JP2012222637A - Multi-screen display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a multi-screen display device that can easily control variations of luminance among screens of a plurality of image display devices.SOLUTION: A multi-screen display device 10 displays an image on a multi-screen 20 made up of combination of the screens 2a-2d of a plurality of image display devices 1a-1d. Among the plurality of image display devices 1a-1d, the master device 1a determines a target luminance value based on a standard luminance value which is a luminance value of a screen 2 when predetermined current is supplied to a light source 3a of its own device, and the standard luminance value of the slave devices 1b-1d obtained via communication means. Each image display device 1a-1d reads out an output value of a luminance sensor 3f of the own device corresponding to the target luminance value as a target luminance output value from a memory circuit 4d, and controls current to be supplied to the light source 3a of the own device by a light source driver 3b such that the output value of the luminance sensor 3f of the own device becomes nearly equal to the target luminance output value.

Description

  The present invention relates to a multi-screen display device that displays a video by combining a plurality of video display device screens to form a single screen.

  There is a multi-screen display device as a device for displaying an image on a large screen. A multi-screen display device forms a single large screen by combining the screens of a plurality of video display devices, and displays video. As a video display device constituting the multi-screen display device, for example, there is a projection type video display device.

  The projection-type image display device displays an image on the surface of the screen by irradiating the image display device with light from a light source and projecting the image from the back of the screen. As the light source, for example, a high voltage discharge lamp or a light emitting diode (abbreviation: LED) which is a semiconductor light emitting element is used.

  Devices such as high voltage discharge lamps and LEDs have manufacturing variations. Due to this variation, the brightness of the screen may vary among a plurality of projection type video display devices. In a multi-screen display device, a plurality of projection-type video display devices are combined to form a single screen (hereinafter sometimes referred to as “multi-screen”). The brightness difference between the screens becomes conspicuous, and the sense of unity of the multi-screen may be impaired.

  In a multi-screen display device, for example, Patent Literature 1 discloses a technique for correcting variations in luminance between screens constituting a multi-screen. In the technique disclosed in Patent Literature 1, after installing a multi-screen display device, an operator visually adjusts the brightness between screens to match. Further, in Patent Document 1, an operator obtains an adjustment value using a measuring instrument such as a luminance meter instead of visual observation, and adjusts the luminance between the screens using the obtained adjustment value. There is also disclosed a method for suppressing variations in luminance.

Japanese Patent No. 3287007

  In the method in which the operator adjusts the luminance by visual observation or using a measuring instrument after installing the multi-screen display device as disclosed in Patent Document 1, it takes a lot of time to measure and adjust the luminance. Further, depending on the installation location and the number of screens constituting the multi-screen, it may be difficult to adjust visually or with a measuring instrument. Further, in the visual adjustment, the brightness of the multi-screen after the adjustment may vary due to variations in the technique of the operator.

  In addition, when adjusting the luminance and chromaticity by adjusting the level of the video signal representing the gradation, in each projection type video display device of the multi-screen display device after adjusting the level of the video signal, The key expression level may be impaired. For example, when an LED is used as the light source, chromaticity cannot be corrected by simply adjusting the LED starting current and adjusting the output of the light source.

  An object of the present invention is to provide a multi-screen display device that can easily suppress variations in luminance among screens of a plurality of video display devices.

  The multi-screen display device of the present invention includes a plurality of projection-type video display devices, and displays video on a multi-screen configured by combining the screens of the plurality of video display devices based on an input video signal. A multi-screen display device, wherein the plurality of video display devices are communicably connected by a communication means, and each video display device outputs an output value corresponding to a luminance value of a video on its screen. A detection means; a light source that outputs light having an intensity corresponding to a supplied current for image projection onto the screen; a current control means that controls a current supplied to the light source; and a luminance value of an image on the screen Storage means for storing the output value of the luminance detection means corresponding to the one of the plurality of video display devices, wherein one of the video display devices is supplied with a predetermined value of current to the light source of the device itself When said Based on the standard luminance value, which is the luminance value of the image on the screen, and the standard luminance value of the video display device other than its own device obtained through the communication means, a target luminance value as a common target is determined. Each of the video display devices reads (a) an output value of the luminance detection unit of the own device corresponding to the target luminance value as a target luminance output value from the storage unit of the own device, and (b) the own device. A value of a current supplied to the light source of the device when the output value of the luminance detection means is substantially equal to the target luminance output value, and (c) the device of the device Control is performed by the current control means of the apparatus itself so that the value of the current supplied to the light source becomes the optimum control current value.

  According to the multi-screen display device of the present invention, any one of the plurality of video display devices determines the target luminance value, and each of the plurality of video display devices obtains the output value of the luminance detection means corresponding to the target luminance value. As described above, the current of the optimum control current value is supplied to the light source by the current control means. Accordingly, it is possible to obtain a multi-screen display device that can easily suppress variations in luminance among the screens of a plurality of video display devices, as compared with the prior art.

It is a figure which shows typically the multi-screen display apparatus 10 which is the 1st Embodiment of this invention. It is a block diagram which shows the structure of the projection type video display apparatus 1 shown in FIG. It is a graph which shows the luminance-sensor output characteristic showing the relationship between the luminance value of the image | video on the screen 2, and the output value of R luminance sensor 3fa corresponding to it. It is a graph which shows the luminance-sensor output characteristic showing the relationship between the luminance value of the image | video on the screen 2, and the output value of G luminance sensor 3fb corresponding to it. It is a graph which shows the luminance-sensor output characteristic showing the relationship between the luminance value of the image | video on the screen 2, and the output value of B luminance sensor 3fb corresponding to it. It is a flowchart which shows the process sequence of the microcomputer circuit 4c regarding the correction process of the brightness | luminance in the master apparatus 1a of the multi-screen display apparatus 10 which is the 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the microcomputer circuit 4c regarding the luminance correction process in the 1st-3rd slave apparatus 1b, 1c, 1d of the multi-screen display apparatus 10 which is the 1st Embodiment of this invention. It is a graph which shows the relationship between a control electric current value and chromaticity value. It is a flowchart which shows the process sequence of the microcomputer circuit 4c regarding the correction process of the brightness | luminance and chromaticity in the master apparatus 1a of the multi-screen display apparatus which is the 2nd Embodiment of this invention. FIG. 10 is a chromaticity diagram used when the master device 1a determines a target chromaticity value in step c13 of FIG. 9. It is a flowchart which shows the process sequence of the microcomputer circuit 4c regarding the correction process of the brightness | luminance and chromaticity in the 1st-3rd slave apparatus 1b-1d of the multi-screen display apparatus which is the 2nd Embodiment of this invention. It is a figure which shows the multiscreen display apparatus 50 of the premise technique of this invention.

<Prerequisite technology>
Before describing the multi-screen display device of the present invention, the multi-screen display device of the prerequisite technology of the present invention will be described. FIG. 12 is a diagram showing a multi-screen display device 50 as a prerequisite technology of the present invention. As shown in FIG. 12, the multi-screen display device 50 includes a plurality of, here, four, projection type video display devices 51a to 51d.

  Each of the projection-type image display devices 51a to 51d is configured to be able to project an image on the screens 52a to 52d. In FIG. 12, only the screens 52a to 52d are shown among the configurations of the projection type video display devices 51a to 51d, and description of the other configurations is omitted. The multi-screen display device 50 displays video on a large-scale screen (hereinafter also referred to as “multi-screen”) 53 configured by combining the screens 52a to 52d of the plurality of projection type video display devices 51a to 51d. It is possible.

  When such a multi-screen display device 50 is used for the first time after manufacture, variations in brightness may occur between the screens 52a to 52d due to manufacturing variations of the projection type image display devices 51a to 51d. . As a result, for example, when each of the projection type video display devices 51a to 51d displays white on the entire screens 52a to 52d based on the all white video signal, as shown in FIG. A brightness difference may occur between them, and the sense of unity of the multi-screen 53 may be impaired.

  Thus, when a brightness | luminance difference arises between the screens 52a-52d of the projection type video display apparatuses 51a-51d, in the multi-screen display apparatus 50 of a premise technique, for example, an operator visually or using a measuring device. The brightness difference is suppressed by adjusting the brightness of each of the projection type video display devices 51a to 51d.

  However, this method requires a lot of time to measure and adjust the luminance. Further, depending on the installation location of the multi-screen display device 50 and the number of screens constituting the multi-screen 53, it may be difficult to adjust the brightness of each of the projection display devices 51a to 51d by visual observation or using a measuring instrument. is there. In addition, in the visual adjustment, the brightness of the adjusted multi-screen 53 may vary due to variations in the technique of the operator.

  In addition, when adjusting the luminance and chromaticity correction by adjusting the level of the video signal representing the gradation, the gradation expression is expressed in each of the projection type video display devices 51a to 51d of the adjusted multi-screen display device 50. The level may be impaired. Further, when a light emitting diode (LED) is used as a light source, chromaticity cannot be corrected by simply adjusting the LED starting current to adjust the output of the light source.

  Therefore, the multi-screen display device of the present invention employs the configuration shown in the following embodiments.

<First Embodiment>
FIG. 1 is a diagram schematically showing a multi-screen display device 10 according to a first embodiment of the present invention. The multi-screen display device 10 includes a projection type video display device that is a plurality of projection type video display devices. In the present embodiment, the multi-screen display device 10 includes four projection type video display devices 1a to 1d. Each of the projection type video display devices 1a to 1d is configured to be able to project video onto the screens 2a to 2d. In FIG. 1, for easy understanding, only the screens 2 a to 2 d are shown among the configurations of the projection type video display devices 1 a to 1 d, and the other configurations are not shown. Of the screens 2a to 2d, portions where images are displayed are referred to as screens of the projection type image display devices 1a to 1d. In the present embodiment, the entire screens 2a to 2d are screens.

  In the following description, the screens 2a to 2d may be referred to as screens 2a to 2d. Further, the “projection type video display device” may be simply referred to as “video display device”. In FIG. 1, in order to distinguish the four video display devices 1, subscripts “a”, “b”, “c”, and “d” are added to the reference numeral “1” of the video display device, 1 video display device 1a ”,“ second video display device 1b ”,“ third video display device 1c ”, and“ fourth video display device 1d ”. When it is not necessary to distinguish the four video display apparatuses 1, the subscripts “a” to “d” of the reference sign “1” of the video display apparatus are omitted.

  In the multi-screen display device 10, the screens 2 a to 2 d that are the screens of the four video display devices 1 a to 1 d are combined to form one large-scale screen (hereinafter sometimes referred to as “multi-screen”) 20. An image can be displayed on the screen 20. In FIG. 1, a screen 2 which is a screen of each video display device 1 is given a subscript “a”, “b”, “c”, “d” indicating the video display device 1, and a first screen 2 a. , A second screen 2b, a third screen 2c, and a fourth screen 2d. In the present embodiment, the multi-screen 20 that is the display screen of the multi-screen display device 10 is configured by arranging the first to fourth screens 2a to 2d in a matrix.

  In the multi-screen display device 10, in order to perform communication between the video display devices 1a to 1d, the first to fourth video display devices 1a to 1d are connected by a communication cable 7 which is a communication means. In the example shown in FIG. 1, the first video display device 1a and the second video display device 1b are connected by a communication cable 7, and the second video display device 1b and the third video display device 1d are connected by a communication cable 7. The third video display device 1d and the fourth video display device 1c are connected by a communication cable 7. Thus, the four video display devices 1 a to 1 d constituting the multi-screen display device 10 are communicably connected by the communication cable 7.

  Each video display device 1a to 1d is assigned a unique ID (Identification) number that does not overlap. In the example shown in FIG. 1, the ID numbers of the first to fourth video display devices 1a to 1d are ID1, ID2, ID3, and ID4, respectively. The first to fourth video display devices 1a to 1d are a master device that supervises control of the first to fourth video display devices 1 when communicating between the first to fourth video display devices 1a to 1d. And the slave device controlled by the master device. Whether the video display devices 1a to 1d are used as master devices or slave devices is set by a user, for example.

  In the present embodiment, the first video display device 1a assigned ID1 as the ID number is a master device, and the second to fourth video display devices 1b-1d assigned ID2 to ID4 are slave devices. To do. Therefore, in the example illustrated in FIG. 1, the first video display device 1 a that is a master device controls the second to fourth video display devices 1 b to 1 d that are slave devices. In the following description, the first video display device 1a is referred to as “master device 1a”, and the second to fourth video display devices 1b to 1d are respectively referred to as “first slave device 1b”, “second slave device 1c”, It may be referred to as “third slave device 1d”.

  FIG. 2 is a block diagram showing a configuration of the projection display apparatus 1 shown in FIG. The configurations of the master device 1a and the slave devices 1b to 1d, which are the projection type image display device 1, are almost the same, and therefore, without distinguishing between the master device 1a and the slave devices 1b to 1d, the projection type image display device 1 has the same configuration. The configuration will be described.

  The projection-type image display device 1 includes the screen 2, the projection unit 3, and the electric circuit unit 4 described above. The projection unit 3 includes a light source 3a, a light source driver 3b, a light source synthesis device 3c, a video display device 3d, a luminance sensor 3f, and a projection lens 3e. The electric circuit unit 4 includes a video input circuit 4a, a video processing circuit 4b, a microcomputer (hereinafter referred to as “microcomputer”) circuit 4c, and a memory circuit 4d.

  The video input circuit 4 a of the electric circuit unit 4 is connected to a video source 5 installed outside the video display device 1. The video source 5 outputs an analog video signal. The analog video signal output from the video source 5 is input to the video input circuit 4a. The video input circuit 4a receives an analog video signal from the input video source 5 and converts it into a digital video signal (hereinafter sometimes referred to as “digital video signal”), and the digital video signal is processed by video processing. This is given to the circuit 4b.

  The video processing circuit 4b performs processing for adjusting the image quality of the video represented by the video signal (hereinafter sometimes referred to as “image quality adjustment processing”) on the digital video signal supplied from the video input circuit 4a. Thereafter, the video processing circuit 4b converts the digital video signal after the image quality adjustment processing into a digital signal format required by the video display device 3d of the projection unit 3, and supplies the digital signal format to the video display device 3d.

  Here, the image quality adjustment processing performed by the video processing circuit 4b will be described. The video processing circuit 4b is a signal level of the three primary colors of light represented by the digital video signal supplied from the video input circuit 4a, that is, red (abbreviation: R), green (abbreviation: G), blue (blue). : B) Image quality adjustment processing is performed to increase or decrease each signal level independently for each pixel of the screen and for each primary color. In the present embodiment, the video processing circuit 4b has a calculation function for performing a 3 × 3 matrix calculation represented by the following expression (1) on the digital video signal given from the video input circuit 4a as an image quality adjustment process. Have. The video processing circuit 4b performs image quality adjustment by performing a 3 × 3 matrix operation.

  In equation (1), Ri, Gi, Bi indicate the signal levels of R, G, B indicated by the input signal, that is, the digital video signal given from the video input circuit 4a by the video processing circuit 4b. Also, RR, RG, RB, GR, GG, GB, BR, BG, BB indicate correction coefficients, and Ro, Go, Bo indicate R indicated by the corrected video signal supplied from the video processing circuit 4b to the projection unit 3. , G and B signal levels are shown.

  According to the calculation of the equation (1), for example, the signal level of Ro is obtained by adding the signal levels of Gi and Bi slightly to the signal level of Ri. The video processing circuit 4b performs such calculation, thereby adjusting the luminance and chromaticity of the R single color, mainly the chromaticity, as the image quality adjustment processing described above. Similarly, the video processing circuit 4b adjusts luminance and chromaticity, mainly chromaticity, for the G and B colors, respectively.

  The light source 3a of the projection unit 3 outputs light having an intensity corresponding to the supplied current for video projection onto the screen 2, which is a screen. In the present embodiment, the light source 3a is a light source of three primary colors constituted by semiconductor light emitting elements such as LEDs. The light source 3a includes a plurality of light sources 3ac, 3ab, 3ac that output light corresponding to the three primary colors of light for video projection onto the screen 2, respectively. Specifically, the light source 3a includes a red light source (hereinafter sometimes referred to as “R light source”) 3aa that emits red (R) light and a green light source (hereinafter referred to as “G light source”) that emits green (G) light. 3ab and a blue light source (hereinafter also referred to as “B light source”) 3ac that emits blue (B) light. The R light source 3aa, the G light source 3ab, and the B light source 3ac correspond to color light sources.

  The light source driver 3b of the projection unit 3 corresponds to current control means and controls the current supplied to the light source 3a. In the present embodiment, the light source driver 3b provides the light source 3a with a control current (hereinafter sometimes referred to as “drive current”) for the light source 3a to emit light. When the light source driver 3b supplies the control current to the light source 3a in a time division manner, light emission of the light source 3a, that is, output light from the light source 3a is controlled in a time division manner.

  The luminance sensor 3f of the projection unit 3 corresponds to a luminance detection unit. The luminance sensor 3f detects the amount of light projected on the screen 2, in other words, the luminance value of the image displayed on the screen 2 that is the screen (hereinafter sometimes referred to as “the luminance value of the image on the screen 2”). The detected luminance value is output to the microcomputer circuit 4 c of the electric circuit unit 4. In the present embodiment, the luminance sensor 3f does not directly detect and output the luminance value of the video on the screen 2, but outputs an output value corresponding to the luminance value.

  Specifically, in the projection unit 3, light emitted from the light source 3a and irradiated onto the video display device 3d via the light source synthesis device 3c is not projected onto the screen 2 (hereinafter referred to as “unnecessary light”). May be guided to the luminance sensor 3f by the video display device 3d. The luminance sensor 3f receives the unnecessary light guided from the video display device 3d and detects the amount of unnecessary light.

  The luminance sensor 3f outputs data representing the detected amount of unnecessary light (hereinafter referred to as “light amount data”) to the microcomputer circuit 4c. The light amount data representing the amount of unnecessary light corresponds to an output value corresponding to the luminance value of the image on the screen 2. The microcomputer circuit 4c detects the light amount projected from the light source 3a onto the screen 2, in other words, the luminance value of the image on the screen 2 based on the light amount data output from the luminance sensor 3f.

  The luminance sensor 3f includes a red luminance sensor (hereinafter referred to as “R luminance sensor”) 3fa that detects red (R) light and a green luminance sensor (hereinafter referred to as “G luminance sensor”) that detects green (G) light. 3 fb and a blue luminance sensor (hereinafter referred to as “B luminance sensor”) 3 fc for detecting blue (B) light.

  In FIG. 2, the luminance sensor 3f detects unnecessary light that is not projected onto the screen 2 in the video display device 3d, thereby detecting the amount of light projected from the light source 3a onto the screen 2, and the luminance value of the video on the screen 2 is calculated. An example of pseudo detection is shown. For example, when the video display device 1 is realized by a liquid crystal video display device, the light amount of light output from the backlight, which is a light source, is detected by the luminance sensor 3f, and based on the detected light amount. Thus, the luminance value of the image on the screen 2 may be detected in a pseudo manner. In this case, the amount of light detected by the luminance sensor 3f corresponds to an output value corresponding to the luminance value of the image on the screen 2.

  The light source synthesis device 3c synthesizes the light output from the R light source 3aa, the G light source 3ab, and the B light source 3ac of the light source 3a, and gives them to the video display device 3d. The video display device 3d is realized by, for example, a digital mirror device (abbreviation: DMD). The video display device 3d generates video light by intensity-modulating the light supplied from the light source synthesis device 3c based on the digital video signal supplied from the video processing circuit 4b. The video display device 3d projects the generated video light onto the surface of the screen 2 via the projection lens 3e. As a result, the video represented by the digital video signal supplied from the video processing circuit 4b is displayed on the screen 2.

  The microcomputer circuit 4 c of the electric circuit unit 4 is connected to an external control device 6 installed outside the video display device 1. The microcomputer circuit 4 c comprehensively controls each component of the video display device 1 based on a control signal or the like given from the external control device 6. Specifically, the microcomputer circuit 4c controls the luminance of the light source 3a by controlling the control current value applied to the light source 3a via the light source driver 3b. Further, the microcomputer circuit 4c writes various control data corresponding to the luminance value of the image on the screen 2 including the output value of the luminance sensor 3f for each of R, G, and B into the memory circuit 4d, and from the memory circuit 4d. Processing for reading the various control data is performed. The memory circuit 4d corresponds to storage means, and stores the output value of the luminance sensor 3f corresponding to the luminance value of the image on the screen 2.

  FIG. 3 is a graph showing a luminance-sensor output characteristic representing the relationship between the luminance value of the image on the screen 2 and the corresponding output value of the R luminance sensor 3fa. FIG. 4 is a graph showing a luminance-sensor output characteristic representing the relationship between the luminance value of the image on the screen 2 and the corresponding output value of the G luminance sensor 3fb. FIG. 5 is a graph showing the luminance-sensor output characteristics representing the relationship between the luminance value of the image on the screen 2 and the corresponding output value of the B luminance sensor 3fb. 3 to 5, the horizontal axis represents the luminance value of the image on the screen 2. The vertical axis in FIG. 3 represents the sensor output value output from the R luminance sensor 3fa. The vertical axis in FIG. 4 represents the sensor output value output from the G luminance sensor 3fb. The vertical axis in FIG. 5 represents the sensor output value output from the B luminance sensor 3fc.

  Based on the graph shown in FIG. 3, the luminance value YRT of the R signal in the video on the screen 2 can be obtained from the output value SRT of the R luminance sensor 3fa. Based on the graph shown in FIG. 4, the luminance value YGT of the G signal in the video on the screen 2 can be obtained from the output value SGT of the G luminance sensor 3fb. Based on the graph shown in FIG. 5, the luminance value YBT of the B signal in the video on the screen 2 can be obtained from the output value SBT of the B luminance sensor 3fc.

  In the present embodiment, a luminance-sensor output characteristic representing the relationship between the luminance value of the image on the screen 2 shown in FIGS. 3 to 5 and the sensor output value corresponding thereto is stored in the memory circuit 4d in advance. . The memory circuit 4d storing the luminance-sensor output characteristic corresponds to the memory circuit 4d storing a sensor output value corresponding to the luminance value of the image on the screen 2.

  Further, the microcomputer circuit 4c provides a luminance value (hereinafter referred to as "standard luminance") of the image on the screen 2 when a predetermined current (hereinafter referred to as "predetermined control current value") is applied to the light source 3a. It may be possible to perform a process of writing a value to the memory circuit 4d and a process of reading a standard luminance value from the memory circuit 4d.

  The microcomputer circuit 4c of the master device 1a and the microcomputer circuit 4c of the slave devices 1b to 1d can exchange information with each other via the communication cable 7 and a communication interface (not shown). For example, the microcomputer circuit 4 c of the master device 1 a transmits a control command to the microcomputer circuits 4 c of the slave devices 1 b to 1 d via the communication cable 7. The microcomputer circuit 4c of the master device 1a is a slave that is directly connected to the master device 1a by the communication cable 7 with respect to the microcomputer circuit 4c of the slave devices 1b to 1d that are not directly connected to the master device 1a by the communication cable 7. A control command is transmitted via the microcomputer circuit 4c of the devices 1b to 1d.

  FIG. 6 is a flowchart showing a processing procedure of the microcomputer circuit 4c related to the luminance correction processing in the master device 1a of the multi-screen display device 10 according to the first embodiment of the present invention. FIG. 7 is a flowchart showing a processing procedure of the microcomputer circuit 4c regarding luminance correction processing in the first to third slave devices 1b, 1c, and 1d of the multi-screen display device 10 according to the first embodiment of the present invention. .

  As a premise of the processing of the flowcharts shown in FIG. 6 and FIG. 7, before each video display device 1 is shipped from the factory, the control current value supplied to the light source 3a is gradually changed for each of R, G, and B. Assume that the memory circuit 4d stores the result of obtaining the brightness value on the screen 2 and the sensor output value output from the brightness sensor 3f corresponding to the brightness value. That is, the memory circuit 4d of each video display device 1 shows the relationship between the luminance value on the screen 2 and the sensor output value output from the corresponding luminance sensor 3f as shown in FIGS. It is assumed that the luminance-sensor output characteristic to be expressed is stored in advance. In addition, it is assumed that a standard luminance value representing a luminance value for each of R, G, and B on the screen 2 when a predetermined control current value is input to the light source 3a is stored in the memory circuit 4d.

  Each process of the flowchart shown in FIG. 6 is executed by the microcomputer circuit 4c of the master device 1a. The processing of the flowchart shown in FIG. 6 is set in the master device when the video display device 1a set as the master device is turned on or the video display device 1a receives a master instruction signal from the external control device 6. Is started, the process proceeds to step a1.

  In step a1, the master device 1a transmits a command to start luminance correction processing (hereinafter referred to as “correction start command”) to all slave devices. In the present embodiment, the master device 1a transmits a correction start command to the first to third slave devices 1b to 1d. The correction start command is given to the slave device that is not directly connected to the master device via the communication cable 7 via the slave device that is directly connected to the master device via the communication cable 7.

  For example, as shown in FIG. 1, a master device 1a and a first slave device 1b are connected, a first slave device 1b and a third slave device 1d are connected, and a third slave device 1d and a second slave device 1c are connected. Is connected, a correction start command is given to the third slave device 1d via the first slave device 1b. A correction start command is given to the second slave device 1c via the first slave device 1b and the third slave device 1d. When the correction start command is transmitted in this way, the master device 1a proceeds to step a2.

  In step a2, the master device 1a obtains a standard luminance value YREF that is a luminance value on the screen 2 when a predetermined control current value IREF, for example, 20A, is given to each of the R, G, and B light sources 3aa, 3ab, 3ac. Read from the memory circuit 4d. In the present embodiment, the master device 1a is configured such that the brightness value YRREFn when the control current value of the R light source 3aa is equal to the specified control current value IREF and the control current value of the G light source 3ab is the specified control current. A luminance value YGREFn when the value IGn is equal to the value IREF and a luminance value YBREFn when the control current value of the B light source 3ac is equal to the specified control current value IREF are read.

  Here, n is a natural number and indicates a number assigned to each video display device 1. The value with n means a value read by the video display device 1 with a number indicated by n, a calculated value, and the like. In the present embodiment, “1” is assigned to the master device 1a, “2” is assigned to the first slave device 1b, and “3” is assigned to the second slave device 1c. The third slave device 1d is assigned “4”.

  Therefore, a value with “1” as n means a value read by the master device 1a or a calculated value. A value with “2” as n means a value read by the first slave device 1b or a calculated value. The value with “3” as n means a value read by the second slave device 1c or a calculated value. The value with “4” as n means a value read by the third slave device 1d or a calculated value.

  In step a3, the master device 1a causes the slave devices 1b to 1d to transmit standard luminance values YRREFn, YGREFn, YBREFn (n = 2 to 4) read from the memory circuit 4d (hereinafter referred to as “brightness value transmission command”). Is transmitted via the communication cable 7.

  In step a4, the master device 1a determines whether or not the standard luminance value transmitted from each of the slave devices 1b to 1d in step b4 of FIG. In step a4, when the master device 1a determines that the standard luminance value transmitted from each of the slave devices 1b to 1d has been received, the master device 1a proceeds to step a5. Wait until

  In step a5, the master device 1a receives the standard luminance values YRREFn, YGREFn, YBREFn (n = 1) of its own device read from the memory circuit 4d in step a2, and each slave device received via the communication cable 7 in step a4. Based on the standard luminance values YRREFn, YGREFn, and YBREFn (n = 2 to 4) of 1b to 1d, common target luminance values that can be output by the multi-screen display device 10 are determined. The target luminance value is a luminance value that is a common target for the plurality of video display devices 1 that constitute the multi-screen display device 10.

  In the present embodiment, the master device 1a sets the red (R) target luminance value YRT = Min (YRREF1, YRREF2, YRREF3, YRREF4) and the green (G) target luminance value YGT = Min (YGREF1, YGREF2, YGREF3). , YGREF4), and blue (B) target luminance value YBT = Min (YBREF1, YBREF2, YBREF3, YBREF4). That is, for each color of R, G, and B, the master device 1a has the standard luminance value of the master device 1a that is its own device, and the first to third slave devices 1b to 1d that are video display devices 1 other than its own device. Among the standard luminance values, the smallest standard luminance value is determined as the target luminance value YRT, YGT, YBT.

  In step a6, the master device 1a transmits the target luminance values YRT, YGT, YBT determined in step a5 to the slave devices 1b to 1d via the communication cable 7.

  In step a7, the master device 1a determines the luminance sensor output value SRTn (corresponding to the target luminance values YRT, YGT, YBT from the luminance-sensor output characteristics shown in FIGS. 3 to 5 stored in the memory circuit 4d. n = 1), SGTn (n = 1), and SBTn (n = 1) are read as target luminance sensor output values. The target luminance sensor output value corresponds to the target luminance output value.

  In step a8, the master device 1a changes the setting of the light source driver 3b while monitoring the output value of the luminance sensor 3f, and increases or decreases the control current value applied to the light source 3a. Then, the master device 1a controls the control current which is the value of the current supplied to the light source 3a when it becomes substantially equal to the target luminance sensor output values SRTn (n = 1), SGTn (n = 1), SBTn (n = 1). The values are determined as optimum control current values IRTn (n = 1), IGTn (n = 1), and IBTn (n = 1). Here, “substantially equal” includes “equal”.

  Specifically, the master device 1a matches the target luminance sensor output values SRTn (n = 1), SGTn (n = 1), SBTn (n = 1), or the target luminance sensor output value SRTn (n = 1), SGTn (n = 1), SBTn (n = 1) closest to the control current value, the optimal control current value IRTn (n = 1), IGTn (n = 1), IBTn (n = 1) ).

  In step a9, the master device 1a sets the optimum control current values IRTn (n = 1), IGTn (n = 1), and IBTn (n = 1) determined in step a8 in the light source driver 3b. Accordingly, the master device 1a causes the control current value given to the light source 3a to be the optimum control current values IRTn (n = 1), IGTn (n = 1), and IBTn (n = 1) determined in step a8. In addition, the light source driver 3b controls. In this way, the master device 1a changes the control current value to be given to the light source 3a based on the target luminance sensor output value. After finishing the process of step a9, all the processing procedures are finished.

  In parallel with the processing of the flowchart shown in FIG. 6 by the master device 1a described above, the processing of the flowchart shown in FIG. 7 is performed in the slave device. Each process of the flowchart shown in FIG. 7 is executed by the microcomputer circuit 4c of the slave device. When a plurality of slave devices are installed, each process of the flowchart shown in FIG. 7 is executed by the microcomputer circuit 4c of each slave device. In the present embodiment, since the first to third slave devices 1b to 1d are installed, each process of the flowchart shown in FIG. 7 is performed by the first to third slave devices 1b to 1d, that is, the first slave device 1b to 1d. The second to fourth video display devices 1b to 1d are executed by the microcomputer circuits 4c.

  In the processing of the flowchart shown in FIG. 7, the second to fourth video display devices 1b to 1d set in the first to third slave devices 1b to 1d are turned on, or the second to fourth video displays are performed. When the devices 1b to 1d are set as slave devices by receiving the slave instruction signal from the external control device 6, they are started, and the process proceeds to step b1.

  In step b1, each of the slave devices 1b to 1d determines whether or not the correction start command transmitted from the master device 1a in step a1 of FIG. 6 has been received. In step b1, each slave device 1b-1d shifts to step b2 if it is determined that a correction start command has been received, and waits until it is received if it is determined that it has not been received.

  In step b2, each of the slave devices 1b to 1d has a standard luminance which is a luminance value on the screen 2 when a predetermined control current value IREF, for example, 20A, is given to each of the R, G, B light sources 3aa, 3ab, 3ac. The value YREF is read from the memory circuit 4d. In the present embodiment, each of the slave devices 1b to 1d has a luminance value YRREFn when the control current value of the R light source 3aa is equal to a value IRn that is a specified control current value, and the control current value of the G light source 3ab. Reads out the luminance value YGREFn when the current value is equal to the specified control current value IREF and the brightness value YBREFn when the control current value of the B light source 3ac is equal to the specified control current value IREF.

  As described above, n indicates a number assigned to each video display device 1. A value with “2” as n means a value read by the first slave device 1b or a calculated value. The value with “3” as n means a value read by the second slave device 1c or a calculated value. The value with “4” as n means a value read by the third slave device 1d or a calculated value.

  In step b3, each of the slave devices 1b to 1d determines whether or not the luminance value transmission command transmitted from the master device 1a in step a3 of FIG. 6 has been received. In step b3, each of the slave devices 1b to 1d proceeds to step b4 when determining that the luminance value transmission command has been received, and receives when determining that the luminance value transmission command has not been received. Wait until.

  In step b4, each of the slave devices 1b to 1d transmits the standard luminance values YRREFn, YGREFn, and YBREFn (n = 2 to 4) read from the memory circuit 4d in step b2 to the master device 1a via the communication cable 7. To do.

  In step b5, each of the slave devices 1b to 1d determines whether or not the target luminance value transmitted from the master device 1a in step a6 in FIG. 6 has been received. In step b5, when each slave device 1b-1d determines that it has received the target luminance value, it proceeds to step b6, and when it determines that it has not received the target luminance value, it waits until it receives it. To do.

  In step b6, each of the slave devices 1b to 1d outputs the luminance sensor outputs corresponding to the target luminance values YRT, YGT, and YBT from the luminance-sensor output characteristics shown in FIGS. 3 to 5 stored in the memory circuit 4d. Values SRTn (n = 2 to 4), SGTn (n = 2 to 4), and SBTn (n = 2 to 4) are read as target luminance sensor output values.

  In step b7, each of the slave devices 1b to 1d changes the setting of the light source driver 3b while monitoring the output value of the luminance sensor 3f to increase or decrease the control current value applied to the light source 3a. Each of the slave devices 1b to 1d supplies the light source 3a when substantially equal to the target luminance sensor output values SRTn (n = 2 to 4), SGTn (n = 2 to 4), and SBTn (n = 2 to 4). The control current value that is the value of the current to be generated is determined as the optimum control current value IRTn (n = 2 to 4), IGTn (n = 2 to 4), IBTn (n = 2 to 4).

  Specifically, each of the slave devices 1b to 1d matches the target luminance sensor output values SRTn (n = 2 to 4), SGTn (n = 2 to 4), SBTn (n = 2 to 4), or The control current value when it is closest to the target luminance sensor output values SRTn (n = 2 to 4), SGTn (n = 2 to 4), SBTn (n = 2 to 4) is the optimum control current value IRTn (n = 2-4), IGTn (n = 2-4), and IBTn (n = 2-4).

  In step b8, the slave devices 1b to 1d use the optimum control current values IRTn (n = 2 to 4), IGTn (n = 2 to 4), and IBTn (n = 2 to 4) determined in step b7 as light source drivers. Set to 3b. As a result, the slave devices 1b to 1d have the control current values given to the light source 3a that are the optimum control current values IRTn (n = 2 to 4), IGTn (n = 2 to 4), IBTn ( Control is performed by the light source driver 3b so that n = 2 to 4). In this way, each of the slave devices 1b to 1d changes the control current value to be given to the light source 3a based on the target luminance sensor output value. After finishing the process of step b8, all the processing procedures are complete | finished.

  As described above, according to the multi-screen display device 10 of the present embodiment, any one of the plurality of video display devices 1 determines the target luminance value, and each of the plurality of video display devices 1 corresponds to the target luminance value. The light source driver 3b supplies the current of the optimum control current value to the light source 3a so that the output value of the luminance sensor 3f can be obtained. Accordingly, it is possible to obtain the multi-screen display device 10 that can easily suppress the luminance variation between the screens 2 of the plurality of video display devices 1 as compared with the related art. Therefore, the sense of unity of the multi-screen 20 in the multi-screen display device 10 can be improved.

  Further, according to the multi-screen display device of the present embodiment, the master device 1a, which is a video display device that determines the target brightness value, includes the standard brightness value of its own device and the video display devices 1b to 1d other than its own device. Of the standard luminance values, the lowest standard luminance value is determined as the target luminance value. As a result, the optimum control current value to be supplied to the light source 3a can be made as small as possible, so that variation in luminance between the screens 2 can be suppressed and power consumption can be reduced as described above.

  In the present embodiment, since the luminance value is adjusted by the control current value supplied to the light source 3a, the control current supplied to the light source 3a is compared with the case where the luminance value is adjusted by the image quality adjustment value in the video processing circuit 4b. The value of can be reduced. Therefore, power consumption can be reduced.

  In the present embodiment, as described above, the master device 1a determines the lowest standard luminance value as the target luminance value. Thus, it is not essential for the master device 1a to determine the lowest standard luminance value as the target luminance value in order to obtain the effect of suppressing variation in luminance. If a common luminance value that can be output by each of the video display devices 1a to 1d is determined as the target luminance value, an effect of suppressing variation in luminance can be obtained even with a determination method other than the above.

  In addition, since the output value of the luminance sensor 3f has a variation for each device, when the luminance adjustment is performed based only on the output value of the luminance sensor 3f, a strict adjustment cannot be performed. On the other hand, in the multi-screen display device 10 according to the present embodiment, the luminance-sensor output characteristic representing the relationship between the luminance value of the image on the screen 2 and the output value of the luminance sensor 3f is stored in the memory circuit 4d. Therefore, accurate brightness adjustment can be performed.

  In the present embodiment, the memory circuit 4d has a brightness-sensor output characteristic as shown in FIG. 3 or the like as a brightness-sensor output characteristic representing the relationship between the brightness value of the image on the screen 2 and the output value of the brightness sensor 3f. Stores output characteristics. The form of the luminance-sensor output characteristic stored in the memory circuit 4d may be a correspondence table between the luminance value of the image on the screen 2 and the output value of the luminance sensor 3f, or the luminance of the image on the screen 2. It may be a relational expression between the value and the output value of the luminance sensor 3f. In the case of the correspondence table between the luminance value of the image on the screen 2 and the output value of the luminance sensor 3f, an effect that the luminance value can be easily read can be obtained. In the case of the relational expression between the luminance value of the image on the screen 2 and the output value of the luminance sensor 3f, an effect that the storage capacity of the memory circuit 4d can be reduced can be obtained.

<Second Embodiment>
The multi-screen display device 10 according to the first embodiment is configured to be able to suppress variations in luminance among the plurality of projection type video display devices 1. However, when an LED is used as the light source 3a, the chromaticity value of the LED corresponding to the control current value, that is, the chromaticity characteristic of the LED varies from LED to LED due to manufacturing variations and the like. Further, since the multi-screen display device 10 of the first embodiment is not configured to determine the control current value in consideration of chromaticity, the multi-screen display device 10 of the first embodiment has a little chromaticity. May vary.

  Therefore, the multi-screen display device according to the second embodiment of the present invention has a configuration that can suppress not only variations in luminance but also variations in chromaticity. Hereinafter, the multi-screen display device of the present embodiment will be described. Since the multi-screen display device of the present embodiment has the same configuration as the multi-screen display device 10 of the first embodiment described above, the corresponding parts are denoted by the same reference numerals and are described in common. Is omitted.

  As in the first embodiment, the microcomputer circuit 4c can perform processing for writing various control data to the memory circuit 4d and processing for reading the various control data from the memory circuit 4d. In the present embodiment, the various control data include not only the luminance-sensor output characteristics shown in FIGS. 3 to 5 but also chromaticity values corresponding to the control current values of the R, G, and B light sources 3a. It further includes chromaticity characteristics to be represented, and image quality adjustment values of R, G, and B luminance values and chromaticity values in the video processing circuit 4b, that is, the correction coefficient shown in the equation (1).

  In the present embodiment, the correction coefficient shown in the equation (1) is calculated in the microcomputer circuit 4c. The video processing circuit 4b uses the correction coefficient calculated by the microcomputer circuit 4c in the equation (1). The video processing circuit 4b converts the digital video signal after the image quality adjustment processing into a digital signal format required by the video display device 3d of the projection unit 3 and supplies the digital signal format to the video display device 3d.

  FIG. 8 is a graph showing the relationship between the control current value and the chromaticity value. The coordinate system shown in FIG. 8 corresponds to the xy coordinate system of the CIE color system. The y axis of the vertical axis shown in FIG. 8 represents luminance. FIG. 8 shows chromaticity characteristics representing chromaticity values corresponding to the control current values of the R, G, and B light sources 3a. In the present embodiment, the chromaticity characteristics shown in FIG. 8 are stored in advance in the memory circuit 4d. The memory circuit 4d stores the chromaticity characteristics when the memory circuit 4d corresponds to the control current value that is the value of the current supplied to each of the R, G, and B light sources 3a. This corresponds to storing a value.

  8, “IRT” indicates the optimal control current value of the R light source 3aa, “IRmin.” Indicates the minimum value of the control current value of the R light source 3aa, and “IRmax.” Indicates the control of the R light source 3aa. Indicates the maximum current value. Here, it is assumed that the chromaticity coordinate x of the chromaticity value when the optimum control current value is given to the R light source 3aa is xR0, and the chromaticity coordinate y is yR0.

  8, “IGT” indicates the optimum control current value of the G light source 3ab, “IGmin.” Indicates the minimum value of the control current value of the G light source 3ab, and “IGmax.” Indicates the G light source 3ab. Indicates the maximum control current value. Here, it is assumed that the chromaticity coordinate x of the chromaticity value when the optimum control current value is given to the G light source 3ab is xG0, and the chromaticity coordinate y is yG0.

  8, “IBT” indicates the optimum control current value of the B light source 3ac, “IBmin.” Indicates the minimum value of the control current value of the B light source 3ac, and “IBmax.” Indicates the B light source 3ac. Indicates the maximum control current value. Here, it is assumed that the chromaticity coordinate x of the chromaticity value when the optimum control current value is given to the B light source 3ac is xB0, and the chromaticity coordinate y is yB0.

  FIG. 9 is a flowchart showing a processing procedure of the microcomputer circuit 4c relating to luminance and chromaticity correction processing in the master device 1a of the multi-screen display device according to the second embodiment of the present invention. FIG. 10 is a chromaticity diagram used when the master device 1a determines the target chromaticity value in step c13 of FIG. FIG. 11 is a flowchart showing a processing procedure of the microcomputer circuit 4c regarding luminance and chromaticity correction processing in the first to third slave devices 1b to 1d of the multi-screen display device according to the second embodiment of the present invention. .

  As a premise of the processing of the flowcharts shown in FIGS. 9 and 11, the control current value supplied to the light source 3a is gradually changed for each of R, G, and B before each video display device 1 is shipped from the factory. It is assumed that the luminance value of the video on the screen 2, that is, the luminance characteristic, and the sensor output value and chromaticity value, that is, the chromaticity characteristic corresponding to the luminance sensor 3f are obtained and stored in the memory circuit 4d. That is, the memory circuit 4d of each video display device 1 corresponds to the control current values of the three primary colors of the light source 3a as shown in FIG. 8 in addition to the luminance-sensor output characteristics shown in FIGS. It is assumed that chromaticity characteristics representing chromaticity values are stored. In the following description, the chromaticity characteristic representing the chromaticity value corresponding to the control current value shown in FIG. 8 may be referred to as “current-chromaticity characteristic”.

  Each process of the flowchart shown in FIG. 9 is executed by the microcomputer circuit 4c of the master device 1a. The processing of the flowchart shown in FIG. 9 is performed when the video display device 1a set as the master device is turned on or when the video display device 1a receives a master instruction signal from the external control device 6, It starts when it is set, and proceeds to step c1.

  Since each process of step c1 to step c9 is the same as each process of step a1 to step a9 of the flowchart shown in FIG. 6, description of the process is omitted. After finishing the process of step c9, it transfers to step c10.

  In step c10, the master device 1a determines the chromaticity value corresponding to the optimum control current value IRTn (n = 1) of the R light source 3aa determined in step c8 from the current-chromaticity characteristics stored in the memory circuit 4d. Read xR0n, yR0n (n = 1). Similarly, the master device 1a determines the chromaticity values xG0n and yG0n (n = 1) corresponding to the optimum control current value IGTn (n = 1) of the G light source 3ab determined in step c8, and is determined in step c8. The chromaticity values xB0n and yB0n (n = 1) corresponding to the optimum control current value IBTn (n = 1) of the B light source 3ac are read.

  In step c11, the master device 1a causes the slave devices 1b to 1d to transmit the chromaticity values xR0n, yR0n, xG0n, yG0n, xB0n, and yB0n (n = 2 to 4) read from the memory circuit 4d (hereinafter, n = 2 to 4). "Chromaticity value transmission command") is transmitted via the communication cable 7.

  In step c12, the master device 1a determines whether or not the chromaticity value transmitted from each of the slave devices 1b to 1d has been received. In step c12, when determining that the chromaticity value has been received, the master device 1a proceeds to step c13. When determining that the chromaticity value has not been received, the master device 1a waits until it is received.

  In step c13, the master device 1a determines the chromaticity value corresponding to the optimum control current value IRTn, IGTn, IBTn (n = 1) of the device read from the memory circuit 4d in step c10, and the communication cable in step c12. Multi-screen display of this embodiment based on the chromaticity values corresponding to the optimum control current values IRTn, IGTn, IBTn (n = 2 to 4) of the slave devices 1b to 1d received via Determine a common target chromaticity value that the device can reproduce. In this way, the master device 1a determines a target chromaticity value that is a common target for the plurality of video display devices 1 constituting the multi-screen display device 10 for each color.

  As described above, FIG. 10 is a chromaticity diagram used when the master device 1a determines the target chromaticity value in step c13 of FIG. In FIG. 10, four triangles indicated by a solid line, a broken line, a one-dot chain line, and a two-dot chain line correspond to four of the master device 1a and the first to third slave devices 1b to 1d. Each vertex of the triangle indicated by each line type has chromaticity values xR0n and yR0n (n = 1 to 4) of the R light source 3aa, chromaticity values xG0n and yG0n (n = 1 to 4) of the G light source 3ab, and B This corresponds to the chromaticity values xB0n and yB0n (n = 1 to 4) of the light source 3ac. In the present embodiment, the master device 1a, in FIG. 10, has three points in the region where the four triangles overlap and close to the vertices of the triangles, the target chromaticity values xRT, yRT, target chromaticity values xGT and yGT of the G light source 3ab, and target chromaticity values xBT and yBT of the B light source 3ac are determined.

  Returning to FIG. 9, in step c14, the master device 1a sends the target chromaticity values xRT, yRT, xGT, yGT, xBT, and yBT determined in step c13 to the slave devices 1b to 1d via the communication cable 7. Send.

  In step c15, the master device 1a calculates a correction coefficient for correcting the level of the video signal input to the own device based on the target chromaticity value determined in step c13. More specifically, the master device 1a first adds the target luminance values YRT, YGT, YBT determined in Step c5 and the chromaticity values xR0n, yR0n, xG0n determined in Step c5 to the following equation (2). , YG0n, xB0n, yB0n (n = 1), and X and Z values XR0n, ZR0n, XG0n, ZG0n, XB0n, ZB0n (n = 1) among the three stimulus values of R, G, B Is calculated.

  In addition, the master device 1a is determined in step c13 by the target luminance values YRT, YGT, YBT determined in step c5 in the following equation (3) which is substantially the same as the equation (2). By substituting the target chromaticity values xRT, yRT, xGT, yGT, xBT, and yBT, X and Z target values XRT, ZRT, XGT, ZGT, among the three stimulus values of R, G, and B, XBT and ZBT are calculated.

  Here, the tristimulus values Xn, Yn, Zn (n = 1) for the input video signals Ri, Gi, Bi of the video display device 1 are expressed by the following equation (4). From the formula (4) and the formula (1), the following formula (5) is obtained. In Expression (5), RRn, RGn, RBn, GRn, GGn, GBn, BRn, BGn, and BBn indicate correction coefficients.

  The master device 1a adds the X and Z values XR0n of the target luminance values YRT, YGT, YBT determined in step c5 and the previously calculated tristimulus values of R, G, B to the equation (5). , ZR0n, XG0n, ZG0n, XB0n, ZB0n (n = 1) and the X, Z target values XRT, ZRT, XGT, ZGT, XBT of the previously calculated tristimulus values of R, G, B , ZBT are substituted. Then, the master device 1a calculates correction coefficients RRn, RGn, RBn, GRn, GGn, GBn, BRn, BGn, BBn (n = 1) from the equation obtained by substitution. In this manner, the master device 1a calculates a correction coefficient for correcting the level of the video signal input to the own device based on the above-described target chromaticity value.

  In step c16, the master device 1a sets so that the correction coefficient calculated in step c15 is used in the video processing circuit 4b. Accordingly, the master device 1a corrects the level of the video signal input to the own device based on the target chromaticity value. After the process of step c16 is complete | finished, all the process procedures are complete | finished.

  In parallel with the processing of the flowchart shown in FIG. 9 by the master device 1a described above, the processing of the flowchart shown in FIG. 11 is performed in the slave device. Each process of the flowchart shown in FIG. 11 is executed by the microcomputer circuit 4c of the slave device. When a plurality of slave devices are installed, each process of the flowchart shown in FIG. 11 is executed by the microcomputer circuit 4c of each slave device. In the present embodiment, since the three slave devices of the first to third slave devices are installed, each process of the flowchart shown in FIG. 11 is performed by the first to third slave devices 1b to 1d, that is, the second to second slave devices. The four video display devices 1b to 1d are respectively executed by the microcomputer circuit 4c.

  In the process of the flowchart shown in FIG. 11, the second to fourth video display devices 1b to 1d set in the first to third slave devices 1b to 1d are turned on, or the second to fourth video displays are performed. When the devices 1b to 1d are set as slave devices by receiving the slave instruction signal from the external control device 6, they are started, and the process proceeds to step d1.

  Since each process of step d1-step d8 is the same as each process of step b1-step b8 of the flowchart shown in the above-mentioned FIG. 7, description of a process is abbreviate | omitted. After finishing the process of step d8, it transfers to step d9.

  In step d9, each of the slave devices 1b to 1d has the optimum control current value IRTn (n = 2 to 4) of the R light source 3aa determined in step d7 based on the current-chromaticity characteristics stored in the memory circuit 4d. Corresponding chromaticity values xR0n, yR0n (n = 2 to 4) are read. Similarly, each of the slave devices 1b to 1d has chromaticity values xG0n and yG0n (n = 2 to 4) corresponding to the optimum control current value IGTn (n = 2 to 4) of the G light source 3ab determined in step d7. The chromaticity values xB0n and yB0n (n = 2 to 4) corresponding to the optimum control current value IBTn (n = 2 to 4) of the B light source 3ac determined in step d7 are read out.

  In step d10, each of the slave devices 1b to 1d determines whether or not the chromaticity value transmission command transmitted from the master device 1a in step c11 of FIG. 9 has been received. In step d10, if each slave device 1b-1d determines that it has received a chromaticity value transmission command, it proceeds to step d11, and if it determines that it has not received a chromaticity value transmission command, Wait for reception.

  In step d11, each of the slave devices 1b to 1d transmits the chromaticity value read in step d9 to the master device 1a via the communication cable 7.

  In step d12, each of the slave devices 1b to 1d determines whether or not the target chromaticity value transmitted from the master device 1a in step c14 of FIG. 9 has been received. In step d12, each slave device 1b to 1d proceeds to step d13 when it is determined that the target chromaticity value has been received, and waits until it is received when it is determined that it has not been received.

  In step d13, each of the slave devices 1b to 1d is input to its own device based on the target chromaticity value received in step d12 in the same manner as the processing of the master device 1a in step c15 shown in FIG. A correction coefficient for correcting the level of the video signal is calculated.

  Specifically, each of the slave devices 1b to 1d first adds the target luminance values YRT, YGT, YBT received at step d5 and the chromaticity values xR0n, yR0n, xG0n received at step d9 to the equation (2). , YG0n, xB0n, yB0n (n = 2 to 4) are substituted, and X and Z values XR0n, ZR0n, XG0n, ZG0n, XB0n, ZB0n (n = N = 3) of the three stimulus values of R, G, B 2-4) is calculated.

  Each slave device 1b to 1d receives the target luminance values YRT, YGT, YBT received in step d5 and the target luminance values YRT, YGT, YBT received in step d5 in the above equation (3) which is substantially the same as the equation (2). Substituting the target chromaticity values xRT, yRT, xGT, yGT, xBT, and yBT, X and Z target values XRT, ZRT, XGT, ZGT, and XBT among the three stimulus values of R, G, and B , ZBT is calculated.

  Next, each of the slave devices 1b to 1d adds the target luminance values YRT, YGT, and YBT received in step d5 and X of the R, G, and B tristimulus values calculated in advance to the equation (5). Z values XR0n, ZR0n, XG0n, ZG0n, XB0n, ZB0n (n = 2 to 4) and the X, Z target values XRT, ZRT among the previously calculated tristimulus values of R, G, B , XGT, ZGT, XBT, ZBT are substituted. Then, each of the slave devices 1b to 1d calculates correction coefficients RRn, RGn, RBn, GRn, GGn, GBn, BRn, BGn, and BBn (n = 2 to 4) from the equations obtained by substitution. In this way, each of the slave devices 1b to 1d calculates a correction coefficient for correcting the level of the video signal input to the own device based on the above-described target chromaticity value.

  In step d14, each of the slave devices 1b to 1d sets so that the correction coefficient calculated in step d13 is used in the video processing circuit 4b. Accordingly, each of the slave devices 1b to 1d corrects the level of the video signal input to the own device based on the target chromaticity value. After the process of step d14 is complete | finished, all the process procedures are complete | finished.

  According to the multi-screen display device of the present embodiment as described above, the operation similar to that of the multi-screen display device 10 of the first embodiment is performed, so that the screens 2 of the plurality of video display devices 1 are as described above. It is possible to suppress variations in luminance between the two. Further, according to the multi-screen display device of the present embodiment, any one of the plurality of video display devices 1 determines the target chromaticity value, and each of the plurality of video display devices 1 is based on the target chromaticity value. A correction coefficient for correcting the level of the video signal is calculated, and the level of the video signal is corrected by the correction coefficient. Therefore, variation in chromaticity between the screens 2 of the plurality of video display devices 1 can also be suppressed.

  Here, if both luminance adjustment and chromaticity correction are performed by only correcting the level of the video signal, the gradation expression level in each video display device 1 may be impaired. On the other hand, in this embodiment, the control current value is adjusted and suppressed for luminance variations, and the video signal level is corrected and suppressed for chromaticity variations. Based on this, it is possible to prevent the digital expression gradation of the video displayed on the screen 2 from being damaged. Therefore, it is particularly effective in displaying a video such as a natural image that uses many intermediate gradations.

  DESCRIPTION OF SYMBOLS 1 Projection type video display apparatus, 1a Master apparatus (1st video display apparatus), 1b 1st slave apparatus (2nd video display apparatus), 1c 2nd slave apparatus (3rd video display apparatus), 1d 3rd slave apparatus ( 4th image display device), 2 screen (screen), 2a 1st screen (1st screen), 2b 2nd screen (2nd screen), 2c 3rd screen (3rd screen), 2d 4th screen (4th) Screen), 3 projection unit, 3a light source, 3aa R light source, 3ab G light source, 3ac B light source, 3b light source driver, 3c light source composition device, 3d video display device, 3e projection lens, 3f luminance sensor, 3fa R luminance sensor, 3fb G luminance sensor, 3fc B luminance sensor, 4 electrical circuit unit, 4a video input circuit, 4b video processing circuit, 4c microcomputer Road, 4d memory circuit, 5 a video source, 6 an external control device, 7 a communication cable, 10 multi-screen display device, 20 a multi-screen.

Claims (4)

A multi-screen display device comprising a plurality of projection-type video display devices and displaying video on a multi-screen configured by combining the screens of the plurality of video display devices based on an input video signal,
The plurality of video display devices are communicably connected by a communication means,
Each video display device
Luminance detection means for outputting an output value corresponding to the luminance value of the image on the screen of the device;
A light source that outputs light of an intensity corresponding to a supplied current for image projection onto the screen;
Current control means for controlling a current supplied to the light source;
Storage means for storing the output value of the brightness detection means corresponding to the brightness value of the image on the screen;
Among the plurality of video display devices, any one of the video display devices includes a standard luminance value that is a luminance value of the video on the screen when a predetermined current is supplied to the light source of the device, and the communication Based on the standard luminance value of the video display device other than its own device obtained through the means, determine a target luminance value as a common target,
Each of the video display devices
(A) Read out the output value of the brightness detection unit of the device corresponding to the target brightness value from the storage unit of the device as a target brightness output value;
(B) When the output value of the luminance detection means of the own device becomes substantially equal to the target luminance output value, the value of the current supplied to the light source of the own device is determined as the optimum control current value,
(C) A multi-screen display device controlled by the current control means of the own device so that the value of the current supplied to the light source of the own device becomes the optimum control current value. The light source of each video display device includes a plurality of color light sources that output light corresponding to the three primary colors of light for video projection onto the screen,
The storage means of each video display device further stores the chromaticity value of each color light source corresponding to the value of the current supplied to each color light source,
Among the plurality of video display devices, any one of the video display devices is provided for each color by the chromaticity value corresponding to the optimum control current value in the light source of the device and the communication unit. Based on the chromaticity value corresponding to the optimal control current value in the light source of the image display device other than the device, a target chromaticity value to be a common target is determined,
2. The multi-screen display device according to claim 1, wherein each of the video display devices corrects the level of the video signal input to the device based on the target chromaticity value.   The video display device that determines the target luminance value uses the lowest standard luminance value as the target luminance value among the standard luminance value of the own device and the standard luminance value of the video display device other than the own device. The multi-screen display device according to claim 1, wherein the multi-screen display device is determined. The plurality of video display devices include
One video display device predetermined as a master device;
A remaining video display device excluding the master device, including the slave device controlled by the master device via the communication means;
The multi-screen display device according to claim 1, wherein the target luminance value is determined by the master device.

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