption corresponds to the failure reference value (100 mA or more). By determining whether or not, a short-circuit type abnormality can be detected.

Further, when a current-driven light-emitting element is used as a display body such as an organic EL panel, for example, there is a proportional relationship between current consumption and screen brightness. For example, when the brightness of the red display body does not reach the original brightness due to the deterioration of the red display body (light emitting element), the current consumption in a state where red is displayed on the entire surface is lower than usual.
Therefore, by comparing the current consumption for each color of the display body and the current consumption during white display with the standard current value defined in the current consumption value reference table 60A, the luminance drop for each color of the display body and the overall It is possible to detect a significant decrease in luminance.
Specifically, the measured value of the current consumption while displaying the test pattern with the entire screen in red is compared with the standard current value, and if the measured value is larger than the standard current value, the normal preferred state is exceeded. If the measured value is larger than the standard current value, it is determined that the luminance is lower than the normal preferable state. When the luminance increases or decreases, the current adjustment circuit 65 provided in the control units 20 and 30 reduces or increases the current flowing through the display panels 27 and 37 to compensate for the luminance change caused by the deterioration. Thus, what is necessary is just to reduce or increase the brightness | luminance of the display panels 27 and 37 intentionally.

  FIG. 9 is a flowchart showing an abnormality detection process in the display system 1. The deterioration / failure detection process shown in FIG. 9 is started when the host computer 4 gives an instruction to the master panel unit 2. When this abnormality detection process is executed, the CPUs 21 and 31 of the master panel unit 2 and the panel unit 3 function as an abnormality detection unit and a transmission unit.

In the abnormality detection process, first, the host computer 4 instructs the master panel unit 2 to start abnormality detection, and in accordance with this instruction, the master panel unit 2 instructs all panel units 3 to start abnormality detection. (Step S11). In accordance with this instruction, in the master panel unit 2 and all the panel units 3, the CPUs 21 and 31 read the consumption current value reference table 60 </ b> A and display the set test pattern on the display panels 27 and 37, and the consumption being displayed. The current is measured by the current detector 60 (step S12).
Subsequently, the CPUs 21 and 31 included in the master panel unit 2 and the panel unit 3 respectively compare the measurement values for each test pattern measured by the current detection unit 60 with the failure standard values in the consumption current value reference table 60A ( Step S13), it is determined whether or not the measured value of any test pattern corresponds to the failure reference value (Step S14).

Here, when the measured value corresponds to the failure reference value (step S14; Yes), the CPUs 21 and 31 determine that a failure has occurred (step S15). Here, when the CPU 31 determines that a failure has occurred in the panel unit 3, control information indicating the occurrence of the failure is transmitted to the master panel unit 2 (step S16). In this case, the master panel unit 2 receives the control information transmitted from the panel unit 3 and temporarily stores information including the ID of the failed panel unit 3 in the RAM 23.
When the CPU 21 determines that a failure has occurred in the master panel unit 2, information indicating that the device has failed is generated and stored in the RAM 23.
Thereafter, the operation of the display system 1 proceeds to step S20.

On the other hand, when the measurement value of the current detection unit 60 at the time of displaying each test pattern does not correspond to the failure standard value (step S14; No), the CPUs 21 and 31 measure the measurement value of the current detection unit 60 and the consumption current value reference table. The degree of deterioration is determined by comparing with the standard current value of 60A (step S17). The degree of deterioration is, for example, the increase or decrease in luminance described above.
Then, the CPUs 21 and 31 determine whether or not correction for compensating for the influence of deterioration is necessary based on the degree of deterioration (step S18). If it is determined that correction is not necessary, the process proceeds to step S20. .
On the other hand, when it determines with correction | amendment being required (step S18; Yes), the control information which shows deterioration is transmitted to the master panel unit 2 (step S19). In this case, the master panel unit 2 receives the control information transmitted from the panel unit 3 and temporarily stores information including the ID of the deteriorated panel unit 3 in the RAM 23. When the CPU 21 determines that correction is necessary in the master panel unit 2, information indicating that the CPU 21 has deteriorated is generated and stored in the RAM 23.
Thereafter, the operation of the display system 1 proceeds to step S20.

In step S <b> 20, the CPU 21 of the master panel unit 2 transmits information including the ID of the deteriorated master panel unit 2 or panel unit 3 and the ID of the failed master panel unit 2 or panel unit 3 to the host computer 4.
Receiving this information, the host computer 4 stores the ID of the failed master panel unit 2 or panel unit 3 and determines the processing to be performed in response to the deteriorated master panel unit 2 or panel unit 3 (step S21). ).
Then, the host computer 4 transmits control information including an instruction necessary for executing the determined process to the master panel unit 2 and the panel unit 3 (step S18), and ends this process.

Here, the corresponding process determined by the host computer 4 in step S21 (FIG. 9) is, for example, the following processes (1) to (3).
(1) In a specific master panel unit 2 or panel unit 3, when the current consumption when white is displayed on the entire surface is lower than the other master panel unit 2 and panel unit 3, that master panel unit 2 or panel unit 3 , Current consumption is increased by the current adjustment circuit 65.
(2) In a specific master panel unit 2 or panel unit 3, when the current consumption when white is displayed on the entire surface is lower than other master panel units 2 and panel units 3, other master panel units 2 and panels In the unit 3, current consumption is reduced by the current adjustment circuit 65.
(3) If a specific master panel unit 2 or panel unit 3 has a current consumption lower than other master panel units 2 and 3 when any one of red, blue, and green is displayed on the entire surface, that master The image data output to the panel unit 2 or the panel unit 3 is corrected. When the current consumption during the entire red display is low, the image data is corrected so that the luminance of the red component is improved. Similarly, when the current consumption during the entire blue display is low, the image data is corrected so that the luminance of the blue component is improved. When the current consumption during the entire green display is low, the image is displayed so that the luminance of the green component is improved Correct the data. Specifically, the RGB component values themselves of the image data may be changed, or the gamma value may be adjusted.

Among the processes (1) to (3), (1) and (2) transmit control information from the host computer 4 to the master panel unit 2 or the panel unit 3, and the master panel unit 2 or the panel unit. 3, it can be easily realized by adjusting the current adjustment circuit 65 under the control of the CPUs 21 and 31. When executing the process (3), the host computer 4 may correct the image data transmitted from the host computer 4 to the corresponding master panel unit 2 or panel unit 3.
In the processes (1) and (2), data indicating the correspondence (proportional relationship) between the change in luminance of the display panels 27 and 37 and the change in current consumption is set in the host computer 4, and based on this data, the host computer 4 may transmit control information to the master panel unit 2 and the panel unit 3.
In addition, a circuit for supplying power to the display bodies 27A and 37A of the display panels 27 and 37 is provided for each display color, and the current adjustment circuit 65 is configured to be able to adjust the supply current for each display color. It is preferable to instruct to adjust the current for each color by the control information transmitted from the host computer 4 to the master panel unit 2 and the panel unit 3.

  Similarly, in the process (3), data indicating the correspondence between the luminance change of the display panels 27 and 37 and the change of the image data (luminance data for each RGB or gamma value) is set in the host computer 4. Based on this, the host computer 4 may transmit control information to the master panel unit 2 or the panel unit 3. Furthermore, in the process of (3), image data output to all the master panel units 2 and panel units 3 may be corrected except for the deteriorated master panel unit 2 or panel unit 3. Also in this case, unevenness of the display state in the display device 10 can be prevented.

As described above, in the display device 10, when any one of the master panel unit 2 or the panel unit 3 is deteriorated and the luminance is reduced, the luminance of the master panel unit 2 or the panel unit 3 having the reduced luminance is set. By improving or reducing the brightness of the other master panel unit 2 and the panel unit 3, the variation in the display state of the entire display device 10 can be eliminated, and a uniform and good display can be performed.
The failure detection processing shown in FIG. 9 may be started by transmitting control information from the host computer 4 to the master panel unit 2 and the panel unit 3, but for example, once a day at a preset time. The master panel unit 2 and the panel unit 3 may autonomously start the failure detection process, or the failure detection process may be started when the display device 10 is activated.

When the master panel unit 2 or the panel unit 3 constituting the display device 10 breaks down, the host computer 4 controls the display device 10 so that the master panel unit 2 or the panel unit 3 can be easily repaired or replaced. A fault identification display is performed.
10A to 10C are diagrams showing examples of failure identification displays. These fault identification displays shown in FIGS. 10A to 10C are not displayed during normal operation. For example, when the input unit 45 of the host computer 4 inputs an instruction to shift to the maintenance mode, the display of the display device 10 is switched from the normal display to the failure identification display.

The examples of FIGS. 10A to 10C are all examples in the case where the panel unit 3 at the center of the display device 10 has failed. The host computer 4 that causes the display device 10 to perform the failure identification display shown in FIGS. 10A to 10C functions as a display control unit.
In the example of FIG. 10A, the display device 10 is displaying the image P (FIG. 7A), and the panel units 3 around (upper, lower, left, and right) around the defective panel unit 3 are An arrow pointing toward the broken panel unit 3 is displayed in a superimposed manner. In the example of FIG. 10B, in the state where the image P is displayed, the display of the image on the failed panel unit 3 is stopped, and a cross is displayed on the entire screen. In the example of FIG. 10C, in the state where the image P is displayed, the display of the image in the defective panel unit 3 is turned off. Of these, the example of FIG. 10B is limited to the case where the faulty panel unit 3 maintains the performance that can display the X mark. It can be very clearly identified which panel unit 3 is out of order. Therefore, for example, when the display device 10 is maintained, an operation of replacing the failed panel unit 3 can be easily performed.

  In the maintenance mode, not only the failed master panel unit 2 and panel unit 3 but also the master panel unit 2 and panel unit 3 determined to have deteriorated by the processing shown in FIG. The display for failure identification shown in C) may be performed. In this case, there is an advantage that the work of replacing the deteriorated master panel unit 2 and the panel unit 3 becomes easy. In addition, for the deteriorated master panel unit 2 or panel unit 3, when the apparent problem has been solved by the corresponding processing of (1) to (3) described above, which master panel unit 2 or panel unit 3 is It is difficult to visually determine whether it has deteriorated. In such a case, if the failure identification display is performed, it is possible to quickly confirm where the deteriorated master panel unit 2 or panel unit 3 is.

  As described above, according to the display system 1 according to the embodiment to which the present invention is applied, the master panel unit 2 and the panel unit 3 included in the display device 10 can be treated as abnormalities such as failure and deterioration in each master panel unit 2. And the master panel unit 2 and the panel unit 3 themselves detect based on the current consumption of the panel unit 3, and the master panel unit 2 and the panel unit 3 themselves adjust the luminance of the display panels 27 and 37 according to this abnormality. It is changed by the circuit 65. Therefore, the master panel unit 2 and the panel unit 3 constituting the display device 10 can detect an abnormality and perform processing corresponding to the abnormality without depending on an external device. Accordingly, when an abnormality occurs in the display device 10, the individual master panel unit 2 and the panel unit 3 quickly detect the abnormality and cope with it, so that the display state of the display device 10 can be changed without taking any special measures. Can keep good.

  When the master panel unit 2 and the panel unit 3 detect an abnormality, the master panel unit 2 and the panel unit 3 transmit control information indicating their own abnormality to the master panel unit 2, and the master panel unit 2 Information including the ID of the panel unit 3 is transmitted to the host computer 4. Then, the host computer 4 determines the handling process and performs the handling processes as described in (1) to (3) above. Thereby, since the host computer 4 can determine how to deal with the abnormality, it is possible to execute complicated handling processing such as cooperating a plurality of the master panel unit 2 and the panel unit 3, and (3) Thus, it is possible to correct the image as described above, or to perform a display such as the display shown in FIGS. As a result, the occurrence of an abnormality can be quickly detected and easily dealt with, and a fine response can be made to the abnormality. Further, the host computer 4 can reliably manage the state of each master panel unit 2 and panel unit 3 constituting the display device 10.

In particular, when the display shown in FIGS. 10A to 10C is performed, which of the plurality of master panel units 2 and the panel unit 3 constituting the display device 10 is an abnormal unit. Since it is clearly visible, in addition to checking the status of the master panel unit 2 and the panel unit 3, operations such as repair and replacement can be easily performed.
Furthermore, if the brightness of the display panel is increased or decreased by correcting the image data of the master panel unit 2 or the panel unit 3 as in the process (3) above, a configuration that adjusts the brightness itself is used. Therefore, it is possible to quickly compensate for an abnormality in luminance that causes display unevenness of the display device 10.

  Further, the master panel unit 2 and the panel unit 3 have a current adjustment circuit 65 built therein, and when an abnormality in which the luminance of the display panels 27 and 37 decreases or increases is detected, the current adjustment circuit 65 changes the luminance. Compensate for abnormalities. Thereby, it is possible to quickly detect and eliminate a luminance abnormality that causes display unevenness in the display device 10 and maintain a good display state.

  Further, in the display system 1, each master panel unit 2 and panel unit 3 constituting the display device 10 detects its own abnormality, and when an abnormality is detected, information indicating its own abnormality is displayed on the master panel unit 2. To the host computer 4, and the host computer 4 changes the display state of the display device 10 in accordance with this information. As a result, the display unit itself can quickly detect an abnormality in the display unit. In addition, by changing the display state of the plurality of display units by the display control unit, it is possible to perform a complicated and effective response to the abnormality of the display units.

In the above embodiment, when the panel unit 3 detects its own abnormality in the abnormality detection process shown in FIG. 9, information indicating the abnormality is transmitted from the panel unit 3 to the master panel unit 2, and the master panel unit 2. However, the present invention is not limited to this, and each master panel is described as transmitting information including IDs of all master panel units 2 or panel units 3 in which an abnormality has been detected. When all of the unit 2 and the panel unit 3 detect an abnormality, the control information may be directly transmitted to the host computer 4.
In the above embodiment, the master panel unit 2 having the four interfaces 26 and the panel unit 3 having the four interfaces 35 have been described as examples. However, the present invention is not limited to this. For example, if the master panel unit 2 is arranged at the corner of the display device 10, the master panel unit 2 only needs to have at least two interfaces 26. Further, when the master panel unit 2 is arranged on the top, bottom, left, and right edges (ends) of the display device 10, the master panel unit 2 only needs to have three interfaces 26. Similarly, the panel unit 3 may be provided with two interfaces 35 when arranged at the corner, and may be provided with three interfaces 35 when arranged at the upper, lower, left and right edges.
Furthermore, the number of master panel units 2 and panel units 3 constituting the display device 10 is arbitrary, and when a plurality of master panel units 2 constitute one display device 10, any one of the master panel units 2 The operation may be performed in the same manner as the panel unit 3, or the other panel unit 3 may be divided into the same number of groups as the master panel unit 2 and the above-described processing may be executed for each group. In addition, the detailed configuration of the display system 1 described in the above embodiment can be arbitrarily changed.

It is a figure which shows the structure of the display system which concerns on embodiment of this invention. It is an external view which shows the structure of a master panel unit and a panel unit. It is a functional block diagram of a master panel unit and a host computer. It is the functional block diagram of a panel unit, and the block diagram of an interface. It is a block diagram of a consumption current detection part and a current adjustment circuit. It is a figure which shows the structural example of the panel arrangement | positioning information which a host computer has. It is a figure explaining the process which displays an image on a display panel. It is a figure which shows the structural example of a consumption current value reference table. It is a flowchart which shows an abnormality detection process. It is a figure which shows the example of the display for failure identification.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1, 1A ... Display system, 2 ... Master panel unit (display unit), 3 ... Panel unit (display unit), 4 ... Host computer (display control part), 5, 6 ... Base part, 10 ... Display apparatus, 11 ... Communication line 20 ... Control unit 21, 31 ... CPU (abnormality detection unit, transmission unit), 24, 34 ... Non-volatile memory, 25 ... Host connection interface, 26, 35 ... Interface, 27, 37 ... Display panel, 27A, 37A ... display body, 28, 30 ... control unit, 38 ... housing, 41 ... CPU, 44 ... storage unit, 60 ... current detection unit, 60A ... current consumption value reference table, 65 ... current adjustment circuit (display adjustment) Part).

Claims (8)

In a display system including a display device configured by arranging a plurality of display units having a display panel,
The display unit is
A current detection unit for detecting current consumption of itself;
An abnormality detection unit for detecting an abnormality based on the consumption current detected by the current detection unit;
A display adjustment unit that changes a display state on the display panel when a self-abnormality is detected by the abnormality detection unit;
A display system characterized by The display unit includes a transmission unit that transmits information indicating its own abnormality when an abnormality is detected by the abnormality detection unit,
A display control unit that receives information indicating an abnormality transmitted from the display unit and transmits an instruction to change a display state to the display unit;
The display adjustment unit included in the display panel changes a display state on the display panel according to an instruction transmitted from the display control unit;
The display system according to claim 1. The display adjustment unit increases or decreases the luminance of the display panel by increasing or decreasing the current flowing through the display panel;
The display system according to claim 1, wherein: In a display system including a display device configured by arranging a plurality of display units having a display panel,
The display unit is
A current detector for detecting current consumption;
An abnormality detection unit for detecting an abnormality based on the consumption current detected by the current detection unit;
A transmission unit that transmits information indicating the abnormality of the self when the abnormality of the abnormality is detected by the abnormality detection unit;
The display device includes a display control unit that receives information indicating an abnormality transmitted from the display unit and changes a display state of the display device;
A display system characterized by The display control unit is configured to perform an identification display for identifying the display unit detected by the abnormality detection unit in the display device;
The display system according to claim 4. The display control unit transmits the information indicating its own abnormality when the display device performs the identification display, or a display state in the display unit located around the display unit. Controlling the display unit detected by the abnormality detection unit,
The display system according to claim 5. The display control unit increases or decreases the luminance of the display panel by correcting an image displayed on the display unit detected by the abnormality detection unit;
The display system according to claim 4. A control method for controlling a display system including a display device configured by arranging a plurality of display units,
Each of the display units detects current consumption, detects an abnormality based on the detected current consumption, and when there is an abnormality, transmits information indicating its own abnormality,
Changing the display state of the display device based on the information indicating the abnormality transmitted from the display unit;
A display system control method characterized by the above.

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