FR2915797A1 - DEVICE AND METHOD FOR CALIBRATING A LIGHT SOURCE. - Google Patents

Abstract

The invention relates to a device for calibrating a light source according to a standard. Said device comprises means for capturing the emitted light and directing it towards a wavelength separator 12. Said calibration device according to the invention is remarkable in that said wavelength separator 12 comprises an optical block in the volume of which is formed a holographic diffraction grating. Said calibration device further comprises means for acquiring the separate wavelengths. These means are of the CCD sensor type and make it possible to convert the light into an electrical signal. Said calibration device further comprises means for comparing 14 the wavelengths emitted by the screen with the wavelengths of the etalon and means for adjusting the wavelengths emitted by the screen.

Description

1 Device and method for calibrating a light source The invention

  relates to a calibration device of a light source. The major manufacturers of computer peripherals and in particular monitors and televisions are entering a new phase of competition where color fidelity is a key parameter. In recent years, and outside the standard parameters of differentiation (cost, aesthetics, dimensions), the competition had mainly focused on the liveliness of the colors. The advent of the personal digital channel (photo, screen, print) no longer allows such a design reasoning, the user need today resides in the color fidelity of the entire chain. To retain the color space, a standard exists for the entire digital chain is the sRGB is the acronym for standardized Red (Red), Green (Green), Blue (Blue). SRGB is a color space whose purpose is to match colors between devices and applications such as screens, scanners, printers and digital cameras. SRGB eliminates the need for color management based on the assumption that all RGB devices have the same color space. A large number of consumer products adhere to this standard such as consumer scanners or digital cameras. The images that come out of these devices are sRGB images and at the other end of the chain, the photographic laboratories that process the digital images consider all the images they receive as sRGB images, whether or not accompanied by their sRGB profile. SRGB has also become the standard for image publishing on the internet. However, not all devices (cameras, screens or printers) have the same color space (the gamut). The gamut of the monitors comes from an additive synthesis of the colors Red, Green, Blue while that of the printers is derived from a subtractive synthesis of four colors Cyan, Magenta, Yellow and Black. Professional printers have three additional colors: Light Cyan, Light Magenta, and Gray.

  Therefore, to limit color drift between different devices, we use calibration methods to match the gamut of the screen to that of the printer: the technical principle is to change the natural characteristics of the printer. screens to match standard features, using calibration profiles such as ICC (the acronym for the International Color Consortium). An ICC calibration profile is a digital file describing how a device reports colors. This file contains ~ o colorimetric information in the form of colorimetric coordinates (for example RGB or CMYK). The ICC profile is the link between the theoretical coordinates of the colors that one would like to achieve and the color coordinates of the colors actually reached by the device. For a screen, a scanner or a digital camera, the profile is RGB and in the case of a printer or plotter, it is a CMYK profile. In addition, the manufacturing technologies specific to flat screens induce non-standardization of monitors. As this standard began to take hold with the latest generations of CRT monitor: 20 (possibility to implement a sRGB setting on the monitor in exchange for a slight loss of saturation), the new flat screens are not yet able to approach the gamut of the sRGB standard and can not meet the standard of this standard. Standardizing the colors of the flat screens involves either: calibrating each monitor at the output of the string, or integrating a tool capable of performing this operation within the monitor. Today most monitors are equipped with a system for adjusting the color parameters (via the buttons on the front for the computer monitors or the menus of the remote control for the television screens 30) but the adjustment is done visually and not in relation to a standard. To calibrate an LCD, there are two main methods. A first method is to calibrate the screen visu using a specialized utility like the sights of television screens or utilities such as Adobe Gamma. This solution is not very precise, and the result

  3 depends heavily on the person calibrating the screen. It is better to check with a chart or a test image. A second method is to have a probe, equipped with suction cups to attach to the screen. The probe used may be either a colorimeter or a spectrophotometer. The first one analyzes the source through 3 or 4 filters, while the second makes a measurement generally every 10nm over the entire visible spectrum, using a diffraction grating. The spectrophotometer is more accurate and works without problems with all types of screens. The calibration principle is based on the measurement of the colors displayed successively on the screen, and the recording of the corresponding L * a * b * coordinates. The profile of the screen is thus the link between the RGB coordinates and the coordinates L * a * b *. However, probes are relatively expensive and reserved for professional use.

  The object of the invention is to overcome the problems mentioned above by proposing a device integrated in the screen capable of capturing the spectrum and comparing it with a reference value. In case of deviation, the device makes it possible to vary the spectrum of the monitor until it corresponds to the standard value. The detection of the optical spectrum is advantageously carried out with a holographic Bragg grating, the perception, for example, using a CCD array and the interpretation part by a software part. The use of a holographic Bragg grating makes it possible to reduce the size of the calibration device. The invention can easily be integrated into a screen thanks to its compactness and its low cost of production. For this purpose, the subject of the invention is a device for calibrating a light source as a function of a standard comprising an optical reference spectrum, comprising: means for capturing the light emitted by the light source; means for separating the spectrum from the captured light, - means for acquiring the separated spectrum, - means for comparing the spectrum emitted by the light source with the reference spectrum, 4 - means for adjusting the spectrum emitted by the light source characterized in that the means for separating the wavelengths from the captured light comprises an optical block in the volume of which a holographic diffraction grating is formed.

  Advantageously, the optical block is of rectangular parallelepipedal shape and comprises successive layers having index variations, said layers being parallel to each other and being inclined with respect to the longitudinal axis of the block.

  Advantageously, said layers are formed of polymer materials or electro-optical materials of the liquid crystal type.

  Advantageously, the spatial separation of the spectrum of the captured light, carried out by the optical block, is linear.

  Advantageously, the calibration device according to the invention comprises automatic means for comparing the spectrum emitted by the light source with the reference spectrum.

  Advantageously, the calibration device according to the invention comprises automatic means for adjusting the spectrum emitted by the light source. Advantageously, the means for capturing the light emitted by the light source comprise a waveguide.

  Advantageously, the means for acquiring the spectrum 3o comprise an electronic optical conversion system, notably a CMOS sensor, a CCD array or a CCD array.

  Advantageously, the standard is in the form of a calibration profile. The invention also relates to a display device comprising a light source, characterized in that it comprises the calibration device according to the invention.

  The invention also relates to a method for calibrating a light source implementing the calibration device according to the invention, characterized in that the calibration of a parameter of the light emitted by the light source comprises the following steps: separation of the spectrum of the emitted light, ~ o the acquisition of the image of the emitted light, the comparison of the image with the standard, if the image is identical to the standard, the said parameter is calibrated, if the The image is different from the standard, the adjustment of the parameter of the light emitted by the screen and the repetition of the step of separating the spectrum of the light emitted.

  Advantageously, the method for calibrating a light source according to the invention further comprises the following step: receiving the parameters of the calibration profile. The invention will be better understood and other advantages will appear on reading the detailed description and with the help of the figures among which: FIG. 1 represents a functional architecture of the calibration device 2.5 according to the invention. Figures 2a and 2b respectively show a linear spatial separation device wavelengths and a sectional view of said device. FIG. 3 represents an exemplary embodiment of the device 30 according to the invention, integrated with a light source. Figure 4 shows the operation of an LCD screen. FIG. 5 represents different steps of the calibration method according to the invention.

  FIG. 1 represents a functional architecture of the calibration device of a light source as a function of a standard. Said device comprises means for capturing the emitted light and directing it towards a wavelength separator 12. Said calibration device according to the invention is remarkable in that said wavelength separator 12 comprises an optical block in the volume of which is formed a holographic diffraction grating. Said calibration device further comprises means for acquiring the separate wavelengths. These means are of the CCD sensor type and make it possible to convert the light into an electrical signal. Said calibration device further comprises means for comparing 14 the wavelengths emitted by the screen with the wavelengths of the etalon and means for adjusting the wavelengths emitted by the screen. Wavelength comparison and parameter adjustment can be done manually by a user.

  However, advantageously, the comparison and adjustment functions of the parameters can be automated.

  Figures 2a and 2b respectively show a linear spatial separation device wavelengths and a sectional view of said device. Said separation device comprises an optical unit 20 in which is inscribed, by a holographic method, a diffraction grating operating in the Bragg regime. Advantageously, said block 20 is of elongate rectangular parallelepiped shape, of photosensitive material in the volume of which appropriate radiation can form refractive index variations by successive layers 21.1, 21.2, 21.n. These strata 21.1, 21.2, 21.n are parallel to each other and inclined relative to the longitudinal axis 22 of the block 20. The linear spatial separation device associates a position at each of the wavelengths XI, 2 ^. 2 and% n. This device is very compact and can have, for example, a LI thickness of 200 μm, a L2 depth of 200 μm and a L3 width of 2 cm. One embodiment of such a device is described in the French patent published under the reference 2,827,679.

  Advantageously, the layers may be composed by different types of materials. Said materials may for example be polymeric materials, electro-optical materials of the liquid crystal type or the like.

  FIG. 3 represents an exemplary embodiment of the device according to the invention, integrated with a light source. The spatial separation device is positioned to capture the light emitted by the light source 31. The means for capturing the emitted light advantageously comprises a waveguide 32 for guiding the light to the means for separating the light lengths. waves of said light. Said means for separating the wavelengths of said light advantageously comprise the spatial separation device 33 described above. Its spectral range is at least equivalent to the gamut of the eye (400-700nm approximately). Its resolution is equivalent or better than that of current systems (from 1 to 10nm). The means for acquiring the separate wavelengths comprises an acquisition system such as a strip 34 or CCD matrix. The means for comparing the wavelengths emitted by the light source with the wavelengths of the standard comprise an analogue counter, a microcontroller or a microprocessor according to the complexity of adjustment and the cost. The means for adjusting the wavelengths emitted by the light source include software for adjusting the parameters such as the primary colors of the light source. Such software is hosted by the system and processed by a microprocessor or microcontroller.

  The invention also relates to a display device comprising a light source and the calibration device according to the invention. Said display device may be an LCD screen for example. Figure 4 shows the functionally of an LCD screen. In an LCD, the liquid crystal 55 will change the light propagation or more exactly its polarization Eco. If an electric field is applied to them, the molecules, of elongated form, naturally arrange themselves in a parallel manner to each other. The principle of the LCD screen consists in placing liquid crystals 55 sandwiched between two plates 53, 57 etched and oriented at 90. The screen is backlit with a light 35 polarized by a vertical polarizer 52. Under the effect of a voltage applied to

  8 a control matrix 54, the crystals are gradually oriented in the direction of the electric field. The light is then blocked by a horizontal polarizer 58. Each pixel of the image consists of a cell of this type in front of which is placed a colored filter 56 red, green or blue. The spatial separation device 59 is positioned so as to capture the light emerging from the second polarizer 58. A CCD strip 50 makes it possible to acquire the separate wavelengths. The LCD screen further includes a glass layer 60 to protect the assembly.

  The invention also relates to a method for calibrating a light source. FIG. 5 represents different steps of the calibration method according to the invention. The calibration method according to the invention comprises the following steps for successively setting parameters of the emitted light: the separation of the wavelengths of the emitted light 41, the acquisition of the image of the emitted light 42, the comparison of the image with the standard 43, if the image is identical to the standard, said parameter is calibrated 45, if the image is different from the standard, the adjustment of the parameter of the light emitted by the 44 and the repetition of the wavelength separation step of the transmitted light 41.

  Adjusted parameters for a display device include: brightness, contrast and the three primary colors red, green and blue.

  Advantageously, the method according to the invention further comprises the following step: receiving the parameters of the calibration profile. The standard can be retrieved from another device to calibrate the light source. For example, the ICC profile of a printer can be used to calibrate an LCD screen.

  For the calibration of an LCD screen, it is possible, for example, to successively adjust the three colors red, green and blue. In general, the standard then takes the form of a reference, white. The method according to the invention applied to the calibration of a color then comprises the following steps: the separation of the wavelengths of the light emitted by the screen, the acquisition of the total spectrum (of the white), the comparison of the spectrum acquired with the white of reference, if the acquired spectrum is identical to the white of reference the screen is calibrated, if the acquired spectrum is different from the white of reference, ~ o the adjustment of the RGB colors of the screen and the repetition of the calibration process from the step of separating the wavelengths of the light emitted by the screen.

Claims (12)

  A device for calibrating a light source according to a standard comprising a reference optical spectrum, comprising: means for capturing (11) the light emitted by the light source; means for separating (12) the spectrum of the captured light, means for acquiring (13) the separated spectrum, means for comparing (14) the spectrum emitted by the light source with the reference spectrum, means for adjusting (15) the spectrum emitted by the source ~ o bright, characterized in that the means for separating (12) the wavelengths of the captured light comprise an optical block in the volume of which is formed a holographic diffraction grating. 15   2. Calibration device for a light source according to a standard according to claim 1, characterized in that the optical block (20) is of rectangular parallelepipedal shape and comprises strata (21.1), (21.2), (21 .n) successive having index variations, said strata being parallel to each other and being inclined with respect to the longitudinal axis (22) of the block.   3. Calibration device for a light source according to a standard according to claim 2, characterized in that said strata (21.1), (21.2), (21.n) are formed of polymeric materials or electro-magnetic materials. optics of the liquid crystal type.   4. Calibration device according to one of claims 1 to 3, characterized in that the spatial separation of the spectrum of the captured light, made by the optical block (20), is linear.   5. Calibration device according to one of claims 1 to 4, characterized in that it comprises means (14) automatic for comparing the spectrum emitted by the light source to the reference spectrum. 30 11   6. Calibration device according to one of claims 1 to 5, characterized in that the means (15) automatic to adjust the spectrum emitted by the light source.   7. Calibration device according to one of claims 1 to 6, characterized in that the means for capturing (11) the light emitted by the light source comprises a waveguide.   8. Calibration device according to one of claims 1 to 7, characterized in that the means for acquiring (13) the separate wavelengths include electronic optical conversion system, including a CMOS sensor, a CCD array or a matrix CCD.   9. Calibration device according to one of claims 1 to 8, characterized in that the standard is in the form of a calibration profile.   10. Display device comprising a light source, characterized in that it comprises the calibration device according to one of claims 1 to 9. 20   11. A method of calibrating a light source implementing the calibration device according to one of claims 1 to 9, characterized in that the calibration of a parameter of the light emitted by the light source comprises the following steps: Separating the spectrum of the emitted light (41), acquiring the image of the emitted light (42), comparing the image with the standard (43), if the image is identical to the image the calibrated parameter (45), if the image is different from the standard, the adjustment of the parameter of the light emitted by the screen (44) and the repetition of the step of separating the spectrum of the the light emitted (41).   12. A method of calibrating a light source according to claim 11, characterized in that it further comprises the step of: receiving the parameters of the calibration profile.