SU1037290A1 - Device for optical electronic scanning of color images on specimens - Google Patents

Abstract

1. DEVICE FOR OPTOELECTRONIC SCAN OF COLOR IMAGES ON SAMPLES, In particular color graphic images on flat samples in reflected or transmitted light, containing a light source, and from the receiver side a photoelectric converter with one light-sensitive element with a wavelength of light, an amplifier and a signal quantization circuit with at least two bands, characterized in that the light source has a frequency spectrum in the light wavelength range of selected colors in, and a light-sensitive element in the visible light range has a nearly linear dependence of sensitivity on the wavelength of light. 2. The device is in accordance with claim 1, which is due to the fact that in the course of the rays from the light source to the photoelectric converter there is an optical broadband filter with a bandwidth in the range of light wavelengths of selected colors. (L 3. The device according to claim 2, which is based on the fact that the optical wideband filter is contained in the sample.

Description

The invention relates to automation and computing, and specifically to devices for. Optoelectronic scanning in reflected or transmitted light for recognizing graphic information in black-and-white and in selected colors on specimens but not used for character recognition and image processing, for example, when scanning images captured in printed products, drawings, on films textile products x. The method of photoelectric scanning of black-and-white information and distinguishing them from each other depending on the amplitude values is known. In the presence of color information, the same type of sensitive elements correspond to the choice of colors. Due to the different included, at the input of the device monochromatic filters, each of the sensitive elements perceives only a certain one. part of the color. The output signals of all sensitive elements in their. . aggregates represent information about the colors of characters or images. In this method, the optical display of color information on sensitive elements is produced using diffuse light. Optical mapping can be transmitted through a fiber or by splitting a beam. In such solutions, the cost of scrolling from color samples is very high, since several chromaticity channels are required with appropriate technical means. ; . Solutions are known that involve one photosensitive element of the image, which in the course of the rays have a filter of color bands. This achieves the fact that the narrow segments of the surface of the sensing element have a selective sensitivity to different colors. An additionally limited bandwidth resolution, in particular for. The color information / does not reach those values that the scan provides with the help of several SENSITIVE elements. It is also known a device in which the acquisition of color parameter signals from black and white signals is provided by means of a television tube. A similar signal, outputted by the receiver and dependent on luminosity, with the help of threshold elements, is divided into several ranges of levels that can be captured or adjusted by the degree of color saturation. This device only allows grayscale color scores. It is not suitable for recognizing colors from color samples and correctly distributing them to the processing channels. To scan graphic information in black-and-white and select colors on flat samples, a device must be created that provides. At low cost for sensitive elements, high resolution. And allowing for mutually ambiguous color matching in the assessment. . The basis of the invention is to ensure the recognition of selected colors at low cost. . . . The goal is achieved in an optoelectronic device. scanning of color graphic information on flat samples in reflected or transmitted light containing a light source, and from the receiver side a photoelectric converter, video amplifier and a signal quantization circuit, a photosensitive element with a photoelectric transducer is used, depending on The wavelength of light is sensitive to the sweep-information in selected colors with a high degree of saturation, and the signal quantization scheme consists of threshold stages, the number of which is equal to the number of differences. x selected sample of colors inclusive of white. Lrie this sensitive element c. The visible range of light has an almost direct dependence of the sensitivity, of the wavelength of the light on the LENGTH. Thus, in the course of the rays of the light source to the photoelectric transducer, the broadband filter with a width of a polo can be located in the region of selected light waves, which can also be located on the sample itself. Instead of using optical broadband fi.titter, you can use a light source with a frequency spectrum in the region of the chosen length of the field. The output signal of the photosensitive element used is is, with a function of the wavelength of the light. In addition, there may also be a dependence on illumination. As the graphic information to be developed. have a high degree of saturation in black-and-white and in selected colors, the dependence on a wavelength is predominant and allows for the evaluation of colors. Selected colors are assigned a non-overlapping amplitude range of the video signal. The highest range of amplitudes refers to white, and the lowest to black. After quantization of a video signal into digital signals, information is stored relative to the original colors, since one amplitude range is one-to-one corresponds to one quantization value. - An important advantage of the invention, along with a one-to-one correspondence between colors, is a small expenditure on the elements and a high allocation capacity of colors. Color information on samples with a black and white mark can be deployed in reflected or transmitted light using a black and white pattern. FIG. i shows a sweep diagram; FIG. 2 shows a spectral characteristic of a silicon photosensitive member, FIG. 3, an example of a sample with graphic information, in FIG. 4 - video signal of the photosensitive element. FIG. 1 shows sample 1, light source 2, lens 3, line sensing element 4 with the corresponding control circuit 5. Video sensor 6 is located at the photosensitive element 4 and analog-to-digital converter. In the course of the light source 2, near infrared sample 1 is arranged infrared. fil.tr 8. The photosensitive element 4 is made in the form of a silicon semiconductor wafer. FIG. The typical spectral characteristic of such an element is shown; The dependence of sensitivity on the wavelength L. On . 3 shows an enlarged sample .1 with graphic information on. white baseNII 10. The information consists of one black stroke 11. and color strokes -12 and 13, and the wavelengths of the color of the stroke 13 are less than the length of the color of the stroke .12, -Information is applied with ink .-. Sample 1 is equipped with source 2. Sveta. By lens 3, part of sample 1 is sharply directed at the line-level photosensitive element 4, Since this photosensitive element eblade high sensitivity and in the infrared range-e {Fig. 2) the non-essential infrared components that are partially reflected from the sample 1 are filtered out by the infrared filter 8. This restricts to the visible, the range of light in which the spectral characteristics (Fig. 2) are almost linear. For the operation of the device, the infrared filter 8 is not required A restriction to a certain range of light can be created by the same source of light 2 or sample 1, or disappear altogether. In the photosensitive element 4, the optical information is converted into an electrical signal, which is amplified by the video amplifier 6. The developable band 14 can lie across the lines 11, 12 .and 13.. FIG. 4 shows the video signal 24 received from the strip 14 to the output of the video amplifier 6. The video signal 24 received from the white base 10 is set to a range of 20, which corresponds. 100% amplitude. The black bar 11 reflects the radiation. Less than all the waves and causes a signal corresponding to the range 21 with zero amplitude. For color bar 12, the amplitude is in the range of 22, and for color bar 13, the amplitude is in the range 23. Since the colors have different wavelengths, they are assigned different amplitude ranges based on the spectral characteristics of the photosensitive element 4. Ranges 25 are dividing ranges that should not include a color signal. This is achieved due to the high degree of saturation of the color graphic information. The video signal 24 thus obtained is converted by an analog-to-digital converter 7 into a binary signal, which is assigned to the corresponding channel of the color signal and which can be subsequently processed. For this. Analog-to-digital converter 7- consists of three: threshold stages, which operate, as soon as the appropriate amplitude range of voltage or current 23, 22 or 20 is reached. As threshold stages, three threshold switches can be switched in parallel with different thresholds. However, the threshold switch can be also used multiple times in a circuit in 1 {combination with subtraction circuits. The threshold stages in this case are allocated by the corresponding logic circuit. . It is recognized as an invention according to the results of the examination carried out by the Office for the Invention of the German Democratic Republic.

eleven

fig.Z

/ J

Claims (3)

1. DEVICE FOR OPTOELECTRONIC SCAN OF COLOR IMAGES ON SAMPLES, in particular color graphic images on flat samples in reflected or transmitted light, containing a light source, and on the receiver side - a photoelectric converter with one photosensitive element with a sensitivity depending on the wavelength of light, an amplifier and a scheme for quantizing a signal with at least two ranges, characterized in that the light source has a frequency spectrum in the range of light wavelengths of selected colors, and The sensitive element in the visible range of light has an almost linear dependence of sensitivity on the wavelength of light. 2. Device-by π. 1, characterized in that during the rays from the light source to the photovoltaic converter, an optical broadband filter with a bandwidth in the range of light wavelengths of selected colors is located. 3. The device according to claim 2, characterized in that the optical broadband filter is contained in the sample. FIG 1>