SU1026110A1 - Device for recording cinema picture on cinema film - Google Patents

Abstract

DEVICE FOR RECORDING A FILM IMAGE ON A FILM, containing red, blue and green lasers, in optical start-ups of which light modulators, collimators, a dichroic mirror system, a mirror scanner, a printing node containing a film channel for negative and positive are arranged. The automatic tension control system of the negative and positive, the first input of which is connected to the tension sensor of the negative and positive, and the second input is the output of synchronous generators, a block of exponential converters, while the mirror scanner is installed on the axis of the first synchronous electric drive the scanner, to the first input of which the scanner’s feedback sensor is connected, and to the second - the output of the synchronous generator, transporting the drum, associated with the film to analogue and mounted on the axis of the second synchronous electric drive connected to the output of the automatic control system by continuous transportation, to the first input of which a feedback sensor is mounted on the axis of the transporting drum, and to the second input is the output of the synchro-generator, the second system of dichroic mirrors mounted above a print unit that is optically matched with it and with a book of three photodetectors, the outputs of which are connected to the inputs of a block of three logarithms, and the codes of the correction unit and The image processing and the feedback amplifier unit are also connected to the output of the synchro generator, in order to improve the quality of the movie image, its completeness and reliability of its decoding, to obtain element-corrected color image with given gradation, color and frequency-contrast characteristics, it is introduced by the | light fixtures, additional modules - light tori, additional collimators, block of interchangeable diaphragms, the first and (L second additional systems of dichrotic mirrors al, additional zerkl .ny scanner, optional synchronous electric, additional. an automatic adjustment system, an additional feedback sensor, a block of three reference photos, receivers, a photogenerator of a sigHVO brightness, a first and a second additional logarifmators, an additional block of three logarifmators, a cube-dividing cube, a large-scale photodetector of a scan, an analog block subtractors, the first and second blocks of video signal binding on the white level, an additional amplifier. Feedback, an additional exponential converter, while the light splitters are set lasers at the laser outputs and optically coupled with the main modulators and additional modulators, behind which additional collimators and the first additional system of dichroic mirrors are sequentially located, and a block of interchangeable diaphragms is installed at the outputs of the main and additional collimators, and the outputs

Description

the main and first additional systems of dichroic mirrors are optically conjugated through the respective first and second optical forming systems with primary and secondary mirror scanners, each optical forming system being made in the form of a telescopic three-lens system with a mirror trihedral isosceles prism inside, in which the first and third lenses are aligned; and the optical axis of the second lens is perpendicular to their optical axis, with the rear focus of the first objec- tive located at the intersection of the axes, the front focus of the second and third lenses and the top of the mirror isosceles trihedral prism, the base of which is parallel to the optical axis of the first and third lenses and the axis of rotation of the mirror scanner, in the middle of the radius of which, in front of the axis of its rotation, is the back focus of the second lens, and the optical axes of the third lenses of the first and second optical images mutually perpendicular systems and at the point of intersection there are their rear foci, the center of the beam-splitting cube and the front focus of the first lens of the input optical forming system, made in the form of a two-objective telescope, the back focus of the second lens is located in the print unit and is aligned with the front focus the first lens of the third optical system forming it, made in the form of a two-lens telescope, and a reflecting mirror located on the optical axis of the systems for the first lens and an angle of 45 ° to the optical axis and optically associated with the second primary input system of dichroic mirrors, wherein optical axes forming three optical systems and optical output forming system are arranged in one plane, and the additional

the mirror scanner is installed on the axis of an additional synchronous electric drive connected to the output of an additional automatic control system, to the first input of which the output of the synchronous generator is connected to the second - the output of the additional feedback sensor, and to the third - the output of the feedback sensor of the main mirror scanner, while the main and additional mirror scanners are optically coupled through the corresponding first and second optical optic shaping systems | beam splitting cube, the output optical A forming unit with a print unit, and through the beam-splitting cube and the second additional system of dichroic mirrors, are optically coupled to the inputs of the reference photodiode of the luminance signal and a block of three reference photoreceivers, the outputs of which are connected to the first inputs through the logarithm of the luminance signal and an additional block of the three logarifmators. block analog subtractors, to the second inputs of which are connected the outputs of the main block of logifiers and through the second additional logarithm - the output of the photodetector of a large n n scanned optically coupled through the third optical system to a print unit, which through it is optically coupled to the second main system of dichroic mirrors, and the outputs of the analog subtractor unit are connected to the inputs of the processing and image correction unit, one of the outputs of which is connected through serially connected additional feedback amplifier, additional exponential converter, additional video amplifier, the second block of video signal level white connection to the inputs additional light modulators, and the outputs of the main light modules are connected to the outputs of the first block of the video signal in terms of the white level connected to the outputs of the video amplifier unit.

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The invention relates to cinematography, in particular, to reproduction devices for film materials.

Known continuous copy contact printing machine,. comprising a thermal light source, an optical system, an exposure control mechanism, a film continuous transport mechanism, a contact printing unit,

Printing in such a device is carried out over the entire field of the frame by an optical beam of light, on the way of which corrective color light filters are installed, which control the exposure control mechanism 1.  The disadvantage of such kinopirov. The low speed of the exposure controllers, which drastically reduces the productivity of the device, and also does not allow element-by-film correction of the image in the printing process, resulting in a sharp decrease in the quality of the screen image and the quality of its de-diffraction.  The closest in technical C5 value to the present invention is a device for recording a film image.  and laser film sources: a kilogram of light, with a tendency to grow, green and green lasers, in the Optical Pups of which light modulators, collimators are a system of dichrases: mirror mirrors, a mirror scanner, a printing unit, containing a movie channel for negative and positive, the system of automatic control of the negative and positive tension by tension / to the first input of which the negative tension sensor is connected, and cctivating a, and to the second - the output of the synchro-generator, the block of exponential conditions 1Tele1, ny Jskaner mounted on the axis of the synchronous motor drive connected to the output of the automatic regulirbvani scanner to the first input connected kotorod feedback scanner sensor, and to a toromu - the output clock conveying drum associated with movie channels and; mounted on a synchronous axis: an electrically-prone water connected to the output of the automatic control system by continuous transportation by transportation to the first input of which is connected a feedback sensor mounted on the axis of the transporting drum, and to the second input - the output of the synchro-generator, and the second system of dichroic mirrors mounted above print unit, optically coupled to it, and c.  The blocks of three photodetectors, the outputs of which are connected to the inputs of the block of -tpex logarithmors, and the inputs of the image correction and processing unit and the feedback amplifier unit are also connected to the output of the sync generator t2. .  The disadvantage of the device is that it does not provide NIN with a leveled corrected film image with predetermined frequency characteristics in the process of recording and printing.  The purpose of the invention is to improve the quality of the film image, the completeness and reliability of its Decryption, to obtain an element-wise corrected color image with given gradient, color and frequency characteristics.  This goal is achieved by the fact that in a device for recording a film image onto a film containing Red, Blue and Green lasers, in optical starts, which are successively arranged light modulators. , collimators, a system of dichroic mirrors, a mirror scanner, a printing unit containing a film channel for negative and positive, an automatic control system for tensioning the negative and positive, the first input of which is connected to the tension sensor of the negative and positive, and the second output of the sync generators, an exponential sensor converters, while the mirror scanner is installed on the axis of the first synchronous electric drive connected to the output of the automatic control system by the scanner / to the first input of which the scanner feedback sensor, and to the second, the output of the synchro generator, transporting the sadia drum connected to the movie channel and installed on the axis of the second synchronous electric drive connected to the output of the automatic control system by Continuous transportation, to.  The first input of which is connected to a feedback sensor mounted on the axle of the transport of the right drum, and to the second input is the output of a synchronous generator, the second system of dichroic mirrors mounted above the print assembly optically coupled to it and to 6Jiok from three photodetectors, the output of which is connected to the inputs of the block of three log arithms, and the inputs of the correction block. and image processing and a feedback amplifier unit are also connected — to the output of the sync generator, additional light splitters.  Light modulators, additional collimators, interchangeable diaphragm block, first and second additional systems of dichroic mirrors, additional mirror scanner, additional synchronous electric drive, additional automatic control system, additional communication sensor, block of three reference photo detectors, reference photodetector SI brightness. , the first and second to-; PLEASE. solid logarithmors, an additional block of three logarithmics, a dyed cube, a large-scale scanning photodetector, a block of intelligent diggers, the first and. the second block of the video signal level is white, an additional feedback amplifier, an additional functional converter, with this (the light is mounted on the B-input of the Lasers and.  optically coupled to the main modulators and additional modulators, for which additional collimators and the first additional system of dichroic mirrors are sequentially located, and the block of interchangeable diaphragms is installed at the main and additional outputs.  collimators, and the outputs of the main and first additional systems of dichroic mirrors are optically conjugated through the corresponding.  introduced first and second optically.  The system is formatted with a primary and secondary mirror scanner, each being optically formed.  The system is designed as a three-objective telescopic system with a mirror trihedral isosceles prism inside, in which the first and third objectives are aligned, and the optical axis of the second object is perpendicular to their optical axis, and in. the intersection point of the axes is the back focus of the first lens, the front focus of the second and third lenses and the top of the mirror isosceles trihedral prism, the base of which is parallel to the optical axis of the first and third lenses and the axis of the axis of the mirror scanner, in the middle of the radius of which the back focus is located in front of the axis of its rotation the second lens, and the optical axes of the third lenses of the first and second optical forming systems are mutually perpendicular and at the intersection of them are their back focus The center of the beam-splitting Kubik and the front focus of the first lens of the introduced optical fs system of the Migrudium system, made in the form of a two-objective telescope, the back focus of Volts, the lens of which is located in the print unit and combined with the front lens of the first Lens introduced by the third optical system in the form of a two-lens telescope, and a reflecting mirror located on the optical axis of the system behind the first lens and at an angle of 45 to the optical axis of the system and optically connected to the input of the main system themes of dichroic mirrors, while the optical centers of the optical Forming systems and the output optical formors of the system are located in the same plane, and the additional mirror scanner is installed on the axis of the additional synchronous elec- tro.  the drive connected to the output of the additional automatic control system, to the first input of which is connected to the synchronous generator, to the second output of the additional feedback sensor / and to it - the output of the feedback sensor of the main mirror scanner / jri.  This updated and additional mirror scanners are optically conjugated through the respective first and second optical systems, the beam splitting cube, the output optical forming system with the print unit, and through the beam splitting cube and the SECOND additional system of dichroic mirrors are optically conjugated to the inputs of the reference photodetector of the signal and a block of three reference | photodetectors, a photodetector of a luminance signal and a block of three reference photodetectors, the outputs of which are through a logarithm of a luminance signal and an additional block of three logifiers is connected to the first inputs of the analogue charge generator unit, to the second inputs f of which the outputs of the main block of logifiers are connected, and through the second additional logarithmizer - the output of a large spot scanning photoreceiver optically coupled through a third optical forming system with a print node, which through it is optically coupled with the second main system of Dichroic mirrors, and the outputs of the block of analog subtractors are connected to the inputs of the processing and image correction unit, One of the outputs of the outputs is through a serially connected additional feedback amplifier, an additional exponential converter, an additional video amplifier, a second video signal binding unit at the white level connected to the inputs of additional light modulators, and the outputs of the first video signal binding unit connected to the inputs of the main light modulators on the white level connected to the outputs of the video amplifier unit.  FIG.  1 shows a functional diagram of a device for recording a film image onto a film by laser light sources; in fig.  2 shows the principal optical design of the first, (second) optical forming system; in fig.  3 is a functional diagram of the Optical system of a recording and printing device; in fig.  4 is a basic optical diagram of the optical system of the device.  .  The device contains lasers 1, light splitters 2, additional light modulators 3, light modulators 4, collimators 5, additional collimators b, the first system of 7 dichroic mirrors, an additional system of 8 dichroic mirrors, the first 9 optical forming system, BTOPSTO optical system 10, beam splitting; cube 11, mirror scanner 12, synchronous electric drive 13 of mirror scanner 12, automatic control system 14 with a mirror scanner 12, mirror scanner 12 feedback sensor 15 / additional mirror scanner 16 j additional synchronous electric drive 17 of additional scanner 16, automatic control system 18 automatic an additional scanner 16, a feedback sensor 19 an additional scanner 16, a second additional system 20 dichroic mirrors a reference luminance photoreceiver 21, a logarithm p 22 signals of viscosity, block 23 of three reference photodetectors, block 24 of three additional logifiers.  The output optical forming system 25 / automatic control system 26, synchronous electric drive 27 by continuous transportation, continuous transport feedback sensor 28, negative 29, positive 30, automatic tension control system 31 and negative 30, 30, print unit 32, sensor 33, tension of negative 29 and positive 30, propelling of drum 34, third optical forming system 35, second system 36 dichroic mirrors, block 37 photo detectors, block 38 of the riffmator log, large photosensor 39 animation, second additional logarithm 40, block 41 analog subtractors, block 42 processing and image correction, block 43 of feedback amplifiers, block 44 of exponential transducers, block 45 of video amplifiers, first block 46 of binding video signals by the white level, additional amplifier 47 feedback, additional exponential transducer 48, additional video amplifier 49, sync generator 50, block 51 of interchangeable diaphragms, second block 52 of signal binding at the white level, first lens 53 (Fig.  2 and 3), the second lens 54, the third lens 55, a three-sided isosceles mirror prism 56, the first and second optical forming system 9 and Yu, the first lens 57, the deaf mirror 58, the integrating lens 59, the third optical forming system 55, the first lens 60 , the second (output) lens 61 of the output optical signaling system 25.  In optical launches of lasers 1 (FIG.  1} light splitters 2 are installed, the outputs of which are optically coupled: first through modulators 4, collimators 5, interchangeable diaphragms of block 51, first system 7 of dichroic mirrors, first optical forming system 9 consisting of three objectives 53-55 and a trihedral isosceles mirror pridma 56 (FIG.  2, FIG.  3) with a mirror scanner 12, which is mounted on the synchronous shaft of the south electric drive 13 connected to the output of the automatic control system 14 by the mirror scanner 12, to the first output of which is connected a feedback sensor 15 mounted on the mirror scanner 12, and to the second output - output synchronization generator 50, the second through additional modulators 3 lights, additional collimators 6, the first additional system 8 dichroic mirrors, the second optical forming system 10 consisting of three lenses 53-55 and triangular mirrors This is equal to the femoral prism 56 (FIG.  2 and 3) with an additional mirror scanner 16 mounted on the shaft of the additional synchronous electric drive 17 connected to the output of the additional automatic control system 18, to the first input of which is connected to the additional feedback sensor 19 installed on the additional scanner 16.  to the second output - the output of the sync generator 50; to the third - the output of the feedback sensor 15 of the mirror scanner 12.  The outputs of the first 9 and second 10 optical systems of the optical systems are optically coupled to the beam-splitting cube 11, which is optically connected through the output optical form-forming system 25 to the print unit 32, in which negative 29 and positive 30 are in contact on the transport drum 34.  The optical forming systems 9 and 10 are identical and consist of three lenses 53-55 (Fig.  2 and 3) and a three-sided isosceles mirror prism 56, and the lenses 54 are located coaxially along the O-axis.  2), and the optical axis OzO4 of lens 55 perpendicular to their optical axis OO2, at the intersection point of the optical axes O Oj and O-jO of lenses 53-55 is the top of a three-sided isosceles reflecting prism 56, the vertex to the lens 56, and mirror edges symmetrical to lenses 53 and 54 and at the same angle to their optical axis.  At the intersection point of the optical axes, there is also a back focus of the lens 53, and the front focuses of the lenses 54 and 55.  A prism 56 at the apex (lower edge, FIG.  2) is located symmetrically and symmetrically to the plane formed by the intersection of the optical axes and OjO lenses 53-55, and the symmetric Oj-O is rotated and perpendicular to the axis of the mirror scanner 12 (16) (Fig.  2 and 3), with the focus of the lens 55 located in the middle of the radius of the mirror scanner 12 and in front of its axis of rotation.  Optical forming system 10 is constructed similarly.  The back focus of the output lenses 54 of both optical forming systems 9 and 10, made in the form of three-objective telescopes, is located in the center of the beam-splitting cube 11, at the intersection point of the optics.  chesus axes and OjOg (fig.  3) and coincides with the focal focus of the first lens 60 of the output optical forming system 25, made in the form of the Dual-Objective Telescope (lenses 60 and 61), and the back focus of the second (output) lens 61 of the system 2 & located in the print assembly 32 (pyOg axis) in the plane of the emulsion layers (not by. cauldrons) of negative 29 and positive 30 (FIG.  1 and 2), here is the front focus of the first lens 57 of the third optical forming system 35, made in the form of a double-lined telescope (lenses 57 and 59) and a deaf mirror 58, located behind the first lens 57 at an angle of the optical axis and in close proximity to the rear surfaces first Oh lenses 57.  Optical axis.  0.04 Qc) O, j O,% O (is in the same plane, and the deaf mirror 58 is optically connected to the input of the second system 36 of binary mirrors and is at the intersection point of the 0, iOi3 and OyO axes and at an angle of 45 ° to them.  The transporting drum 34 is mounted on the axis of the synchronous electric drive 27 connected to the output of the automatic control system 26 by continuous transportation to the first input of which is connected a feedback sensor 28 mounted on the shaft (not shown) of the transporting drum 34, and to the second input - output Synhrogeneratra 50.  Tension negative 29 and positive 30. The print unit 32 is controlled by an automatic tension control system 31, with a sensor connected to the first input: 33 tensioning the negative 29 and positive 30, and to the second - the output of the synchro-generator 50.  The second output of the beam-splitting cube 11 is optically coupled (axis 0.62) through the second additional system 20 Dichroic mirrors with the input of the reference photo detector 21 and the luminance signal and with the input of the unit 23 of the three reference photodetectors.  The outputs of blocks 21 and 23 of photo-detectors NIKOV through blocks 22 and 24 of logifiers are connected to the first inputs of 41 analog outputs, to whose second inputs are connected via block 38 of logarifmators, the outputs of block 37 of photoretectors, whose inputs are optically connected to negative 29 and positive, 30 through the second system 36 dykhroichnyh: mirrors and the third. optical formation system 35, and through the second before.  Complementary logarithm 49 is connected.  a large scanning spot photodetector 39, the input of which is optically coupled through a third optical forming system 35 with negati. Om 29 and positive 30, on the course of Adihs s u5l “32 seals on; transport warabane 34.  The outputs of block 41 of analog readers are connected to the inputs of block 42 for processing and image correction, the outputs of which are through a sequentially switched on block 43 of feedback amplifiers, block 44 of exponential transducers, block 45 of video amplifiers, the first block 46 of video signal level-white connection to inputs modulators 4 light, and through series-connected additional amplifier 47 feedback, additional exponential converter 48, additional video amplifier 49 and the second exponential preamp The driver 52 is connected to the inputs of additional modulators 3 of the light, and the outputs of the synchronous generator 50 are also connected to the inputs of the blocks 42, 43 and 47.  A device for recording a motion picture on a film by laser light sources works as follows.   In the printing unit 3i on the teeth (not shown) of the transport drum 34, negative 29 is charged and positive 30 emulsion is applied to the emulsion.  Included are lasers 1, synchronous drives 1E, 17 and 27, automatic control systems 14 and 18, 26 and 31. .  Puch-  The ki from the outputs of the lasers 1 are fed to the inputs of a splitter 2 of light consisting of beam-splitting cubes and deaf mirrors, as a result of which three dual laser beams of three color each are obtained. per channel, in the first channel in the path of the laser beams - modulators 4 lights, collimators 5, block 51 interchangeable diaphragms, which may have a different shape from. Versty: annular, square, slotted, cruciform, etc. P.  The use of diaphragms is intended to form. Neither the S Laser Beam has a specific law of intensity distribution (it is possible to use a two-axis acousto-optic deflector) in order to carry out a more effective Frequency-Contrast Correction of the printed and recorded film image to a positive 30.  Next, the three laEner beams — the red, green, and blue of the first channel — will drop at the input of the first system of 7 dichroic mirrors / which bring together three laser beams into a three-color one.  Similarly. the second output of the splitter 2 works through additional modulators of 3 light. .  Additional collimators 6, block 51 of interchangeable diaphragms; laser beams arrive at the input of the first additional system of 8 binary mirrors.  C outlets of systems 7 and 8 of dichrillic mirrors, tricolor beams, extended collimators 1 and 5 and 6 with visible magnifications, 08, arrive at the inputs of the corresponding first and second optical forming systems 9 and 10, each of which is designed as a three-objective telescopic system with visible magnification with a mirror trihedral isosceles prism inside the system.  The prism 56 serves to introduce the optical beam onto the scanner 12 (16) with the left side and output the beam unrolled into a row with the right edge into the lens 54.  From BUBO systems 7 and 8 dichroic mirrors, optical tricolor beams with a diameter of about 22 mm enter the first lens 53, the first and second optical systems 9 and 10, which focus the beam to a point on the left mirror face of the prism 56 (Fig.  2).  The left and right sides of the prism 56 are located at an angle 4 of the optical axis () of lenses 53 and 54 and its top is located at the intersection point of the optical axes (O4 (07Og - 0 (6 (0) lenses 53-55, here are the back focus The input lens is 63, the front focus of the transition lens on the scanner is 12 (16) 55 and the front focus of the output volume is 54.  Further, the focused light beam is reflected from the left mirror face of the prism 56 and through the pass-through lens 55 enters the mirror (the wounds of the scanner 12. and an additional body scanner 16, with the optical beam covering at once two edges of the scanner.  The mirror scanner 12 (16 is a mirror prism with a diameter of 60 mm, a face height of 12 # t and a face width of about 7.5 mm, material — steel SHKh15SG, angle accuracy and pyramid 3) number of faces 25, surface frequency g14.  The rear focus of the transition lens 55 is located with the mid-radius of the mirror scanner: 12 (16).  Mirror scanner 12 (16), rotated in one direction (250 ck).  Each face captures the optical beam of light, scanning it on the line / due to the fact that the beam covers two adjacent faces of the scanner at once, in such a system there are no losses on the reverse sweep.  The row resulting from the reflection from the edges of the rotating mirror scanner 12 (16), the passage in the opposite direction through the transition lens 55, yo steps on the right side of the mirror prism 56 (the angle of incidence is equal to the angle of reflection).  The transition lens 55 focuses on the right edge of the prism 56 a line with a length of about 22 mm and a width equal to the aperture of the focused point (spot) on the left mirror edge of the prism 56.  The first optical forming system 9 will form a focused line with an aperture of about 15 microns (cutting the line forming a sharp mask), and the second optical forming system 10 will form a defocused line with an aperture of about 100-150 microns, of the first) lens 53 of the system 10, the unstripped line forms a negative 29 - positive 30 non-sharp mask in the plane, the spot value is set based on preliminary calculations - according to the Tables and graphs, and the intensity controls feedback loop on the world.  The mirror scanner 12 (16) spreads a beam of rays at an angle C of the outputs of the first and second optical FOU and in systems 9 and 10, the beams of the sharp and unsharp lines are folded by rotating the scanners 12 (16) on a 50% beam-splitting cube 11, which. separates part of the light flux to an additional (second) system of 20 dichroic mirrors.  A dual scanning beam through an output optical image sensor system 25, made in the form of a double-lens telescope with visible magnification, objectives 60 and 61 is transferred and.  It focuses the plane of the ammunition layers of negative 29 and positive 30 and produces simultaneous analysis and exposure.  the film image with two spots - sharp and unsharp.  The output of the second auxiliary system of 20 dichroic mirrors is optically coupled to the photodetectors:. with reference photodetector 21 signal | The luminance and block 23 of the three-support photodetectors, which serve to obtain the mask reference signal and the signal about the possible non-uniformity of reflection of the mirror mirror scanners 12 (16), the latter are further integrated (not shown).  The outputs of the reference photodetector 21 of the luminance signal and the unit 23 and 3 of the three reference photodetectors through the logarithmizer 22 of the luminance signal and the block 24 of the three additional logifiers, respectively, are connected to the first inputs of the block 41 of analog subtractors.  Above the print unit 32 is installed a third optical formulated system 35, coaxial with the exit. optical system 25 and made in the form of a two-lens telescope - lenses 57 and 59 and a deaf mirror 58 ,.  located behind the first lens at an angle of the optical axis In close proximity to the back surface of the first lens 57.  The projection of the blind mirror 58 onto the surface of the first prism is a circle with a radius equal to half the diameter of the first lens 57.  The deaf mirror 58 leads to the second system 36 dichroic. of the mirrors, the luminous flux of the cut (focused) scanning spot modulated by the transparency of the negative 29, and the remaining part of the luminous flux - the light ring behind the deaf mirror 58 is transferred by the second lens 59 of the system 35 to the optical input of the high-resolution photoplate 39 and from the exit of which. the signal corresponding to the brightness of a large spot or a blurred mask is removed.  A second system of 36 dichroic mirrors separates the light flux corresponding to a sharp image into monochromatic components, which are fed to the optical input of unit 37 of three photodetectors.  From the output of blocks 38, color-separated video signals (logarithmic) are removed, which are fed to the second inputs of block 41 of analog subtractors.  The use of logarithmic values with subsequent signal processing has an undoubted advantage for performing an effective electronic gradation, beam-splitting, and frequency-contrast correction on the elementally printed and recorded image (negative 29 serves as a passive light modulator and produces a positive print of the movie image on the positive 30, and signal correction modulate the luminous flux through modulators 4 and additional modulators 3, which play the role of active modulators).  In this case, simply changing the gain of logarithmic signals over a wide range can change the contrast ratio of the reproduction characteristic of the device; Conducting linear and nonlinear gradation correction of logarithmized signals allows matching the characteristics of the analyzed image with the characteristics.  visual perception under various conditions of image observation during decryption; In addition, the transformation of logarithmic signals is a necessary and sufficient condition for the elimination of the beam-splitting of the photo-photographic process; The beam-splitting and gradation masking of logarithmic signals using the four-component light correction method independently controls the contrast of achromatic and chromatic chroma, which increases the completeness and accuracy of decoding the resulting image. i The function of the analog subtractor 41 is to implement the function. I.  .  . , neg oporn oporn neg.  cd  -D Du, ft, o 3 - for blue,,, 2, green and red: channels of the analyzing system.  From the outputs of the block 41 of analog subtractors, color-separated optical density signals, proportional to the effective densities of negative 29 with respect to the photoelectric analyzing system, and the signal from a large scanning spot are fed to the input of block 4 2 of processing and image correction, which performs operations with received. by their signals.  With a linear computational matrix (not shown), block 42 compensates for the harmful side effects of positive, 30, t multilayer film dyes. e.  performs alignment of color-separated signals Dfc in accordance with densities. Negative 29 in relation to the photosensitive layers of positive 30; their difference is due to the color separation properties of both analyzing systems (a system of 26 dichroic mirrors and light-sensitive sl. oi positive 30); in the achromatic component extraction unit (not shown), a signal equal to the minimum of the three current signals is selected.  color separation which is fed to the first input of an analog subtractor (not shown), to the second input of which a signal is sent from a large scanning spot from the output of block 41, the output of which is equal to zero if photomaterials are sharp and unsharply spotted , in the places of optical density difference (fine details of the film image, contour), the steepness of the increase in the signals from the sharp and unsharp spots is different, as a result of which the signal is formed, corresponding to the second derivative of this The difference between the planes of the neighboring elements of the image elements is negative (29, which, after amplification, is summed. It comes with color-separated signals from a small (sharp) spot and serves as an Adjustable Signal from the feedback circuit and thereby realizes the frequency-contrast correction of the printed and recorded image from negative 29 to positive. 30 when using two scan points. - sharply and non-, sharply.  Further, this signal from the output of the image correction processing unit 42 is via a serially coupled feedback amplifier 47, an additional exponential converter 48, an additional video. the amplifier 49 and the second block 52 of binding the video signal according to the white level are fed to the electrical input of additional modulators 3, modulating the laser beams forming a blurred scanning spot in the plane of the emulsion layers of the negative 29. and positive 30.  In addition, the O1 unit 42 optimally coordinates the gradation characteristics of the resulting image on positive 30 with the characteristics of the visual analyzer of a torus (not shown), which improves the quality and reliability of the NII-ши exporters. , the outputs of the processing and image correction block 42 through the series-connected feedback amplifiers 43, the block 44 of exponential transducers, the block 45 of the video amplifiers, the second block 46 of video signal level-related white signal are connected to the electrical inputs of the modulators 4 lights producing the module correction signals of laser beams that form a sharp mask - a small scanning spot.  The exponential transducers of blocks 44 and 48 are designed to ensure the proportional dependence of the radiant fluxes of lasers 1 on the video signals from the blocks 43 and 47 of the feedback amplifiers.  In order to ensure synchronous and common-mode operation of the device / as well as to ensure the video signal leveling on the white level, the outputs of the clock generator 50 are connected to the terminals of blocks 42, 43, 46, 47, 52.  The control of the line mirror scanners 12 and 16 is described as follows.   The mirror scanner 12 is installed on the axis of the synchronous drive 13, which is connected to the output of the automatic control system 14 by the scanner 12, and the additional mirror scanner 16 is installed on the axis (not shown) of the additional synchronous electric drive 17 connected to the output of the additional automatic control system 18.  The first inputs of systems 14 and 18 are connected to the output of the synchro-generator 50.  The purpose of the automatic control systems 14 and 18 by the mirror scanners 12 and 16 is to stabilize the instantaneous rotational speed of the scanners — compensating for low-frequency rotations of the rotors (not shown) of synchronous electric drives 13 and 17 from the pc1Mi scan 12 and 16 on the shaft, respectively, according to the phase error signals to the synchro pulses, taken from the respective sensors 15 and 19 of the feedback of the scanners 12 and 16 and the pulse Mj received from the output of the clock generator 50.  For inter-phase operation of scanners 12 and 16, the output of the feedback sensor 15 is also connected to the input of the additional automatic control system theme 18 by the additional scanner 16.  The continuous transportation of negative 29 and positive 30 is controlled by a continuous transport system 26, the output of which is connected to a synchronous actuator 27, on a shaft (not shown) of which a transport drum 34 and a feedback sensor 28 are installed, the output of which is connected to the first input of the feedback system 26 and, to the second input, the output of the synchronous generator 50 is connected. To ensure the necessary contact between the negative 29 and the positive 30 in the printing unit 32, the automatic control system 31 pusit, to the first in ode is connected to tension sensor 33 negative 29 and positive 30 and to a second, clock input connected to the output 50.  The purpose of the system of automatic control by continuous transportation is to create on the positive 30 a uniform density raster along the length of the film material with a predetermined degree of overlapping of lines determined by the visual threshold for differentiating the horizontal structure D. ABOUT.  The use of the dual beam scanning mode also contributes to a reduction in the conspicuity of the line structure. However, the dual beam scanning is primarily intended to more effectively pass the frequency contrast correction of the printed and recorded images in the positive 30 movies.  The use in the proposed device of controlled feedback on the light for sharp and unsharp scanning and exposure spots allows for an effective gradation, color separation and frequency contrast correction of an elementary printed video image from a negative 29 to a positive 30.  Moreover, both the process of element-by-element recording and printing are performed simultaneously, which makes it possible to obtain an element-by-element corrected image on Positive 30 with predetermined gradation, color, and frequency-contrast characteristics, which in co-.  In the end, it improves the quality, dignity and completeness of decoding of the received Movie images. The proposed device, in comparison with the basic device, allows to produce element-by-element printing of images with all kinds of correction.

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Claims (1)

DEVICE »FOR RECORDING A MOVIE IMAGE ON A FILM, containing red, blue and green lasers, in optical launches of which light modulators, collimators, a system of dichroic mirrors, a mirror scanner, a printing unit containing a film channel for negative and positive, an automatic tension control system and positive, to the first input of which a negative and positive tension sensor is connected, and to the second input is the output of synchro-generators, a block of exponential converters, while The scanning scanner is mounted on the axis of the first synchronous electric drive connected to the output of the automatic control system by the scanner, the scanner feedback sensor is connected to the first input of the scanner, and the synchro generator output, the transporting drum, connected to the film channel and mounted on the axis of the second synchronous electric drive, is connected to the second input, connected to the output of the automatic control system by continuous transportation, to the first input of which a feedback sensor mounted on the axis of the transp a rotary drum, and the synchro-generator output to the second input, the second system of dichroic mirrors mounted above the print unit is optically coupled to it and to a block of three photodetectors, the outputs of which are connected to the inputs of the block of three logarithms, and the inputs of the block for correction and image processing and a block of feedback amplifiers are also connected to the output of the sync generator, characterized in that. that, in order to improve the quality of the cinema image, the completeness and reliability of its decryption, to obtain element-wise corrected color images with specified gradation, color, and frequency-contrast characteristics, light filters, additional light modulators, additional collimators are introduced into it , a block of interchangeable diaphragms, the first and second additional systems of dichroic mirrors; an additional mirror scanner; an additional synchronous electric drive; automatic control system, additional feedback sensor, a block of three reference photodetectors, a reference photodetector of brightness signal, the first and second additional logarithmators, an additional block of three logarithmators, a light dividing cube, a large-spot scanning photodetector, an analog block subtractors, the first and second blocks of the video signal by white level, an additional amplifier. feedback, an additional exponential converter, while the light splitters are installed at the laser outputs and are optically coupled to the main modulators and additional modulators, behind which additional collimators and the first additional system of dichroic mirrors are sequentially located, and a block of interchangeable diaphragms is installed at the outputs of the main and additional collimators, and the outputs> the main and first additional system of dichroic mirrors are optically coupled through the corresponding first and second optically forming systems with the main and additional mirror scanners, each optical forming system made in the form of a telescopic triple-lens system with a mirror trihedral isosceles prism inside, in which the first and third lenses located coaxially ·; and the optical axis of the second lens is perpendicular to their optical axis, and at the point of intersection of the axes are the rear focus of the first lens, the front focus of the second and third lenses and the apex of the mirror isosceles trihedral prism, the base of which is parallel to the optical axis of the first and third lenses and the axis rotation of the mirror scanner, in the middle of the radius of which the rear focus of the second lens is located in front of its rotation axis, and the optical axes of the third lenses of the first and second optical Forms The generating systems are mutually perpendicular and at their intersection are their rear foci, the center of the beam splitting cube and the front focus of the first lens introduced; · The output optical forming system, made in the form of a two-lens telescope, the back focus of the second lens of which is located in the printing unit and combined with the front focus of the first lens of the introduced third optical forming system, made in the form of a two-lens telescope, and a reflecting mirror located on the optical the axis of the system behind the first lens and at an angle of 45 ° to the optical axis of the system and optically coupled to the input of the second main system of dichroic mirrors, while the optical axes of the three optical formations of the generating systems and the output optical forming system are located in the same plane, and the additional mirror scanner · is mounted on the axis of the additional synchronous electric drive connected to the output of the additional automatic control system, to the first input of which the output of the sync generator is connected, to the second - the output of the additional feedback sensor, and to the third - the output of the feedback sensor of the main mirror scanner, while the primary and secondary mirror scanners are optically coupled through the corresponding There are the first and second rptic forming systems ₍ beam splitting cube, output optical forming system with a printing unit, and through the beam splitting cube and the second additional system dichroic! mirrors are optically coupled to the inputs of the reference photodetector of the luminance signal and a block of three reference photodetectors, the outputs of which are connected through the logarithm of the brightness signal and an additional block of three logarithms to the first inputs of the block of analog subtractors, to the second inputs of which the outputs of the main block of the logarithmators are connected and through the second additional logarithm is the output of the photodetector of a large scanning spot, which is optically coupled through a third optical forming system with a printing unit, which through it is optically coupled to the second main system of dichroic mirrors, and the outputs of the analog subtractor unit are connected to the inputs of the image processing and correction unit, one of which outputs through series-connected additional feedback amplifier, additional exponential converter, additional video amplifier, and the second block of video signal binding according to white level connected to the inputs of additional light modulators, and the outputs of the first video linking unit are connected to the inputs of the main light modulators drove πό to the level of white connected to the outputs of the video amplifier block.