JP2002333671A - Color reproducibility correction device for projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a color reproducibility correction device for a projector, which compensates the degradation in color reproducibility of the projector provided with a light control function for a light source to realize satisfactory color reproducibility. SOLUTION: A current detection part 21 and a temperature detection part 22 detect the driving current of a light source 2 and the temperature state of the light source 2 respectively. A microcomputer 10 uses tables and calculation formulas stored in a memory 11 to obtain driving conditions of a cooling part 15 and a display element 6 on the basis of the detection results. Since a change factor of emitted light wavelength characteristics of the light source 2 is detected to be able to drive the display element 6 in the optimum condition, the degradation in color reproducibility of a projected picture is compensated. The wavelength of illuminating light from the light source 2 and chromaticities of a lot of primary color light obtained by resolving illuminating light of the light source 2 are detected and are used to correct the driving condition of the display element 6, and thus reproducibility of the projected picture is improved furthermore.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for correcting color reproducibility of a projector, and more particularly, to a device for correcting color reproducibility that occurs when dimming a light source of a projector, thereby achieving good color reproducibility. The present invention relates to a color reproducibility correction device for a projector that realizes reproducibility.

[0002]

2. Description of the Related Art A projector is a device which includes a light source and a display element, and obtains a projected image by modulating illumination light from the light source with the display element. In a conventional projector, the light source is driven by a constant current, and the brightness of the light source is constant. However, in recent years, projectors having a function of adjusting the brightness of the light source (hereinafter, referred to as a dimming function) have been put to practical use for the purpose of reducing power consumption and extending the life of the light source. In such a projector, it is also possible to adjust the brightness of the projected image according to the use environment. JP 2000
JP-A-131668 discloses a light source light control device for a liquid crystal projector that switches the power supplied to a light source by detecting the amount of light in the surroundings.

FIG. 4 is a block diagram showing the configuration of a conventional projector having a dimming function. 4, the display signal processing section 12, the display element 6r on the input video signal V _in, 6 g, a signal processing corresponding to the driving modulation characteristics of 6b subjected. The display element driving unit 13 includes the display signal processing unit 1
Display elements 6r, 6g, 6 using the signals output from
Drive b. Thereby, the display elements 6r, 6g, 6b
In is displayed an image corresponding to the video signal V _in.

On the other hand, the light source 2 emits light under the drive control of the light source driving unit 1. The illumination light from the light source 2 is condensed by a relay optical system 4 after being reflected by a reflecting mirror 3 and further decomposed into a plurality of primary color lights by a color separation optical system 5. Each primary color light is applied to the display element 6r, 6g, 6b, and when passing through the display element or reflected by the display element, the intensity is modulated according to the image displayed on the display element. Each of the intensity-modulated primary color lights is combined by the color combining optical system 7, passes through the projection lens 8, and is enlarged and displayed on the screen 9. At this time, since the temperature of the light source 2 becomes high, the light source 2 is cooled by the cooling unit 15. The microcomputer 10 controls the cooling unit 15 via the cooling drive unit 14.

[0005] The microcomputer 10 controls the light source driving unit 1 for dimming the light source 2. The light source driving unit 1 includes a microcomputer 10
The driving current of the light source 2 is changed in accordance with the control from (1). When the drive current of the light source 2 changes, the brightness of the light source 2 changes, and the brightness of the projected image on the screen 9 changes. At this time, the driving condition of the cooling unit 15 can be controlled in conjunction with the light control of the light source 2. For example, when the cooling unit 15 is configured by a fan, the microcomputer 10 performs control to reduce the number of rotations of the fan of the cooling unit 15 in conjunction with reducing the drive current of the light source 2 to reduce power consumption. And low noise can be realized.

[0006]

However, the conventional projector has a problem in that the light emission wavelength of the light source changes when the light source is dimmed, and accordingly, the color reproducibility of the projected image is deteriorated. Specifically, in the conventional projector, when the light source is dimmed, the projected image may be displayed with a yellow-green tint, or the skin color may be displayed faintly.

In recent years, an ultra-high pressure mercury lamp is often used as a light source for a projector. FIG. 5 is a diagram illustrating an example of emission wavelength characteristics of an ultra-high pressure mercury lamp. In an ultra-high pressure mercury lamp, when the driving state or the temperature state changes, the excitation state of the mercury or the pressure inside the lamp changes, and the emission wavelength characteristic changes. For example, in the graph shown in FIG. 5, the peak value of each primary color light and the relative intensity of light at each wavelength change. When the emission wavelength characteristic of the light source changes in this way, the spectral characteristics and chromaticity characteristics of each primary color light applied to each display element change, and in a projected image obtained by modulating and combining these primary color lights, Reproducibility deteriorates.

[0008] Even if the driving conditions of the cooling unit are controlled in conjunction with the dimming of the light source to solve this problem, the driving conditions and the temperature conditions of the light source are controlled to optimal values because the operating environments of the projectors are different from each other. Can not. Therefore, even if this method is used, the emission wavelength characteristic of the light source changes, and as a result, the color reproducibility of the projected image deteriorates.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a projector color reproducibility correction apparatus which compensates for deterioration of color reproducibility in a projector having a light source dimming function and realizes good color reproducibility. And

[0010]

Means for Solving the Problems and Effects of the Invention A first invention is a dimmable light source, display means for displaying image information and modulating illumination light from the light source, and displaying based on an input video signal. A color reproducibility correction apparatus applied to a projector comprising a display driving unit for driving the unit and a cooling unit for cooling the light source, wherein a current detection unit for detecting a driving state of the light source, and a temperature state of the light source. Temperature detecting means for detecting,
Control means for controlling the driving condition of the cooling means based on the current detection result by the current detection means and the temperature detection result by the temperature detection means.

[0011] According to the first aspect of the invention, in the projector having the dimming function of the light source, the driving state and the temperature state of the light source can be measured, and the cooling condition of the light source can be controlled.
Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image that occurs when the light source is adjusted, and to realize good color reproducibility.

In a second aspect based on the first aspect, the apparatus further comprises a wavelength detecting means for detecting an emission wavelength of the light source, and the control means includes a current detection result by the current detecting means, a temperature detection result by the temperature detecting means, The driving condition of the cooling means is controlled based on the wavelength detection result by the detection means.

According to the second aspect of the invention, based on the emission wavelength of the light source in addition to the driving state and the temperature state of the light source,
The cooling condition of the light source can be controlled. Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image generated when the light source is dimmed with high accuracy, and to realize more excellent color reproducibility.

According to a third aspect, in the first aspect, the apparatus further comprises chromaticity detecting means for detecting chromaticity of a plurality of primary color lights obtained by decomposing the illumination light from the light source, and The driving condition of the cooling unit is controlled based on the current detection result by the detection unit, the temperature detection result by the temperature detection unit, and the chromaticity detection result by the chromaticity detection unit.

According to the third aspect, the cooling condition of the light source can be controlled based on the chromaticity of the primary color light in addition to the driving state and the temperature state of the light source. Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image generated when the light source is dimmed with high accuracy, and to realize more excellent color reproducibility.

In a fourth aspect based on the first aspect, the apparatus further comprises timer means for measuring an elapsed time from when the light source is turned on, and the control means comprises a current detection result by the current detection means and a temperature detection by the temperature detection means. The driving condition of the cooling means is controlled based on the result and the elapsed time measured by the timer means.

According to the fourth aspect, the cooling condition of the light source can be controlled on the basis of the elapsed time since the light source was turned on, in addition to the driving state and the temperature state of the light source. Therefore, the application of the color reproducibility correction is prohibited until the projector is in a stable state, and when the light emission characteristics are unstable immediately after the light source is turned on, it is possible to prevent the color reproducibility from deteriorating due to erroneous correction. it can.

According to a fifth aspect of the present invention, a dimmable light source, display means for displaying image information and modulating illumination light from the light source, display driving means for driving the display means based on an input video signal, and a light source A color reproducibility correction device applied to a projector including a cooling unit for cooling the light source, a current detection unit for detecting a driving state of the light source, a temperature detection unit for detecting a temperature state of the light source, and a current detection unit Control means for controlling the driving conditions of the display means via the display drive means based on the current detection result by the temperature detection means and the temperature detection result by the temperature detection means.

According to the fifth aspect of the invention, in the projector having the function of dimming the light source, the driving condition and the temperature condition of the light source can be measured, and the driving condition of the display means can be controlled. Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image that occurs when the light source is adjusted, and to realize good color reproducibility.

In a sixth aspect based on the fifth aspect, the apparatus further comprises a wavelength detecting means for detecting an emission wavelength of the light source, wherein the control means comprises: a current detection result by the current detection means; a temperature detection result by the temperature detection means; The driving condition of the display means is controlled via the display driving means based on the wavelength detection result by the detection means.

According to the sixth aspect, in addition to the driving state and the temperature state of the light source, based on the emission wavelength of the light source,
The driving condition of the display means can be controlled. Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image generated when the light source is dimmed with high accuracy, and to realize more excellent color reproducibility.

A seventh invention according to the fifth invention, further comprising chromaticity detecting means for detecting the chromaticity of a plurality of primary color lights obtained by decomposing the illumination light from the light source, wherein the control means comprises: The driving condition of the display means is controlled via the display drive means based on the current detection result by the detection means, the temperature detection result by the temperature detection means, and the chromaticity detection result by the chromaticity detection means.

According to the seventh aspect, the driving condition of the display means can be controlled based on the chromaticity of the primary color light in addition to the driving state and the temperature state of the light source. Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image generated when the light source is dimmed with high accuracy, and to realize more excellent color reproducibility.

In an eighth aspect based on the fifth aspect, the apparatus further comprises timer means for measuring an elapsed time from when the light source is turned on, and the control means comprises a current detection result by the current detection means and a temperature detection by the temperature detection means. The driving condition of the display means is controlled via the display driving means based on the result and the elapsed time measured by the timer means.

According to the eighth aspect, the driving condition of the display means can be controlled based on the elapsed time from when the light source is turned on in addition to the driving state and the temperature state of the light source. Therefore, the application of color reproducibility correction is prohibited until the projector is in a stable state, and when the light emission characteristics are unstable immediately after the light source is turned on, it is possible to prevent the color reproducibility from being degraded due to erroneous correction. it can.

A ninth aspect of the present invention is a projector which obtains a projected image by modulating illumination light from a light source, and a light source capable of dimming, and display means for displaying image information and modulating the illumination light from the light source. A display driving unit that drives a display unit based on an input video signal; a cooling unit that cools a light source; a current detection unit that detects a driving state of the light source; a temperature detection unit that detects a temperature state of the light source; Control means for controlling the driving conditions of the cooling means based on the current detection result by the detection means and the temperature detection result by the temperature detection means.

According to the ninth aspect, in the projector having the light source dimming function, the driving state and the temperature state of the light source can be measured, and the cooling condition of the light source can be controlled.
Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image that occurs when the light source is adjusted, and to realize good color reproducibility.

According to a tenth aspect, there is provided a projector for modulating illumination light from a light source to obtain a projected image, comprising a dimmable light source and display means for displaying image information and modulating the illumination light from the light source. Display drive means for driving the display means based on the input video signal, cooling means for cooling the light source,
Current detection means for detecting the drive state of the light source; temperature detection means for detecting the temperature state of the light source; and display via the display drive means based on the current detection result by the current detection means and the temperature detection result by the temperature detection means. Control means for controlling the driving conditions of the means.

According to the tenth aspect, in a projector having a light control function of the light source, the driving condition and the temperature condition of the light source can be measured, and the driving condition of the display means can be controlled. Therefore, it is possible to compensate for the deterioration of the color reproducibility of the projected image that occurs when the light source is adjusted, and to realize good color reproducibility.

[0030]

(First Embodiment) FIG. 1 is a block diagram showing a configuration of a projector to which a color reproducibility correcting apparatus according to a first embodiment of the present invention is applied. The color reproducibility correction apparatus according to the present embodiment includes a microcomputer 10, a memory 1,
1, a timer circuit 20, a current detection unit 21, and a temperature detection unit 22 for controlling driving conditions of the cooling unit 15.

In FIG. 1, an input video signal V
_in it is supplied to the display signal processing section 12. The display signal processing unit 12 performs the display driving condition 1 supplied from the microcomputer 10.
In accordance with 03, it performs a predetermined signal processing to the video signal V _in.
The signal processing in the display signal processing unit 12 is performed by the display element 6.
r, 6g, and 6b are determined according to the drive modulation characteristics, and details thereof are specified by the display drive condition 103. In the display signal processing unit 12, for example, brightness adjustment, gain adjustment, gamma correction, and the like are performed on the video signal Vin _in order to adjust the brightness and image quality of the projection image. Further, the display signal processing section 12, processes such as size conversion and image quality correction on the video signal V _in is performed. Display element driver 1
Reference numeral 3 drives the display elements 6r, 6g, 6b using the signal output from the display signal processing unit 12. Thus, the display element 6r, 6 g, the 6b, is displayed an image corresponding to the video signal V _in.

On the other hand, the light source driving section 1 drives the light source 2 according to the light source driving conditions 101 supplied from the microcomputer 10. More specifically, the light source driving unit 1 changes the driving current of the light source 2 according to the light source driving conditions 101 in order to dimming the light source 2. The light source 2 emits light under the drive control of the light source driving unit 1.

The illumination light from the light source 2 is reflected by the reflecting mirror 3 and then enters the relay optical system 4. The relay optical system 4
The incident light is condensed using a convex lens or the like, and condensed light suitable for subsequent processing is obtained. The condensed light passing through the relay optical system 4 is separated into a plurality of primary color lights by a color separation optical system 5 including a prism, a dichroic mirror, and the like.
In this embodiment, the illumination light from the light source 2 is decomposed into three types of primary color light of red, green, and blue (hereinafter, referred to as R, G, and B, respectively). These three types of primary color lights are applied to the display elements 6r, 6g, and 6b, respectively.

Each of the display elements 6r, 6g, and 6b displays an image corresponding to each color component, and separately modulates the intensity of each irradiated primary color light. For example, when the display element is a transmission element such as a liquid crystal panel, the intensity of each primary color light is modulated according to the transmission characteristics of each display element when passing through the display element. The display element is a DMD (Digita).
In the case of a reflective element such as 1 Mirror Device, each primary color light is intensity-modulated according to the reflection characteristics of each display element when reflected by the display element.

Each of the intensity-modulated optical signals is combined by a color combining optical system 7 composed of a prism, a dichroic mirror, and the like, and then passes through a projection lens 8. Thus, on the screen 9, the display element 6r, 6 g, 6b in the displayed image (i.e., an image corresponding to the video signal V _in) is enlarged and displayed. Note that the color separation optical system 5 and the color synthesis optical system 7 can be configured by the same prism.

A user of the projector operates a remote controller, a control panel, or the like (not shown) to instruct light control of the light source 2. The microcomputer 10 changes the light source driving condition 101 according to an operation from the user. The light source driving unit 1 changes the driving current of the light source 2 according to the light source driving conditions 101, whereby the light source 2 is dimmed. The dimming of the light source 2 changes the brightness of light passing through the optical system from the reflecting mirror 3 to the projection lens 8, and finally changes the brightness of the projected image on the screen 9.

The current detector 21 detects a drive current supplied from the light source driver 1 to the light source 2. Current detector 21
Detects the drive current of the light source 2 by, for example, (1) a method using a current detector using a Hall element, or (2) a method of detecting a voltage across a resistor inserted in a current path. The current detection unit 21 outputs the current detection result 201 thus detected to the microcomputer 10.

The temperature detecting section 22 detects the temperature of the light source 2 or the temperature at a peripheral position of the light source 2. Temperature detector 2
2 includes, for example, (1) a method of directly attaching a temperature sensor to the light source 2 to directly detect the light source temperature, or (2) disposing a non-contact temperature sensor for detecting thermal radiation near a position where the light source is viewed, A method of detecting the light source temperature by a non-contact temperature sensor, (3) a method of arranging the temperature sensor near a position where the light source is viewed and detecting the temperature at that position, and Then, the temperature of the light source 2 or the temperature of the peripheral position of the light source 2 is detected by a method of detecting the temperature of the reflecting mirror 3 or the like. The temperature detection unit 22 outputs the temperature detection result 202 thus detected to the microcomputer 1
Output to 0. When the above method (2), (3) or (4) is adopted, the relationship between the temperature detection result 202 and the light source temperature is experimentally obtained, and the correspondence is stored in the memory 11 in a table format. deep. The microcomputer 10 converts the temperature detection result 202 into a light source temperature using this table.

The memory 11 has a first table for converting the current detection result 201 into a current value, a second table for converting the temperature detection result 202 into a temperature value, and a table for converting the current value and the temperature value. A third table for obtaining the driving condition of the cooling unit 15 is stored. More specifically, the first and second tables respectively include the current detector 2
1 and the correspondence obtained in accordance with the type and characteristics of the temperature detector 22 are stored. The third table stores the optimum values of the drive conditions of the cooling unit 15 experimentally obtained in advance for the current value and the temperature value in the operation range of the projector. Note that the memory 11 has, instead of these three tables,
A table for directly obtaining the driving condition of the cooling unit 15 from the current detection result 201 and the temperature detection result 202 and an arithmetic expression corresponding to each table may be stored.

The microcomputer 10 receives the current detection result 201 and the temperature detection result 202 at predetermined time intervals, and obtains the driving condition of the cooling unit 15 by referring to the table or the arithmetic expression stored in the memory 11. The driving condition is output to the cooling driving unit 14 as the cooling driving condition 102. Cooling drive unit 1
4 changes the drive current of the cooling unit 15 according to the cooling drive condition 102. The cooling unit 15 includes, for example, a fan, and uses the driving current supplied from the cooling driving unit 14 to
To cool.

As described above, the current detector 21 and the temperature detector 2
2. Microcomputer 10, cooling drive unit 14, and cooling unit 1
5 forms a feedback loop. This feedback loop works to optimize the driving conditions of the cooling unit 15 according to the driving state and the temperature state of the light source 2 and stabilize the emission wavelength of the light source 2. When the emission wavelength of the light source 2 is stabilized, the color reproducibility of the projected image is stabilized as a result.

In the projector shown in FIG. 1, it is assumed that it takes a time T from when the light source 2 is turned on to when the driving state and the temperature state of the light source 2 are stabilized. Timer circuit 20
Operates according to the control of the microcomputer 10 from the start-up of the projector, obtains the elapsed time t from the lighting of the light source 2, and outputs it to the microcomputer 10. The microcomputer 10 calculates the elapsed time t
Is not performed until the time T is reached. This prohibits the application of color reproducibility correction until the projector is in a stable state and prevents the color reproducibility from deteriorating due to erroneous correction when the light emission characteristics are unstable immediately after the light source is turned on. Can be.

When the temperature detecting section 22 is configured by the above method (3) or (4), the temperature detection result 202 changes later than the actual temperature value of the light source 2. For this reason,
The microcomputer 10 converts the temperature detection result 202 into a temperature value with reference to the elapsed time t measured by the timer circuit 20. This makes it possible to compensate for deterioration in color reproducibility correction due to dimming of the light source, regardless of the method of realizing the temperature detection unit 22.

As described above, the color reproducibility correction apparatus according to the present embodiment detects the driving state and the temperature state of the light source, and cools the light source under the driving conditions calculated based on the detection results. For this reason, even if the light source is dimmed,
The cooling condition of the light source can be controlled so that the emission wavelength characteristic of the light source is stabilized. Therefore, it is possible to compensate for the deterioration in color reproducibility of the projected image that occurs when the light source is adjusted.

(Second Embodiment) A block diagram of a projector to which a color reproducibility correction device according to a second embodiment of the present invention is applied is the same as that of the first embodiment (see FIG. 1). The color reproducibility correction apparatus according to the present embodiment includes a microcomputer 10, a memory 11, a timer circuit 20, a current detector 2
1 and a temperature detecting unit 22, and the display elements 6r and 6
The g and 6b driving conditions are controlled. FIG.
, The configuration and operation of the timer circuit 20, the current detection unit 21 and the temperature detection unit 22,
In addition, the light control method of the light source 2 is the same as that of the first embodiment, and the description is omitted.

A case will be described in which three primary colors of red, green, and blue are assigned to the three display elements 6r, 6g, and 6b, respectively, and three primary color lights are modulated by the three display elements to perform color display. The white color obtained by combining the three primary colors of R, G, and B is referred to as W.

The light source 2 emits light in the reference driving state and the temperature state, and the emission wavelength at that time is set as the reference emission wavelength. At this time, the reference chromaticities of R, G, B, and W of the projection image displayed in a fixed size on the screen 9 are respectively set to (Rx, R
y), (Gx, Gy), (Bx, By), (Wx, W
y) and the illuminances of R, G, B, and W on the screen 9 are RY, GY, BY, and WY, respectively.
Holds.

[0048]

(Equation 1)

In the design of the color reproducibility correction device, when the driving state or the temperature state of the light source 2 changes from the reference value, the light source 2
How the chromaticity of the primary color light obtained by decomposing the illumination light from the chromaticity changes from each reference chromaticity is experimentally obtained in advance, and the obtained chromaticity change data is stored in the memory 11. . At the same time, even if the chromaticities (Rx, Ry), (Gx, Gy), and (Bx, By) of R, G, and B change, the color of the white W in the above equation (1) is stored. Degree (Wx, W
y) and a correction value RY ′ for keeping the illuminance WY constant,
A table or an arithmetic expression for calculating GY ′ and BY ′ is stored.

The microcomputer 10 receives the current detection result 201 and the temperature detection result 202 at predetermined time intervals, and obtains the driving conditions of the display element 6 by referring to a table or an arithmetic expression stored in the memory 11. The driving condition is output to the display signal processing unit 12 as the display driving condition 103.

The display signal processing unit 12 controls the display driving condition 10
3 Follow switches the signal processing performed on the video signal V _in. For example, the display signal processing unit 12 sets the display drive condition 10
3 Follow corrects the chromaticity and luminance of the video signal V _in, and outputs the corrected drive signal. The display element driving unit 13 drives the display elements 6r, 6g, 6b using the corrected drive signal. Thereby, the projected image on the screen 9 is
The chromaticity and illuminance are displayed in a corrected state.

As described above, the color reproducibility correction apparatus according to the present embodiment detects the driving state and the temperature state of the light source, and drives the display element under the driving conditions calculated based on these detection results. Therefore, even when the light source is dimmed, the driving conditions of the display element can be controlled so as to compensate for the effect. Therefore, it is possible to compensate for the deterioration in color reproducibility of the projected image that occurs when the light source is adjusted.

(Third Embodiment) A block diagram of a projector to which a color reproducibility correcting device according to a third embodiment of the present invention is applied is common to the first embodiment (see FIG. 1). The color reproducibility correction apparatus according to the present embodiment has both the features of the first and second embodiments. That is, the color reproducibility correction apparatus according to the present embodiment includes the microcomputer 10, the memory 11, the timer circuit 20, the current detection unit 21, and the temperature detection unit 22, and the driving conditions of the cooling unit 15 and the display elements 6r and 6g. , 6b are simultaneously controlled.

According to this embodiment, only the driving condition of the cooling unit 15 is controlled (first embodiment), or only the driving condition of the display elements 6r, 6g, 6b is controlled (second embodiment).
As compared with the embodiment, the deterioration of the color reproducibility of the projected image which occurs when the light source is dimmed can be corrected with higher accuracy.

(Fourth Embodiment) FIG. 2 shows a fourth embodiment of the present invention.
FIG. 3 is a block diagram showing a configuration of a projector to which the color reproducibility correction device according to the embodiment is applied. The color reproducibility correction device according to the present embodiment has the emission wavelength detection unit 30 and the photoelectric converter 31 added to the color reproducibility correction device according to the third embodiment to improve the accuracy of color reproducibility correction. Things. Except for the added two elements and the function of the microcomputer 10, the third embodiment is the same as the third embodiment, and the description is omitted.

The emission wavelength detector 30 can detect the illumination light from the light source 2 and does not affect the light incident on the relay optical system 4 (ie, a position where no shadow is formed on the relay optical system 4). And detects the wavelength of the light leaked from the light source 2. The emission wavelength detection unit 30 may be, for example, a filter element that filters an optical signal so that the wavelength can be detected if the microcomputer 10 performs post-processing. In this case, the wavelength of the light source 2 is determined by the emission wavelength detection unit 30 and the microcomputer 1
It is detected by the action with 0. The photoelectric converter 31 converts the wavelength detected by the emission wavelength detector 30 into an electric signal,
The wavelength detection result 203 is output to the microcomputer 10.

As in the third embodiment, the microcomputer 10 receives the current detection result 201 and the temperature detection result 202 at predetermined time intervals and refers to a table or an arithmetic expression stored in the memory 11 to perform cooling. The driving conditions of the unit 15 and the driving conditions of the display element 6 are obtained, and the cooling driving conditions 102 are respectively obtained.
And, as the display drive condition 103, it outputs to the cooling drive unit 14 and the display signal processing unit 12. At this time, the microcomputer 10
Receives the wavelength detection result 203 and corrects the driving condition of the display element 6 based on the result.

In the design of the color reproducibility correction device, how the driving conditions of the display element 6 should be corrected based on the wavelength detection result 203 is experimentally obtained in advance, and the obtained correction data is stored in the memory 11. . The microcomputer 10 has a memory 1
The wavelength detection result 2 is referred to with reference to the correction data stored in 1.
03, the driving condition of the display element 6 is corrected.

As described above, the color reproducibility correcting apparatus according to the present embodiment detects the driving state and the temperature state of the light source and calculates based on these detection results, as in the third embodiment. The light source is cooled under the set driving conditions, and the display unit is driven. In addition, in the present embodiment, the emission wavelength of the light source is detected, and the driving conditions of the display unit are corrected based on the detected emission wavelength.
Therefore, it is possible to more stably and accurately correct the deterioration of the color reproducibility of the projected image that occurs when the light source is adjusted.

(Fifth Embodiment) FIG. 3 shows a fifth embodiment of the present invention.
FIG. 3 is a block diagram illustrating a configuration of a projector to which the color reproducibility correction device according to the embodiment is applied. The color reproducibility correction apparatus according to the present embodiment adds a primary color chromaticity detection unit 40 and a photoelectric converter 41 to the color reproducibility correction apparatus according to the third embodiment to improve the accuracy of color reproducibility correction. It is something. Except for the added two elements and the function of the microcomputer 10, the third embodiment is the same as the third embodiment, and the description is omitted.

The primary color chromaticity detector 40 is a junction between the color separation optical system 5 and the display elements 6r, 6g, 6b,
Color separation optics, which can detect primary color light obtained by decomposing illumination light from the display device and does not affect the light incident on the display element (that is, a position where no shadow is formed on the display element); The chromaticity of each primary color light output from the system 5 is detected. The primary color chromaticity detection unit 40 may be, for example, a filter element that filters the optical signal so that the chromaticity can be detected when the microcomputer 10 performs post-processing. In this case, the chromaticity of each primary color light is detected by the operation of the primary color chromaticity detection unit 40 and the microcomputer 10. The photoelectric converter 41 converts the chromaticity detected by the primary color chromaticity detection unit 40 into an electric signal, and outputs a chromaticity detection result 204 to the microcomputer 10.

As in the third embodiment, the microcomputer 10 receives the current detection result 201 and the temperature detection result 202 at predetermined time intervals, and refers to a table or an arithmetic expression stored in the memory 11 to perform cooling. The driving conditions of the unit 15 and the driving conditions of the display element 6 are obtained, and the cooling driving conditions 102 are respectively obtained.
And, as the display drive condition 103, it outputs to the cooling drive unit 14 and the display signal processing unit 12. At this time, the microcomputer 10
Receives the chromaticity detection result 204 and corrects the driving conditions of the display element 6 based on the result.

In the design of the color reproducibility correction apparatus, how to correct the driving conditions of the display element 6 based on the chromaticity detection result 204 is experimentally obtained in advance, and the obtained correction data is stored in the memory 11. deep. The microcomputer 10 has a memory 1
Chromaticity detection result 2 with reference to the correction data stored in
04, the driving condition of the display element 6 is corrected.

As described above, the color reproducibility correction apparatus according to the present embodiment detects the driving state and the temperature state of the light source and calculates based on these detection results, as in the third embodiment. The light source is cooled under the set driving conditions, and the display unit is driven. In addition, in the present embodiment, the chromaticity of each primary color light is detected, and the driving condition of the display unit is corrected based on the detected chromaticity.
Therefore, it is possible to more stably and accurately correct the deterioration of the color reproducibility of the projected image that occurs when the light source is adjusted.

In the first to fifth embodiments, the color reproducibility correction device having a specific configuration has been described. However, the present invention is not limited to this, and measures the driving state and the temperature state of the light source. , And all color reproducibility correction devices that control the driving conditions of the cooling unit or the display element. The color reproducibility correction device of the present invention may simultaneously control the driving condition of the cooling unit and the driving condition of the display element, and may include an emission wavelength detection unit and a primary color chromaticity detection unit for the purpose of correction accuracy. A timer circuit may be provided for the purpose of improving characteristics at the time of starting. Further, a part of the functions of the microcomputer 10 may be realized by an independent arithmetic circuit, and the display element may have a configuration other than R, G, and B. Further, any light modulation element that modulates incident light can be used as the display element.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a projector to which a color reproducibility correction device according to first, second, and third embodiments of the present invention is applied.

FIG. 2 is a block diagram illustrating a configuration of a projector to which a color reproducibility correction device according to a fourth embodiment of the present invention is applied.

FIG. 3 is a block diagram illustrating a configuration of a projector to which a color reproducibility correction device according to a fifth embodiment of the present invention is applied.

FIG. 4 is a block diagram illustrating a configuration of a conventional projector.

FIG. 5 is a diagram illustrating an example of emission wavelength characteristics of a light source.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Light source drive part 2 ... Light source 3 ... Reflecting mirror 4 ... Relay optical system 5 ... Color separation optical system 6r, 6g, 6b ... Display element 7 ... Color synthesis optical system 8 ... Projection lens 9 ... Screen 10 ... Microcomputer 11 ... Memory DESCRIPTION OF SYMBOLS 12 ... Display signal processing part 13 ... Display element drive part 14 ... Cooling drive part 15 ... Cooling part 20 ... Timer circuit 21 ... Current detection part 22 ... Temperature detection part 30 ... Emission wavelength detection part 31, 41 ... Photoelectric converter 40 ... Primary color chromaticity detection unit 101: Light source drive condition 102: Cooling drive condition 103: Display drive condition 201: Current detection result 202: Temperature detection result 203: Wavelength detection result 204: Chromaticity detection result

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09G 5/00 G09G 5/00 550C 5/02 5/02 B H05B 41/39 H05B 41/39

Claims (10)

[Claims] 1. A dimmable light source, display means for displaying image information and modulating illumination light from the light source, display driving means for driving the display means based on an input video signal, and A color reproducibility correction apparatus applied to a projector including a cooling unit for cooling, a current detection unit for detecting a driving state of the light source, a temperature detection unit for detecting a temperature state of the light source, and the current A color reproducibility correction device for a projector, comprising: a control unit that controls a driving condition of the cooling unit based on a current detection result by a detection unit and a temperature detection result by the temperature detection unit. 2. The apparatus according to claim 1, further comprising a wavelength detecting unit for detecting an emission wavelength of the light source, wherein the control unit detects a current detected by the current detecting unit, a temperature detected by the temperature detecting unit, and a wavelength detected by the wavelength detecting unit. 2. The color reproducibility correcting apparatus for a projector according to claim 1, wherein a driving condition of the cooling unit is controlled based on the result. 3. A chromaticity detection unit for detecting chromaticity of a plurality of primary color lights obtained by decomposing illumination light from the light source, wherein the control unit detects a current detection result by the current detection unit and 2. The color reproducibility correction of the projector according to claim 1, wherein a driving condition of the cooling unit is controlled based on a temperature detection result by the temperature detection unit and a chromaticity detection result by the chromaticity detection unit. apparatus. 4. The apparatus further comprises timer means for measuring an elapsed time from when the light source is turned on, wherein the control means includes a current detection result by the current detection means, a temperature detection result by the temperature detection means, and a timer The driving condition of the cooling unit is controlled based on the measured elapsed time.
3. The color reproducibility correction device for a projector according to item 1. 5. A dimmable light source, display means for displaying image information and modulating illumination light from the light source, display driving means for driving the display means based on an input video signal, and A color reproducibility correction apparatus applied to a projector including a cooling unit for cooling, a current detection unit for detecting a driving state of the light source, a temperature detection unit for detecting a temperature state of the light source, and the current A color reproducibility correcting device for a projector, comprising: control means for controlling driving conditions of the display means via the display driving means based on a current detection result by the detection means and a temperature detection result by the temperature detection means. 6. A wavelength detecting means for detecting an emission wavelength of the light source, wherein the control means detects a current detected by the current detecting means, a temperature detected by the temperature detecting means, and a wavelength detected by the wavelength detecting means. 6. The color reproducibility correcting apparatus for a projector according to claim 5, wherein a driving condition of the display unit is controlled via the display driving unit based on the result. 7. A chromaticity detection unit for detecting chromaticity of a plurality of primary color lights obtained by decomposing illumination light from the light source, wherein the control unit determines a current detection result by the current detection unit. 6. The driving condition of the display unit is controlled via the display driving unit based on a temperature detection result by the temperature detection unit and a chromaticity detection result by the chromaticity detection unit. Color reproducibility correction device for projectors. 8. The apparatus further comprising timer means for measuring an elapsed time from when the light source is turned on, wherein the control means comprises a current detection result by the current detection means, a temperature detection result by the temperature detection means, and a timer The color reproducibility correcting apparatus for a projector according to claim 5, wherein a driving condition of the display unit is controlled via the display driving unit based on the measured elapsed time. 9. A projector for modulating illumination light from a light source to obtain a projected image, comprising: a dimmable light source; display means for displaying image information and modulating the illumination light from the light source; A display driving unit that drives the display unit based on a video signal; a cooling unit that cools the light source; a current detection unit that detects a driving state of the light source; and a temperature detection unit that detects a temperature state of the light source. A projector, comprising: a control unit that controls a driving condition of the cooling unit based on a current detection result by the current detection unit and a temperature detection result by the temperature detection unit. 10. A projector for modulating illumination light from a light source to obtain a projected image, comprising: a dimmable light source; display means for displaying image information to modulate the illumination light from the light source; A display driving unit that drives the display unit based on a video signal; a cooling unit that cools the light source; a current detection unit that detects a driving state of the light source; and a temperature detection unit that detects a temperature state of the light source. A projector, comprising: control means for controlling driving conditions of the display means via the display driving means based on a current detection result by the current detection means and a temperature detection result by the temperature detection means.