SU1094018A1 - Device for electromagnetic photographic recording - Google Patents

Abstract

DEVICE FOR ELECTROMAGNETIC PHOTO RECORDING, containing an optical conversion unit, information recording unit on a magnetic disk, kinematically connected to a magnetic disk drive unit and electrically connected to an electrical signal recording unit, characterized in that it has an optical raster splitter to improve the quality of photo recording. , semiconductor image converters located along the edges of optical fibers of an optical splitter, and blocks of formations of color difference signals from In this case, the outputs of semiconductor image converters are connected to the first inputs of the corresponding blocks of forming color-differentiated image signals, the second inputs of which are connected to the control of the magnetic disk drive block, the outputs of the blocks of forming color-difference image signals are connected to the inputs of the electric recorder§ optical signals, the optical conversion unit being optically interconnected with the optical raster splitter. About with i4i

Description

The invention relates to devices for electromagnetic photographic recording and can be used to register an image on a magnetic medium. A device for an electromagnetic photo recording is known, comprising an optical conversion unit, a recording unit on a magnetic disk, kinematically connected to a magnetic disk drive unit and electrically connected to a recording unit. Electrical signals C3 The disadvantage of the known device is the low quality of the photo recording. The aim of the invention is to improve the quality of photo recordings. This goal is achieved by the fact that a device for electromagnetically recordings containing an optical conversion unit, an information recording unit on a magnetic disk, kinematically connected to a magnetic disk drive unit and electrically connected to an electrical signal recording unit has an optical raster splitter, semiconductor image converters or, located along the edges of the optical fibers of the optical splitter, and blocks for colouration of the color signals of the image signals, while the outputs are semi The water image converters are connected to the first inputs of the corresponding color image forming units, the second inputs of which are connected to the output control of the disk drive unit, the output of the color separation image forming units are connected to the inputs of the electric signal unit, and the unit optical conversions are optically interconnected with an optical raster splitter. The drawing shows a block diagram of the proposed device. The device consists of a shooting lens 1, a semitransparent mirror 2, a viewfinder 3, a fiber optic raster coupler 4, semiconductor image converters 5, blocks 6 for forming color difference image signals, a block for recording electrical signals consisting of nodes 7 for recording electrical signals. The device also has a magnetic disk 8, a drive 9 and a control unit 10. The optical conversion unit has a shooting lens 1, a semitransparent mirror 2 and a viewfinder 3. The magnetic disk drive unit contains a drive 9 and a control unit 10, the outputs of the semiconductor image converters 5 are connected to the first inputs of the corresponding color difference signals 6, the second inputs of which are connected to the control output of the magnetic disk drive unit, the outputs of the color-forming units 6 of the image signals are connected to the inputs of the recording unit electrically signals, the optical block transformations optically coupled relationship an optical splitter 4. The apparatus rastrovm sleduk CIM works properly. With the help of a shooting lens 1, a translucent mirror 2 on the combined surface of the fiber coupler 4, which determines the resulting image format during its registration, and in the viewfinder 3 two identical images of the objects to which the device is aimed are formed. Through the viewfinder 3, a visual assessment of the plot of the image, the contrast between the objects and the background, and the quality of focusing are made. The combined surface of the splitter 4 is spatially aligned with the focal plane of the shooting lens 1. The splitter 4 is an optical element; it divides the image into equal parts (cells), for example, into 4 equal parts. With its help, the selected part of the image is transferred to the given space Kakfb. Splitter 4 is assembled from flexible fiber regular bundles. The harness windows are combined into a common aperture plane, and their rear windows are combined directly with the photosensitive areas of the image projection, for example, the transducer matrix of the transducers 5. The diameter of the fibers in the harness is smaller than the size of the photosensitive element of the matrices. Taking into account that the average size of the photosensitive elements of large-format matrices with the number of elements 576x360 achieved by the present time is 24x24 µm, the required diameter of the fibers in the bundles should be 12 µm or less. The current image projection area in the large-format matrixes of the transducers 5 has a size of 8x12 mm. Consequently, the full format of the image recorded with this camera will be 16x24 mm. The connection of the windows of the harnesses in one plane is made by grinding the sides of the harnesses at a short distance from the surface of the window, joining and mechanical tightening along the perimeter of the combined surface. After the tie, the aperture surface of the fibers of the raster splitter is finally ground. When using, for example, a set of large-format matrixes of converters 5 with the number of elements 576x360. And four cell raster splitters 4, the total number of decomposition elements of the optical image is 1152x270. With so many elements, the clarity of the color image on the TV screen is 504 LINE. and a print size of 82x107 mm obtained with a printing device is 1008 phone lines / 107 mm, 10 phone lines / mm or 5 mm photographic resolution. The fabrication of a single-chip transducer matrix with an image decomposition number of 1152x720 is a complex and expensive technological task. Reducing the size of photosensitive elements or increasing the format of matrices leads to a significant effect of surface defects of the semiconductor crystal on the performance characteristics of the products. The yield of matrices decreases dramatically. Many photocells become insensitive to light flux. Moreover, such super-large matrices require special cooling due to the increased power of the scattering and require either a large storage time of the charge or a higher frequency of the readout signals. Considering that the maximal storage time of the charge currently implemented is 8–20 ms, the required frequency of the readout signals for the extra large matrix will be: 3 / 1152x720 // 2 ”10 -126x MHz. Such a reading speed is almost impossible to ensure. The spatial combination of large-format matrices of transducers 5 into a single photosensitive plane is also directly impossible due to the presence in each of them of a large number of auxiliary elements located along the perimeter of the photosensitive area of image projection and the complexity of the operation of coupling the matrices with optical precision. The use of fiber raster splitter 4 in the device is the most rational solution to the problem of increasing its resolution. When synchronous and parallel video signals are generated by the matrixes of the .5 converters, the frequency of the read signals is not required. The thermal mode of operation of spatially separated matrices is facilitated, and therefore their special cooling is not required. The video signals developed by the matrixes of the transducers 5 are simultaneously fed to the corresponding inputs of blocks 6. In blocks 6 they produce, with the formation of color-difference image signals and luminance signals. At the same time reddish green, blue color components of the decomposition of the image. According to the signal of the node 10, which is fed to the combined second inputs of the blocks 6, they are controlled and the matrices of the transducers 5 are controlled. For the duration of this signal, 5 corresponding parts of the image are exposed in the transducer matrix in the range of shutter speeds 0.5–20 ms and conversion of readable video signals to color and luminance signals. The specified range of shutter speeds in the device is provided by automatically adjusting the accumulation time of charges in the photosensitive elements, depending on the magnitude of the average illuminance of the image. A signal proportional to the average illumination is formed from the video signal of the image. The adjustment of S10 ka is carried out in each matrix independently of the others. When the device is operated as a video camera, when continuous, frame-by-frame shooting of objects is carried out, a signal is sent from node 10, at which the color difference signals and the luminance signal at the outputs of the TV blocks appear periodic with a 50 Hz repetition rate. In this case, they are fed either to a color television to reproduce images on the screen, or to a color video recorder recording unit in which they are recorded onto a magnetic tape. When the device acts as a camera from node 10, another signal is given, at which the color and luminance signals at the outputs of blonts 6 appear either at a repetition rate of 10 Hz or in single frames. These signals go on to the corresponding inputs of the nodes. They convert signals into frequency-modulated signals at the corresponding subcarrier frequencies. The frequency-modulated color and luminance signals thus obtained are then recorded with the aid of electromagnetic heads on the four tracks of the magnetic disk 8. The magnetic disk is controlled by the drive 9. The drive is controlled by signals from node 10 that are synchronized with the control signals supplied to the blocks 6. The total number of images recorded by the electromagnetic device is equal to T2. The advantage of the proposed device is to obtain almost twice the resolution when using already. developed and manufactured serially matrix converters, which makes it possible to get good quality prints. The use of the invention improves the quality of the photo recording.

Claims (1)

DEVICE FOR ELECTROMAGNETIC PHOTO RECORDING, comprising an optical conversion unit, an information recording unit on a magnetic disk kinematically connected to a magnetic disk drive unit and electrically connected to an electric signal recording unit, characterized in that, in order to improve the quality of the photo recording, it has an optical raster branch semiconductor image converters located at the edges of the optical splitter optical fibers, th blocks of the formation of color-difference image signals I, while the outputs of the semiconductor image converters are connected to the first inputs of the corresponding blocks for generating color-difference image signals, the second inputs of which are connected to the control output of the drive unit of the magnetic disk, the outputs of the blocks for generating color-difference image signals are connected to the inputs of the recording block of electrical signals, and the optical conversion unit is optically interconnected with an optical raster splitter.