JP2007241059A - Display device for mobile object - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively perform color correction according to the reflected light on the surface of a display device and satisfactorily reproduce the intended color. <P>SOLUTION: An outside light detection part 5 is disposed adjacent to a display device 3, and a spectrum measuring instrument 6 is disposed for measuring a spectrum (color temperature) in the visible light region of the outside light received by the outside light detection part 5. A color balance adjustment circuit 13 performs color correction, by multiplying the intensity in each wavelength of the measured spectrum by the reflectivity in the surface of the display device 3 for each wavelength, acquiring the intensity of the reflected light for each of the segmented wavelengths, and subtracting the acquired intensity of the reflected light of each wavelength acquired, from RGB signals inputted from inverse gamma transformation part 12. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a moving body display device that is provided in a moving body such as a vehicle and displays a color image on a screen of a display based on an image signal.

  For example, a display device mounted on a vehicle (automobile) displays various images such as a navigation (map) screen, a video of a camera around the vehicle for driving support, and a video of a TV or a DVD on the display. It has become. In this case, particularly when displaying the surrounding image of the vehicle, the display color of the display device is required to be equivalent to the actual color when the user visually observes the periphery. However, especially in an environment where the vehicle is used outdoors, such as in-vehicle use, the display color changes due to the reflection of external light on the surface of the display. In order to reproduce the intended color on the display screen Color correction will be necessary.

For example, Patent Document 1 discloses a color correction device in a display device that includes a selective absorption filter that absorbs a red wavelength component on the front surface of a plasma display panel (PDP). In this apparatus, an external light detection unit for detecting external light incident on the filter is provided in the vicinity of the PDP, and the external light detected by the external light detection unit is passed through three primary color filters, and R (red), G ( The level (light intensity) for B) and B (blue) is detected (see FIG. 3C), and the display color of the PDP is corrected based thereon.
JP-A-8-123364

  However, the technique disclosed in Patent Document 1 detects the light intensity of external light that has passed through the three primary color filters and performs color correction that balances the three primary colors. For this reason, the wavelength components of the outside light that are out of the three primary colors cannot be accurately detected, and hence cannot be corrected over the entire visible light region, so that it is not possible to accurately reproduce the color. It was enough.

  In general, in a liquid crystal display device of an in-vehicle navigation device, the color temperature when displaying a TV or DVD image is set to about 9500K (slightly bluish white). The color temperature is higher than about 6300K. For this reason, when watching a TV program in an outdoor environment, the color temperature is lower than intended (a slightly yellowish display). In addition, in the case of an in-vehicle display device, there are circumstances in which the external light color and the reflected light fluctuate variously due to environmental changes such as a yellow sodium lamp in the tunnel, reflections on snowy days, sunsets, etc. In spite of the color display, the user may perceive a different color.

  The present invention has been made in view of the above circumstances, and the object thereof is to effectively perform color correction according to the reflected light on the surface of the display and to sufficiently reproduce the intended color. The present invention provides a display device for a moving body.

  In order to achieve the above object, a display device for a moving body according to the present invention is provided on a moving body and displays a color image on a screen of a display based on an image signal, and receives light from outside. A spectral spectrum measuring means for measuring a spectral spectrum in the visible light region of external light received by the light receiving section, and an image to be displayed on the display unit based on the spectral spectrum measured by the spectral spectrum measuring means. And a color balance adjusting means for adjusting the color balance.

  In the present invention, the spectral spectrum in the visible light region of the external light received by the light receiving unit can be measured by the spectral spectrum measuring means. As a result, a spectrum (intensity) obtained by subdividing the light in the visible light region for each wavelength can be measured with respect to the external light incident on the display. Based on this, the entire visible light region can be measured by the color balance adjusting means. Thus, the color correction of the image displayed on the display can be performed. As a result, the color correction according to the reflected light on the surface of the display can be effectively performed, and the intended color can be sufficiently reproduced.

  More specifically, the color balance adjusting unit is configured to obtain the intensity for each wavelength of the reflected light on the display surface from the spectral spectrum, and to correct the image signal according to the reflected light intensity for each wavelength. (Invention of claim 2). Thereby, the correction | amendment according to the intensity | strength for every wavelength which subdivided the visible light area | region of the reflected light reflected on the display surface can be performed, and an effective color correction can be performed.

  In this invention, the said light-receiving part can be provided in the surrounding part of the screen of a display (Invention of Claim 3). The light receiving unit can be easily provided. Or a light-receiving part can also be provided in the screen of a display device (invention of Claim 4). External light incident on the screen of the display can be directly received, and color correction with higher accuracy can be performed. Or you may make it provide a light-receiving part in the vicinity of the position of a user's eye who looks at the screen of a display device normally (invention of Claim 5). Thereby, the reflected light when the user views the screen of the display device directly can be directly received, and more effective color correction can be performed.

  The display device for a moving body of the present invention can be applied to a display device that is mounted on a vehicle and displays an image for driving support on a display (invention of claim 6). According to this, even when there is a situation in which the outside light color and thus the reflected light fluctuate greatly, the display device displays a high-quality image for driving assistance that reproduces the intended color. Can do.

  Hereinafter, an embodiment in which the present invention is applied to an in-vehicle display device will be described with reference to the drawings. FIG. 1 schematically shows a cross-sectional configuration of a display device 1 according to the present embodiment. This display device 1 includes a frame (case) 2 having a thin rectangular box shape in front and rear, a display 3 made of a full-color liquid crystal display, an image signal processing unit (circuit board) 4, and an external light detection unit 5 as a light receiving unit. A spectral spectrum measuring device 6 or the like serving as a spectral spectrum measuring means is incorporated. Although not shown, the display device 1 is arranged, for example, at the center of an instrument panel of a vehicle (automobile) as a moving body.

  The display 3 is provided on the front surface of the frame 2, and more specifically, as shown in FIG. 2, the display 3 has a backlight 8 on the back side of the LCD panel 7. As will be described later, the display 3 is driven by the image signal processing unit 4 to display a color image. Although not shown, a touch panel is provided on the front surface of the display 3 for a user (driver) to perform various input instruction operations (for example, selection of a display image).

  The image signal processing unit 4 receives an image signal (video input signal) from a control unit of a car navigation system (not shown), a TV tuner, a DVD player, a vehicle surrounding camera, or the like. Based on the image signal, the display unit 3 is driven to display images such as a navigation screen such as a road map screen, a TV image, a DVD image, and a driving support image by a vehicle surrounding camera. ing.

  Specifically, as shown in FIG. 2, the image signal processing unit 4 includes a γ / c separation unit 9 that separates an input image signal into a luminance signal γ and a color signal c, and demodulates the color signal c into a color difference signal. A decoder 10 that performs matrix conversion of the color difference signal into an RGB signal, an inverse gamma conversion unit 12 that performs inverse gamma conversion of the RGB signal, and color as color balance adjustment means that adjusts the color balance of the RGB signal, as will be described later. A balance adjustment circuit 13 and an analog drive circuit 14 for driving the LCD panel 7 are provided.

  The image signal processing unit 4 also includes a synchronization detection circuit 15 that detects the synchronization of the input image signal, a timing generator 16 that generates a timing signal based on the detection, and a digital that drives the LCD panel 7 based on the timing signal. The driving circuit 17 includes a backlight driving circuit 18 that drives the backlight 8 based on the timing signal. The timing signal from the timing generator 16 is also input to the decoder 10 and the color balance adjustment circuit 13.

  The external light detection unit 5 is composed of, for example, an optical sensor, and is provided near the periphery (upper part) of the display 3 (LCD panel 7) on the front surface of the display device 1 as shown in FIG. It has been. Thus, the external light detection unit 5 detects (receives) external light incident on the display 3. The external light received by the external light detector 5 is input to the spectral spectrum measuring device 6 as shown in FIG.

  The spectral spectrum measuring instrument 6 measures (detects) a spectral spectrum (color temperature) in the visible light region of external light input from the external light detection unit 5. As shown in FIG. 2, the measurement signal is input to the color balance adjustment circuit 13 of the image signal processing unit 4. At this time, in this embodiment, as shown in FIG. 3B, for example, the spectroscopic spectrum measuring instrument 6 divides the 400 nm range (380 nm to 780 nm) of the wavelength in the visible light region into 20 equal increments of 20 nm. A spectrum (intensity) subdivided for each wavelength is measured. At this time, the degree of subdivision may be selected as appropriate (the more subdivided, the better the color reproducibility), but it is necessary to make it finer than detecting at least three primary colors.

  The color balance adjustment circuit 13 adjusts the color balance of the image to be displayed on the display 3 based on the measurement signal from the spectral spectrum measuring device 6, that is, the RGB signal from the inverse gamma conversion unit 12. On the other hand, the color correction corresponding to the reflected light on the surface of the display 3 caused by the external light is performed.

  More specifically, as will be described in the following explanation of the operation, first, the reflectance at the surface of the display 3 (a fixed value, which is known in advance) with respect to the intensity at each wavelength of the measured spectrum. ) Is multiplied for each wavelength, and in this case, the reflected light intensity for each wavelength subdivided into 20 is obtained. Next, correction is performed by subtracting the obtained reflected light intensity for each wavelength from the RGB signal (spectrum to be displayed) input from the inverse gamma conversion unit 12.

  Next, the operation of the above configuration will be described with reference to FIGS. As described above, the in-vehicle display device 1 displays various images such as a navigation (map) screen, a video of a camera around the vehicle for driving support, and a video of a TV or a DVD on the display 3. It has become. In this case, in particular, when displaying an image for driving assistance (peripheral image of the vehicle by the camera), the display color of the display device 3 is required to be equivalent to the actual color when the user visually observes the periphery. . On the navigation screen, the color of the road may be color-coded (for example, the highway is displayed in purple, while the road during route guidance is displayed in blue). It is important to avoid it.

  However, in an environment where the vehicle is used outdoors such as in-vehicle use, there is a situation in which the external light is reflected on the surface of the display 3 and the display color visually recognized by the user changes. For example, depending on environmental changes such as daytime on sunny days, cloudy and rainy days, yellow sodium lamps in tunnels, reflections on snowy days, sunsets, etc., the ambient light color and the reflected light on the display 3 surface will vary There is a possibility that the user may recognize a different color in spite of a predetermined color display. Therefore, color correction is necessary to reproduce the intended color on the screen of the display device 3. In this embodiment, color correction is performed as follows.

  That is, the external light is received by the external light detector 5 arranged in the vicinity of the periphery of the display 3, and the spectral spectrum obtained by subdividing the visible light region wavelength of the external light into 20 equal parts by the spectral spectrum measuring device 6. Is measured. FIG. 3 shows an example. For example, when the external light has the intensity (white light) shown in FIG. The intensity of external light for each wavelength obtained by subdividing the visible light region into 20 as shown in b) is obtained. The measurement result is input to the color balance adjustment circuit 13 of the image signal processing unit 4.

  Incidentally, in FIG. 3C, for reference, outside light equivalent to that shown in FIG. 3A is passed through the three primary color filters as described in the conventional example, and R (red), G ( The case where the level (light intensity) regarding B) and B (blue) is detected is shown. In this way, when the three primary color filters are used, the intensity of light at an intermediate wavelength between wavelengths corresponding to RGB cannot be detected.

  In the color balance adjustment circuit 13, first, as shown in FIG. 4, an indicator that is known in advance with respect to the intensity (see FIG. 4A) of each spectrum of the spectrum measured as described above. 3 is multiplied for each wavelength by the reflectance on the surface of 3 (see FIG. 4B), and the reflected light intensity for each wavelength on the surface of the display 3 is obtained (see FIG. 4C). Next, as shown in FIG. 5, from the RGB signal to be displayed (see FIG. 5A) input from the inverse gamma conversion unit 12, the reflected light intensity for each wavelength obtained above (see FIG. 5B). ) Is subtracted to correct the color balance (see FIG. 5C). The corrected signal is input to the analog drive circuit 14, and the display 3 (LCD panel 7) is driven.

  As a result, the influence of the reflection of external light on the surface of the display 3 is corrected, and the intended image color is displayed on the display 3 (LCD panel 7) over the entire visible light region with good reproducibility. It is. In this case, the correction according to the intensity | strength for every wavelength which subdivided the visible light area | region into plurality (in this case 20) of the reflected light reflected in the display 3 surface of the external light which injected into the display 3 can be performed. Therefore, effective color correction can be performed.

  As described above, according to the present embodiment, the spectral spectrum obtained by subdividing the wavelength of the visible light region of the external light incident on the display unit 3 is measured by the spectral spectrum measuring device 6, and the color balance is determined based on the measurement result. Unlike the conventional method of performing color correction based on detecting the light intensity through the color filters of the three primary colors of external light, the reflected light on the surface of the display unit 3 is reflected. The corresponding color correction can be effectively performed over the entire visible light region, and an excellent effect that the intended color can be sufficiently reproduced can be obtained.

  In the above embodiment, the external light detection unit 5 (light receiving unit) is provided in the vicinity of the display 3. However, the light receiving unit may be provided in the display screen. good. As a result, external light incident on the screen of the display can be directly received, and more accurate color correction can be performed. Or a light-receiving part can also be provided in the vicinity of the position of the eyes of the user who views the display screen. Thereby, the reflected light when the user views the screen of the display device directly can be directly received, and more effective color correction can be performed.

  Moreover, in the said Example, although this invention was applied to the display apparatus 1 which displays a navigation screen etc., it applies to a vehicle-mounted combination meter (thing provided with a speedometer, a tachometer, etc.), an electronic mirror, etc. You can also. In addition, the present invention is not limited to in-vehicle use, and can be applied as appropriate to a display device of a portable terminal such as a PDA that can be carried by an individual and used outdoors. Can be implemented.

The longitudinal cross-sectional view which shows one Example of this invention and shows the structure of a display apparatus roughly Block diagram schematically showing the configuration of the image signal processor Figure showing an example of spectral spectrum measurement Figure showing a calculation example of reflected light intensity Diagram showing an example of color balance correction

Explanation of symbols

  In the drawings, 1 is a display device, 3 is a display, 4 is an image signal processing unit, 5 is an external light detection unit (light receiving unit), 6 is a spectral spectrum measuring device (spectral spectrum measuring means), and 13 is a color balance adjustment circuit. (Color balance adjusting means) is shown.

Claims (6)

A moving body display device that is provided on a moving body and displays a color image on a display screen based on an image signal,
A light receiving unit for receiving external light;
Spectral spectrum measuring means for measuring a spectral spectrum in the visible light region of external light received by the light receiving unit,
A moving body display device comprising: color balance adjusting means for adjusting a color balance of an image displayed on the display unit based on a spectral spectrum measured by the spectral spectrum measuring means.   The color balance adjusting unit is configured to obtain an intensity for each wavelength of reflected light on the display surface from the spectral spectrum, and to correct the image signal according to the reflected light intensity for each wavelength. The moving body display device according to claim 1, wherein:   The mobile light display device according to claim 1, wherein the light receiving unit is provided in a peripheral part of a screen of the display.   3. The moving body display device according to claim 1, wherein the light receiving unit is provided in a screen of the display.   The mobile light display device according to claim 1, wherein the light receiving unit is provided in the vicinity of a position of an eye of a user viewing the screen of the display device.   6. The moving body display device according to claim 1, wherein the display device is mounted on a vehicle, and displays an image for driving support on the display.

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