JP2001249652A - Multiscreen display device, display system and projector drive circuit used for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the image quality of a multiscreen display device by suppressing the color irregularity and luminance unevenness between unit screens by the change with lapse of time of the lamps and optical sections of respective unit projector sections with this multiscreen display device. SOLUTION: Either or both of the display device or illumination optical systems of the unit projectors are controlled in accordance with the reference luminance information common to the plural unit projectors, by which the luminance unevenness between the plural unit screens is suppressed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a multi-screen display device for providing one screen with a plurality of screens and a display system using a plurality of displays.
In a display device using a display device such as a Micromirror Device (registered trademark of Texas Instruments)), the image quality of the display screen is changed with respect to a luminance change and a color change due to a temporal change of a light source such as a lamp or an optical system component. Technology for compensation.

[0002]

2. Description of the Related Art Conventionally, as this type of display technology, for example, as described in JP-A-10-319926, when the brightness of the entire multi-screen becomes bright, the overall brightness is lowered, and When the brightness is reduced, the overall brightness is increased.
matic Brightness Limiter) control,
As described in Japanese Patent Application Laid-Open No. 1-305534, there is a method of raising and lowering the black level of an image signal according to the amplitude level of the image signal.

[0003]

However, in a multi-screen display technique using a display device such as a liquid crystal panel or a panel of a reflection type micromirror type, a light source component such as a lamp used for each display or an optical system. There is a variation in the change over time of the optical characteristics of the parts, and the influence tends to appear on the display screen. For example, as shown in FIG. 6, in general, each lamp of each unit projector corresponding to each unit screen of a multi-screen display device has considerably different luminance variation characteristics with time (varies). For this reason, the luminance varies between the unit screens as time passes. In addition, for each color, the luminance varies with time as shown in FIG.
As shown in FIG. 8, the chromaticity of the lamp itself changes. For this reason, the color of the display image (video) changes, and color unevenness occurs between the unit screens. Such a luminance difference and a color tone difference between unit screens appear as image quality deterioration of the entire multi-screen. In addition, variations in aging of optical components such as a polarizing plate and an ultraviolet filter may cause image quality deterioration. Conventional technology, for example, as described in the above-mentioned publication,
This technology simply changes the brightness and black level of the entire multi-screen to make the brightness difference and color tone difference between unit screens inconspicuous. It does not control to get rid of it. Further, in the related art, it is conceivable to perform separate brightness adjustment and color tone adjustment for each unit on a regular basis. However, in such a case, it takes time and effort for such adjustment, and it is economically burdensome. An object of the present invention is to improve the disadvantages of the prior art, suppress the color tone difference between unit screens due to the aging of the characteristics of light sources such as lamps and optical components and the like, the difference in luminance, etc., and improve the image quality of the entire screen. It is to provide a display technique capable of obtaining an image.

[0004]

In order to achieve the above object, the present invention provides: 1) a unit projector (one embodiment: reference numerals 13 and 13);
A to 13I) display device (one embodiment: reference numerals 3, 3)
r, 3g, 3b) in a multi-screen display device that forms a whole image by combining a plurality of unit images displayed on a unit screen (one example: reference numeral 1) using the emitted light from the display device or Either one or both of the illumination optical systems including a light source such as a lamp (an example: reference numeral 4) is controlled based on reference luminance information common to the plurality of unit projectors to reduce luminance unevenness between the plurality of unit screens. The configuration is such that it is suppressed.

2) The luminance information is compared among a plurality of unit projectors, and based on the comparison result, either one or both of a display device and an illumination optical system including a light source such as a lamp are controlled to control a plurality of unit screens. The configuration is such that luminance unevenness is suppressed.

3) First luminance information (one embodiment: reference numeral 101) obtained from a first unit projector (one embodiment: reference numeral 13) of the plurality of unit projectors;
A comparison circuit (1) that compares the second luminance information (one embodiment: reference numeral 102) obtained from the second unit projector and outputs third luminance information (one embodiment: reference numeral 103) as reference luminance information. One of an image signal (an embodiment: reference numeral 106) or a light amount of an illumination optical system including a light source such as a lamp (an embodiment: reference numeral 4) based on the third luminance information; Or a control circuit (one embodiment: reference numerals 7, 9, and 10) for controlling both of them.
Is used as common information among the plurality of unit projectors, and based on this information, uneven brightness between a plurality of unit screens is suppressed.

[0007] 4) A detection means (one embodiment: reference numeral 5) for detecting the luminance information of the unit projector and a detection means obtained from the first unit projector (one embodiment: reference numeral 13) of the plurality of unit projectors. The first luminance information (one example: reference numeral 101) obtained from the second unit projector is compared with the second luminance information (one example: reference numeral 102) obtained from the second unit projector.
A comparison circuit (an embodiment: reference numeral 103) that outputs luminance information (an embodiment: reference numeral 103), and a display image signal (an embodiment: reference numeral 103) based on the third luminance information and the first luminance information. 1
06) A circuit for calculating the output amplitude conversion gain (one embodiment:
Reference numeral 7), a conversion circuit for converting the amplitude of the image signal according to the obtained gain (an embodiment: reference numeral 9), and a drive circuit for driving a display device based on the amplitude-converted image signal (an embodiment: Reference numeral 10), wherein the third luminance information is used as common information among the plurality of unit projectors, and based on the third luminance information, the display device is controlled to suppress luminance unevenness between the plurality of unit screens. I do.

[0008] 5) The first luminance information of the red, green, and blue light obtained from the first unit projector among the plurality of unit projectors is compared with each of the predetermined luminance information of the red, green, and blue light. A comparison circuit for outputting the third luminance information of the reference luminance information based on the luminance information of the color having the largest luminance level difference and the second luminance information of the second unit projector, and A control circuit for controlling one or both of the amounts of light of an illumination optical system including a light source such as an image signal or a lamp (reference numeral 4), and transmitting the third luminance information to the plurality of unit projectors. Based on this common information, the configuration is such that the luminance unevenness of each of the red, green, and blue lights between a plurality of unit screens is suppressed.

[0009] 6) A reference based on first luminance information of red, green and blue light obtained from a first unit projector among a plurality of unit projectors and second luminance information obtained from a second unit projector. A circuit for outputting third luminance information as luminance information, and an image signal or a lamp based on the third luminance information (one embodiment: reference numeral 4)
A control circuit for controlling one or both of the amounts of light of the illumination optical system including the equal light sources, wherein the third luminance information is common information among the plurality of unit projectors, and a plurality of unit screens are formed based on the common information. The configuration is such that the luminance unevenness of each of the red, green, and blue lights between them is suppressed.

7) a circuit for outputting, as reference luminance information, luminance information that is common to a plurality of unit projectors and that has a maximum difference from a preset luminance level;
A circuit that controls one or both of a display device or an illumination optical system including a light source such as a lamp in the plurality of unit projectors based on the reference brightness information so as to suppress uneven brightness between the plurality of unit screens; The configuration is provided with.

8) A personal computer is connected to the multi-screen display device of the above 1) to 7),
An image signal from the personal computer is input to the multi-screen display device to enable image display.

9) A projector driving circuit for a multi-screen display device for irradiating a display device with light from an illumination optical system including a light source such as a lamp on a unit projector and combining a plurality of unit images displayed on a unit screen to form an entire image. , The third luminance information as reference luminance information based on the first luminance information obtained from the first unit projector of the plurality of unit projectors and the second luminance information obtained from the second unit projector And a control circuit for controlling one or both of the image signal and the light amount of the illumination optical system based on the third luminance information, and outputting the third luminance information to the plurality of light sources. The information should be shared between unit projectors, and should be controlled so as to suppress uneven brightness between multiple unit screens. A configuration to drive the Kuta.

[0013]

FIG. 1 shows a first embodiment of the present invention. In this embodiment, the luminance level of light from an illumination optical system such as a lamp is detected by a sensor, and the driving state of a display device such as a liquid crystal panel or a reflective micromirror panel is changed by changing the amplitude gain of an image signal based on the detection signal. It is intended to be controlled. In the drawing, reference numeral 13 denotes one of a plurality of unit projectors for forming a multi-screen display device, and includes an optical device 11 and a signal processing device 12 therein. The optical device 11 includes a lamp 4, a condenser lens (not shown), a display device 3, a projection lens 2, and the like. The light source such as the lamp 4 and the condenser lens form an illumination optical system for irradiating the display device 3 with light. Reference numeral 1 denotes a unit screen on which light from the display device 3 is projected by the projection lens 2 to display a unit image, and 5 denotes a luminance sensor for detecting the luminance of the lamp 4. The signal processing device 12 also includes a comparison circuit 6 for comparing the luminance information 101 obtained from the luminance sensor 5 with the luminance information 102 from an external unit projector such as an adjacent unit projector. The arithmetic circuit 7 for forming information for converting the output amplitude level of the display image signal 106 based on the information 103; the image processing unit 8 for performing processing such as enlargement or reduction of the input image signal 105 or scan conversion; Control signal 10 obtained from
4, a gain conversion circuit 9 for changing the amplitude and the like of the display image signal 106, and a drive circuit 10 for driving the display device.

FIG. 5 shows a connection example between a plurality of unit projectors. Each of the unit projectors 13A to 13I is capable of mutually exchanging (exchanging) the luminance information output from the comparison circuit 6 between the unit projectors. That is, the luminance information is transmitted and received between the plurality of unit projectors 13A to 13I in a closed loop state, and the reference luminance information is obtained. This connection example
It is a configuration example of a multi-screen multi-screen display device including nine unit screen surfaces (consisting of a configuration using nine unit projectors 13A to 13I and nine unit screens).

The operation of the first embodiment will be described below. First, the input image signal 105 is input to the input 1 of the input terminal. The input image signal 105 is subjected to frequency conversion, scaling processing, and the like by the image processing unit 8, and the display image signal 10
6 is converted. The output signal 106 is input to the amplitude gain conversion circuit. On the other hand, luminance information 101 obtained from the luminance sensor 5 of the optical device 11 is input to the comparison circuit 6. The brightness sensor 5 directly detects the brightness of the lamp 4. The comparison circuit 6 includes external luminance information (information from another connected unit projector) (second luminance information) 102 and internal luminance information (first luminance information) 10.
Then, the information of the lower luminance is output to another connected unit projector as luminance information (luminance information for transfer between unit projectors) 109. The same comparison / output operation as described above is performed in the comparison circuit 6 in the another unit projector. This operation is performed sequentially for all unit projectors in a closed loop,
Luminance information (luminance information for transfer between unit projectors) 109 output from the comparison circuit of each unit projector
Is equal in all unit projectors, that is, when the lowest luminance level of the lamp 4 used is determined, the luminance information 103 (third luminance information) from the comparison circuit at that time (the unit of the lowest luminance level) The arithmetic circuit 7 determines the amplitude gain value of the display image signal 106 based on the inter-projector transfer luminance information 109). Assuming that the luminance information 101 of the lamp 4 is X and the minimum luminance level value obtained by the comparison circuit 6 is Y, the arithmetic circuit 7 determines a gain value so as to multiply the amplitude of the display image signal 106 by Y / X. However, there is a case where the luminance that can be displayed on a display device such as a liquid crystal panel does not match the amplitude level of the image signal. In this case, the gain value may be determined using the luminance information corrected in advance. The gain-adjusted display image signal 107 is input to the drive circuit 10, and the drive circuit 10 drives the display device 3 so that the luminance levels of the unit screens become equal. The reference luminance information common to all the unit screens obtained by exchanging information between the unit screens (the same as the third luminance information 103) is luminance information obtained based on a difference or a ratio with respect to the luminance information at the time of the initial adjustment. For example, the ratio X / Z of the detected lamp luminance information X to the initial luminance information Z stored in the memory unit of the comparison circuit 6 may be the minimum.

As described above, by correcting the amplitude of the display image signal in accordance with the luminance level of the lamp in the unit projector which changes with time, the luminance level of the entire multi-screen can be changed, for example, to 101 'shown in FIG. The brightness level can be unified, and an image with less unevenness can be maintained.

FIG. 2 shows a second embodiment of the present invention. In the second embodiment, the brightness sensor 5 is disposed on the lamp 4 via an optical component 14 such as a condenser lens or a polarizing plate (both not shown) so as to detect the brightness of the portion. This is a configuration example. The configuration of the other parts is almost the same as that of the first embodiment. That is, the comparison circuit 6 compares the external luminance information (second luminance information) 102 with the internal luminance information (first luminance information) 101, and outputs the lower luminance information to the luminance information (transfer between unit projectors). (Luminance information) 109 is output to another unit projector side. The comparison circuit 6 performs the above-described comparison and output operations in another connected unit projector.
This operation is sequentially performed for all unit projectors in a closed loop, and each comparison circuit 6 in each unit projector is used.
When the luminance information (luminance information for transfer between unit projectors) 109 output from the projector becomes equal in all the unit projectors, that is, when the minimum luminance level of the lamp 4 used is determined, the comparison circuit Luminance information 103 (third luminance information) (same as luminance information 109 for transfer between unit projectors at the lowest luminance level)
The arithmetic circuit 7 determines the amplitude gain value of the display image signal 106 based on When the luminance information 101 of the lamp 4 is X and the minimum luminance level value obtained by the comparison circuit 6 is Y, the arithmetic circuit 7 determines a gain value so that the amplitude of the display image signal 106 is multiplied by Y / X. In the case of a display device whose displayable luminance does not match the amplitude level of the image signal, the gain value is determined using the luminance information corrected in advance. The display image signal 107 whose gain has been adjusted is supplied to the driving circuit 1.
0, the display device 3 is driven by the drive circuit 10 so that the brightness levels of the images on the unit screens are equalized. Reference luminance information common to all the unit screens obtained by exchanging information between unit screens (third luminance information 1 also in the second embodiment)
03) may be luminance information obtained based on a difference or a ratio with respect to the luminance information or the like at the time of the initial adjustment, similarly to the case of the first embodiment. Further, in the configuration of the second embodiment, since the luminance sensor 5 can detect the luminance level including the temporal change of the optical component 14 such as the polarizing plate, the accuracy is higher than that of the first embodiment. Brightness unevenness can be suppressed.

FIG. 9 is a diagram for explaining the brightness control operation of the display image in the first and second embodiments. In the first and second embodiments, as shown in FIG. 9, a lamp failure can be determined by detecting the brightness of the lamp. For example, the comparison circuit 6 determines when the comparative luminance information (at least one of the first luminance information and the second luminance information) in the unit projector is abnormal, and determines the third luminance information as normal comparison result information. It does not output luminance information. In this case, the entire screen of the multi-screen is prevented from being extremely darkened by a lamp failure. According to the configuration as in the first and second embodiments, even when the luminance level varies between the unit screens as shown in FIG. , The luminance difference between the unit screens can be almost eliminated.

FIG. 3 shows a third embodiment of the present invention. In the figure, reference numeral 13 denotes a unit projector. The unit projector 13 includes an optical device 11 and a signal processing device 12. The optical device 11 is a so-called three-plate type configuration example in which a display device such as a liquid crystal panel is provided for each of the three primary colors of red, green, and blue, and 1 is a screen, 2 is a lens, 3r, 3g, and 3b are Display devices for red, green, and blue light, 4 is a lamp, 15A is a dichroic mirror that transmits blue light, 15B is a dichroic mirror that transmits red light, 14A, 14B, and 14C are mirrors, 16r and 1r.
Reference numerals 6g and 16b denote optical components such as polarizing plates that polarize the split light, 5r, 5g and 5b denote luminance sensors for detecting the luminance of the lamp, and 6 denotes luminance information 101r obtained from the luminance sensors 5r, 5g and 5b. , 101g, 101b and the external luminance information 102, 7 is an arithmetic circuit for determining a gain value for converting the amplitude level of the display image signal 106 based on the information 103 obtained from the comparison circuit 6, and 9 is the arithmetic circuit 7, an amplitude level conversion circuit for changing the image amplitude by the control signal 104 obtained from 7, an image processing unit 8 for processing the input image signal 105 by enlargement / reduction, scan conversion, etc., 10 for driving the display devices 3r, 3g, 3b 14A, 14B and 14C are mirrors for reflecting light, and 15A and 15B are dichroic mirrors for reflecting light in a specific wavelength range. Chromatography, 16r, 16g, 16b is an optical filter such as a polarizing plate, 17 is a prism for combining images of each primary color light.

The operation of the third embodiment will be described below. Also in the third embodiment, similarly to the first and second embodiments, the image processing unit 8 converts the input image signal 105 into the output signal format 106 and inputs the output signal format 106 to the amplitude gain conversion circuit 9. . On the other hand, in the optical portion 11 of the unit projector, the light emitted from the lamp 4 is separated (spectralized) by 15A into blue light and is separated (spectralized) by 15B from red light and green light. Further, these split lights enter the display devices 3r, 3g, and 3b, respectively, and the light passing through the devices is combined by the prism 17 to display an image. Here, the luminance information 101r, 101g, and 101b are obtained by detecting the luminance from the respective light incident on the display devices 3r, 3g, and 3b by the luminance sensors 5r, 5g, and 5b.
This is input to the comparison circuit 6. The comparison circuit 6 stores the luminance information of the red, green, and blue lights in the initial adjustment state, and detects the detected luminance information 101r, 101g, and 101b of red, green, and blue.
Out of the initial state. The comparison circuit 6 compares the lowest level luminance information m with the external luminance information 102 and outputs the lower level luminance information as the external luminance information 109. The output external luminance information 109 is transmitted between the unit sections in a state where a plurality of unit sections (unit projectors) are connected in a chain as described in the first and second embodiments. Is done. When all the values of the luminance information 109 become the same value, the minimum value M of the luminance information is determined. The arithmetic circuit 7 determines the amplitude gain of the display image signal 106 based on the minimum value M of the luminance information and the luminance information Cr, Cg, Cb of the red, green, and blue light incident on the display devices 3r, 3g, 3b. . For example, assuming that the luminance characteristics of the display device change linearly, the amplitude gains of the signals corresponding to red, green, and blue are M / Cr times, M / Cg times, and M / C times.
b times. If the luminance characteristic of the display device changes nonlinearly, the amplitude gain is a value obtained by correcting the value.

As described above, based on the set value of the arithmetic circuit 7,
The amplitude of the display image signal 106 is individually converted by the amplitude gain conversion circuit 9 into red, green, and blue to obtain an output image signal 107. As a result, the correction is performed as shown by 101 ″ in FIG. 7. As described above, the luminance information of each of red, green, and blue is monitored, and the luminance of all the screens is changed to the one with the largest luminance change between the unit screens. , It is possible to suppress a change in color tone and uneven brightness between screens.

Further, as for a method of obtaining the lowest level value of the multi-screen luminance information, a method in which the luminance becomes the lowest level at one place may be selected. In the third embodiment, the luminance is corrected for all the color signals based on the luminance information of the color whose luminance is at the lowest level. The level may be obtained, and the luminance may be corrected for each color. In this case, the color tone of the entire screen is different from the initial state, but uneven brightness and uneven color between unit screens are suppressed.

FIG. 10 shows a flowchart of control in the third embodiment. In the third embodiment, when each of the luminance levels of red, green, and blue light significantly changes, it can be recognized as a defect in the optical system. This allows the first,
As in the case of the second embodiment, it is possible to prevent the screen from becoming extremely dark.

FIG. 4 is a diagram showing another example of connection between unit projectors. In this configuration, each of the unit projectors 13A to 13I transmits the lamp luminance information 101 to a common comparison circuit 6 ', and the comparison circuit 6' processes the information collectively. The comparison circuit 6 '
Outputs the lowest-level luminance information M from the luminance information 101 output from each of the unit projectors 13A to 13I, and outputs the luminance information M to all the unit projectors 13A.
~ 13I. Each unit projector 13A ~
13I, the luminance information M and the value C of the luminance information 101 of the lamp obtained inside are, for example, the first, second, and third values described above.
Is input to the arithmetic circuit 7 as described in the embodiment. The arithmetic circuit 7 forms the amplitude conversion data (conversion gain) M / C times of the display image signal 106 or forms the conversion data (conversion gain) according to the characteristics of the display device 3. The gain conversion unit 9 performs amplitude conversion of the display image signal 106 based on the conversion data (conversion gain). Further, as shown in the third embodiment, the luminance information 101r, 101g, and 101b of the red, green, and blue lights are compared with the comparison circuit 6 '.
And the luminance information having the lowest luminance level or the luminance level having the largest decrease width may be output as the reference luminance information. In this way, according to the configuration in which the luminance information is concentrated at one place and compared there, the luminance information can be centrally managed, and
It is also possible to easily change the brightness control conditions for all screens. As described above, according to the configuration of each of the above-described embodiments, it is possible to achieve image display with reduced luminance unevenness and color unevenness on the multi-screen.

In each of the above embodiments, the display device is controlled based on the reference luminance information. In addition, the illumination optical system such as a lamp power supply, or both the display device and the illumination optical system such as a lamp power supply are controlled. You may do so. The detection of the luminance information may be performed on the emission side of the lens (projection lens) 2, or may be detected from a current or the like by a power supply unit of a light source such as a lamp. The image signal may be controlled by changing other parameters of the amplitude gain. Further, the reference luminance information is not limited to the lowest level or the minimum ratio level. Further, the comparison circuit is configured to convert first luminance information of red, green, and blue light obtained from a first unit projector among the plurality of unit projectors into a predetermined red, green, and blue light.
In comparison with the luminance information of green and blue light, the luminance information is output as third luminance information based on the luminance information of the color with the smallest luminance level difference and the second luminance information of the second unit projector. Alternatively, luminance information that is common to a plurality of unit projectors and that has a maximum difference from a preset luminance level may be output as reference luminance information. Further, a display system configuration in which a personal computer is connected to the multi-screen display device of each configuration described above, and an image signal from the personal computer is input to the multi-screen display device to enable display, is also within the scope of the embodiment of the present invention. is there. Furthermore, the present invention includes, in its scope, all inventions having technical ideas or constituent requirements substantially in the same range as the above-mentioned respective constitutions.

[0026]

According to the present invention, it is possible to display an image in which uneven brightness or uneven color between unit screens due to a temporal change of a lamp, an optical system component or the like is suppressed.

[Brief description of the drawings]

FIG. 1 is a diagram showing a first embodiment of the present invention.

FIG. 2 is a diagram showing a second embodiment of the present invention.

FIG. 3 is a diagram showing a third embodiment of the present invention.

FIG. 4 is a diagram illustrating a connection example between unit projectors.

FIG. 5 is a diagram illustrating a connection example between unit projectors.

FIG. 6 is a diagram illustrating an example of a temporal change in luminance of a lamp of a unit screen.

FIG. 7 is a diagram showing an example of a temporal change in luminance of each color in a lamp of a unit screen.

FIG. 8 is a diagram showing an example of a change in chromaticity due to a change over time of a lamp.

FIG. 9 is a diagram showing an operation flowchart in the first and second embodiments.

FIG. 10 is a diagram showing an operation flowchart in the third embodiment.

[Explanation of symbols]

1. Unit screen, 2. Projection lens, 3, 3
r, 3g, 3b: display device, 4: lamp, 5: brightness sensor, 6, 6 ': comparison circuit, 7: arithmetic circuit, 8:
Image processing unit, 9: gain conversion unit, 10: drive circuit,
11: Optical device, 12: Signal processing device, 13, 13A
~ 13I unit projector, 14 ... optical parts,
14A, 14B, 14C: mirror, 15A, 15B: dichroic mirror, 16r: optical component for red light, 1
6g: Optical component for green light, 16b: Optical component for blue light, 17: Prism, 101: First luminance information, 101
A, 101B, 101C: brightness information of lamps for each unit screen; 101r, 101g, 101b: brightness information by lamp color; 102: second brightness information;
... third luminance information, 104 ... gain control signal, 105
... input image signal, 106 ... display image signal, 107 ... gain-adjusted display image signal, 108 ... display device drive signal, 109 ... luminance information for transfer between unit projectors.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09F 9/00 360 H04N 5/74 D 5C082 H04N 5/74 9/31 A 5G435 9/31 G02F 1/1335 530 (72) Inventor Takayuki Yamaguchi 292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa Prefecture Inside the Digital Media Systems Division of Hitachi, Ltd. (72) Inventor Kiyoshi Yamamoto 292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa Hitachi, Ltd. F-term in the Digital Media System Division of the Works (Reference) BA23 BA35 BB25 EA03 EA26 5C060 BA04 BC05 DA04 EA01 GB02 HB16 JA19 JB06 5 C082 AA03 AA21 AA34 BA02 BA12 BA34 BD00 BD07 CA11 CA81 CB03 MM10 5G435 AA00 BB06 BB12 FF02 GG03 GG04 GG08 GG11 GG23 GG46

Claims (13)

[Claims] 1. A multi-screen display apparatus for forming a whole image by combining a plurality of unit images displayed on a unit screen by using light emitted from a display device of a unit projector, wherein the display device or the illumination optical system in the unit projector is provided. A multi-screen display device, wherein one or both of them are controlled based on reference luminance information common to the plurality of unit projectors so as to suppress luminance unevenness between the plurality of unit screens. 2. A multi-screen display device for forming a whole image by combining a plurality of unit images displayed on a unit screen by using light emitted from a display device of a unit projector, and comparing light luminance information among the plurality of unit projectors. A multi-screen display device wherein one or both of the display device and the illumination optical system are controlled based on the comparison result to suppress luminance unevenness among a plurality of unit screens. 3. A multi-screen display device for irradiating a display device with light from an illumination optical system side in a unit projector to form a whole image by combining a plurality of unit images displayed on a unit screen. A comparing circuit that compares first luminance information obtained from the first unit projector with second luminance information obtained from the second unit projector and outputs third luminance information as reference luminance information; And a control circuit for controlling one or both of the image signal and the light amount of the illumination optical system based on the luminance information of the above, wherein the third luminance information is set as common information among the plurality of unit projectors, and Multi-screen characterized by suppressing uneven brightness between a plurality of unit screens Display device. 4. A multi-screen display device for irradiating a display device with light from an illumination optical system side in a unit projector and combining a plurality of unit images displayed on a unit screen to form an entire image, wherein the luminance information of the unit projector is obtained. Detecting means for detecting; comparing first luminance information obtained from the first unit projector among the plurality of unit projectors by the detecting means with second luminance information obtained from the second unit projector; A comparison circuit that outputs third luminance information as information; a circuit that calculates an output amplitude conversion gain of an image signal based on the third luminance information and the first luminance information; A conversion circuit for converting the amplitude, and a drive for driving the display device based on the image signal having the converted amplitude. And a circuit, wherein the third luminance information is set as common information among the plurality of unit projectors, and the display device is controlled based on the third luminance information to suppress luminance unevenness between the plurality of unit screens. Multi-screen display device. 5. The multi-screen display device according to claim 3, wherein the comparison circuit is configured to output lowest-level luminance information from the plurality of unit projectors as the third luminance information. 6. A configuration in which comparison result information of the first and second luminance information is transmitted and received between a plurality of unit projectors in a closed loop state, and the third luminance information is obtained as reference luminance information of the entire screen. Item 6. A multi-screen display device according to any one of Items 3 to 5. 7. The multi-screen display device according to claim 3, wherein the comparison circuit has a configuration capable of storing the third luminance information. 8. A multi-screen display device which irradiates light from an illumination optical system side in a unit projector to display devices for red, green and blue light and combines a plurality of unit images displayed on a unit screen to form an entire image. In the plurality of unit projectors, the first luminance information of the red, green, and blue light obtained from the first unit projector is compared with each of the predetermined luminance information of the red, green, and blue light, and the luminance level is calculated. A comparing circuit that outputs the third luminance information of the reference luminance information based on the luminance information of the color having the largest difference and the second luminance information of the second unit projector; A control circuit for controlling one or both of the light amounts of the illumination optical system, wherein the third luminance information is stored in the plurality of unit programs. A multi-screen display device characterized in that, based on the common information among the projectors, the luminance unevenness of each of red, green and blue light among a plurality of unit screens is suppressed based on the common information. 9. A multi-screen display device for irradiating light from a light source side to display devices for red, green, and blue light in a unit projector and combining a plurality of unit images displayed on a unit screen to form an entire image, Based on first luminance information of red, green, and blue light obtained from the first unit projector among the plurality of unit projectors, and second luminance information obtained from the second unit projector, a second luminance as reference luminance information is obtained. And a control circuit for controlling one or both of the image signal and the light amount of the illumination optical system based on the third luminance information, and the third luminance information Is used as the common information among the plurality of unit projectors, and based on this, the luminance of each of the red, green, and blue light A multi-screen display device characterized by suppressing unevenness. 10. The comparing circuit according to claim 3, wherein said comparing circuit determines that said first or second luminance information is abnormal and does not output said third luminance information. Multi-screen display device. 11. A multi-screen display apparatus for forming a whole image by combining a plurality of unit images displayed on a unit screen by using light emitted from a display device of the unit projector, wherein the multi-screen display device has brightness information common to the plurality of unit projectors. A circuit that outputs, as reference luminance information, luminance information having a maximum difference from a preset luminance level, and one of the display device or the illumination optical system in the plurality of unit projectors based on the reference luminance information, or A circuit for controlling both of them so as to suppress uneven brightness between a plurality of unit screens. 12. A multi-screen display device according to claim 1, wherein a personal computer is connected to the multi-screen display device, and an image signal from the personal computer is input to the multi-screen display device to enable display. A display system characterized by the following. 13. A projector driving circuit for a multi-screen display device, wherein a unit projector irradiates light from an illumination optical system side to a display device and forms a whole image by combining a plurality of unit images displayed on a unit screen. A comparison circuit that outputs third luminance information as reference luminance information based on first luminance information obtained from a first unit projector and second luminance information obtained from a second unit projector among the projectors; A control circuit for controlling one or both of the image signal and the light amount of the illumination optical system based on the third luminance information, wherein the third luminance information is shared between the plurality of unit projectors. The unit projector is used as information to reduce brightness unevenness between multiple unit screens. A projector driving circuit characterized by being driven.