RU2117410C1 - Device which measures characteristics of cathode-ray tubes - Google Patents

Abstract

FIELD: instruments. SUBSTANCE: device has unit of cameras which receive picture of cathode-ray tube under investigation, video processor which converts analog signal to digital one and stores latter in internal memory unit, central processor which controls address allocation controller, magnetic field controller, which controls shift of electron beams, selector which serves selection of analog and video signals which are related to temperature drift under control of signals from central processor. Signals from magnetic field controller are sent to deflecting coils of video cameras. EFFECT: measuring temperature drift of cathode- ray tube. 15 cl, 9 dwg

Description

 The invention relates to a system for measuring the characteristics of cathode ray tubes (CRTs), and more particularly, to a system for measuring thermal drift of CRTs.

 As the main factor in evaluating the characteristics of CRTs - the magnitude of the CRT thermal drift - the degree of change in the magnitude (coordinate) of the place where the electron beam hits the screen is presented, due to the thermal expansion of the shadow mask and frame to fix the details of the CRT, which are the metal components of the CRT.

 Usually, the measurement of the wrong place an electron beam hits the screen, due to the thermal expansion of the metal components in a CRT, is carried out by a special CRT and manual measurement with a microscope. This method cannot achieve the exact values of thermal drift due to subjective error.

 FIG. 1 is a block diagram of a conventional system for measuring CRT characteristics.

 In FIG. 1 shows a camera 1 that converts an image into an electrical signal, receives an image of a CRT test 2 through an image receiving lens 1a. The electrical signal represents the output signal to the video processor 3 to be digitally converted and stored in the built-in storage device. The video monitor 4 reproduces the data stored in the storage device of the video processor 3, as an analog signal. The Central processing unit (CPU) 5 analyzes the data stored in the storage device of the video processor 3, and sends the corresponding data based on the analyzed data to the magnetic field controller 6 in order to force the electron beam to be moved. Data analyzed by the central processor 5 is also reproduced on another video monitor 7 or printed by a printing device 8.

 Here, the image reproduction state after the movement of the electron beam is again analyzed by the central processor 5, and the states before and after the movement of the electron beam are compared in order to calculate its magnitude of the place where it hits the screen. The degree of thermal drift is measured by repeated calculations on points and for each period of a predetermined activity. However, this measurement of the thermal drift of a CRT takes a relatively long time.

 The aim of the invention is to develop a system for measuring thermal drift for a CRT, which has the ability to automatically measure the degree of thermal drift with time at the same time at many points of a CRT, thereby shortening the measurement period and performing standardized measurement by quantifying the magnitude of thermal drift.

 To achieve this, the thermal drift measurement system for a CRT according to the present invention comprises: cameras for receiving an image of a measured CRT to convert it to an electrical signal; a video processor for converting the output of analog signals from cameras to store them in a built-in storage device; a central processor for analyzing data stored in this video processor memory to output an appropriate control signal according to the analyzed data; a magnetic field controller for controlling the movement of electron beams by a control signal of the central processor; a selector for selecting analog video signals from cameras controlled by a central processor and transmitting a magnetic field conversion signal from a magnetic field controller to camera means controlled by a central processor, and a part of an output for quantifying data analyzed by a central processor to reproduce or print these updated data on a display screen .

The aforementioned object and other advantages of the present invention will become more apparent by a detailed description of a preferred embodiment of the present invention with reference to the attached drawings, in which:
FIG. 1 is a block diagram of a conventional CRT measurement system.

 FIG. 2 is a block diagram of a CRT measurement system according to the present invention.

 FIG. 3 is a block diagram of a camera selecting device of a CRT measurement system according to the present invention.

FIG. 4 is a detailed wiring diagram of camera selecting means shown in FIG. 3;
FIG. 5 is a block diagram of a magnetic field shift coil selection device of a CRT measurement system according to the present invention.

 FIG. 6 is a detailed circuit diagram of means for selecting a magnetic field shift coil shown in FIG. 5.

 FIG. 7 shows a cross-sectional side view of a portion of the apparatus where cameras and CRTs of a CRT measurement system according to the present invention are installed.

 FIG. 8 shows a front view of a portion of a camera installation of a CRT measurement system according to the present invention.

 FIG. 9, A and B illustrate a sectional view and a side view of a camera holder of a portion of a camera installation of a CRT measurement system according to the present invention.

 As shown in FIG. 2, the CRT thermal drift measurement system consists of a camera 10, a selector 20, a video processor 30, a video monitor 40, a magnetic field controller 50, a central processor 60, and an output unit 70.

 The camera 10 is composed of a set of lenses 11 for receiving images from a test CRT 1, a set of cameras on the TEC (charge-coupled devices) in a 3 x 4 matrix, for example, twelve, for outputting an image received from the corresponding lenses 11 as an electrical signal, a plurality of magnetic field shift coils 13 provided on the front of each lens 11 for receiving a magnetic field conversion signal from a magnetic field controller 50, through a selector 20, under the control of a central processor 60 so To move the electron beam, and a cascade operating system XYZ to maintain the cameras on the PES.

 The operation of a system for measuring the thermal drift of a CRT according to the present invention will be described below in accordance with the above scheme.

 The Central processor 60 initializes the video processor 30, the magnetic field controller 50 and the selector 20. The lens 11 receives the image of one point from the test CRT 1, and the camera on the PES 12 converts it into an electrical signal. The video processor 30 converts the analog video signal output from one camera to the CCD selected by the selector 20, under the control of the central processor 60, into a digital signal and stores it in the built-in storage device. In this case, the stored data undergoes a change according to a continuously changing analog signal, and it matters in the X-Y coordinate system, and the brightness information for one image point is displayed on the screen of a test CRT 1.

 The video monitor 40 displays the data stored in the storage device of the video processor 30 as an analog signal. The central processor 60 analyzes this data to evaluate the current state of the characteristics of the electric beam, and transmits the corresponding data to the magnetic field controller 50. The magnetic coil 13 forms a magnetic field according to the data transmitted from the central processor 60 through the selector 20 and converts the electron beam.

 The selector 20 is connected to twelve cameras on the CCD 12, supported by a cascade 14 operating in the XYZ system, and connected to twelve magnetic field shift coils 13, which are associated with the corresponding lenses 11, and selects one camera 12 that receives one image point, and one magnetic coil 13 installed on it.

 Meanwhile, the central processor 60 takes a state after moving the electron beam and comparatively analyzes it with the state before moving the electron beam in order to read the value of the point of impact at the first point. When the measurement of one point is completed, the video monitor 70a reproduces the value of the data analyzed by the central processor 60.

 After completing the measurement of the first point, according to the method described above, the initial hit points of the remaining twelve points are measured and, after a predetermined period of time, their hit points are measured again to calculate the degree of thermal drift. In this case, the degree of thermal drift can be quantified and reproduced on the video monitor 70a with an estimate of the position for each point, graph, or chart. The measurement values at twelve points can be simultaneously output through the printing device 70b.

 In the system according to the present invention, the thermal drift degrees of 12 points can be read in a unit of micron and, since it takes less than 5 s to read the value of the point of impact of one point, twelve degrees of thermal drift can be read every minute.

 With reference to FIG. 3, the camera selection device consists of a central processor 60, a video processor 30, a plurality of cameras CA1 to CA12 located at corresponding points in front of the CRT 1, and means for selecting a camera 100 to select a single camera among the cameras CA1 to CA12 to output their video signal.

 In the camera selection means 100, the control signals from the central processor 60, which uses the control program to control the entire system and select the camera, present the input signals to the trigger latch 110 and the address controller 120. The address controller 120 controls the clock signal for the trigger latch 110 in accordance with the control signal of the Central processor 60.

 The output of the trigger latch 110 is connected to the inputs of the camera selector 130, which connects the individual outputs of the cameras CA1 to CA12 located in front of this CRT. The output of the camera selector 130 is connected to a stabilizing circuit of the output signal 140. The trigger latch 110 generates its output signal according to the data from the central processor 60 and the synchronization signal from the address controller 120.

 As shown in FIG. 4, the trigger latch 110 uses the signal from terminal D3 among the terminals D0 to D3 as a trigger signal for the camera selector 130.

 The camera selector 130 comprises two video multiplexers 131 and 132 having eight channels CH1 - CH8 and CH9 - CH16, respectively. The address inputs A0, A1 and A2 of each video multiplexer 131 and 132 are connected together to the data outputs D0, D1 and D2 of the trigger latch 110. The output D3 of the trigger latch 110 is connected directly to the unlock port of the video multiplexer 132 and to the unlock port of the video multiplexer 131 through inverter 133.

 The corresponding channels CH1 through CH6 and CH9 through CH14 of the video signal multiplexers 131 and 132 are connected to each camera CA1 to CA12. The outputs of the video signal multiplexers 131 and 132 are connected to a stabilizing circuit of the output signals 140.

The output signal stabilizing circuit contains parallel correction capacitors C1 and C2 for the high-frequency component and for blocking the direct current, resistor R ₁ for adjusting the input signal level, non-inverting amplifier OP1, resistor R ₂ connected to the non-inverting port of non-inverting amplifier OP1 to provide a voltage dividing voltage resistors R ₃ and R _4, the capacitor C3, which provide the reference voltage output signal fed back noninverting amplifier OP1, C4 to capacitor liminatsii (elimination, Trans.) the dc component of the output signal of the noninverting amplifier OP1, R ₅ a resistor for adjusting the output level and resistor R ₆ to give the DC power from the power voltage V _cc to the output video signal.

 Below will be described the operation of a system for measuring the characteristics of a CRT according to the present invention.

 The central processor 60 generates a 5-bit control signal according to a predetermined control program. The trigger latch 110 latches this control signal and the address controller controls the trigger latch 110 under the control of the central processor 60. The corresponding control signals from the data outputs D0, D1 and D2 of the trigger latch 110 represent the input signals to the respective inputs A0, A1 and A2 of the video multiplexers 131 and 132 of the camera selector 130. The control signal from terminal D3 represents an input signal to the unlock port of the video signal multiplexer 132 and, at the same time, an inverted inverter 133 to be supplied to the unlock gate The port multiplexer video signal 131.

 Accordingly, if the logical state of the data output D3 of the trigger latch 110 is “1”, the video multiplexer 131 is locked, unlocked to the video multiplexer 132 to select one of the channels CH9 to CH14 so that the photographed video signal is the output signal through the video multiplexer 132 .

The output of this video signal is supplied to the stabilizing circuit of the output signals 140. Since this signal is weak, capacitors C1 and C2 compensate for its high-frequency component and eliminate the DC component. Then this video signal is fed to the input of the non-inverting amplifier OP1 through the resistor R ₁ .

This video signal, amplified to a sufficient amplitude by the non-inverting amplifier OP1, represents the input signal to the video processor 30 through the resistor R ₅ , and with its constant component removed by the capacitor C4. Through the resistor R ₆ , the supply voltage Y _cc imparts a constant component suitable for the input signal to the video processor 30 and thus this video signal is stabilized.

 Meanwhile, if the logical state of the data output D3 of the trigger latch 110 is “0”, the video signal multiplexer 131 is started. Thus, one of the channels CH1 - CH6 is selected in accordance with the control signals of the data outputs D0, D1 and D2 of the trigger-latch 110, the corresponding camera is selected, and this video signal is stabilized by the stabilizing circuit of the output signals 140 to become an input signal and a video processor 30.

 In other words, by setting the stabilizing circuit of the output signals 140 to stabilize the video signal after the camera selector 130, the quality of this video signal is improved and its interference is eliminated.

 As shown in FIG. 5, the magnetic field shift coil selection device of the selecting means according to the present invention includes a central processor 60 for controlling the entire system and outputting data to select a magnetic field shift coil according to a predetermined program, an address controller 120 for controlling the address of the central processor 60, a trigger a latch 110 for snapping an address signal controlled by the addressing controller 120 and data transmitted from the central processor 60, a decoder unit 200 for decoding data x according to the output and the enable signal from the trigger latch 110, the power component block 300, controlled according to the output signal of the decoder unit 200, in order to separately supply the computer control power and the power of the magnetic field shift coils, the switching unit 400 for selecting one of the combination the relay according to the control of the power divider 300 to include the selected relay, a magnetic field controller 500 for providing a magnetic field control signal through the switching unit 400, and a block of shear coils a magnetic field 600 for receiving a control signal from a magnetic field controller 500, through a switching unit 400, to control a magnetic field shift coil at a single point.

 Here, the decoder unit 200 consists of two decoders of the “3 and 8” type 201 and 202. Since the “3 in 8” decoder 201 receives the inverted unlocking signal of the trigger latch 110 through the inverter 203, and the “3 in 8” decoder 202 receives a non-inverted unlocking (enable) signal, only one of the two 3-in-8 decoders is selected in order to be actuated.

The output of the decoder unit 200 represents the input to the power divider 300. The corresponding power divider from the combination of power dividers 301 - 306 and 307 - 312 of the power divider 300 is driven to provide a supply voltage V _cc to the switching unit 400, and the remaining dividers capacities become blocked.

 The switching unit 400 only includes a relay selected by the power divider 300 and provides the control signal of the magnetic field controller 500 to the corresponding magnetic field shift coil 600. Thus, the magnetic field shift coil of a desired point can be selected to measure characteristics at that point.

 Power dividers 301-306 and 306-312, respectively, consist of light emitting diodes (D1 - D12) receiving the corresponding output signals from decoders 201 and 202 through an inverter (11 - 112) and a photocell (PT1 - PT12). Here, the first resistor (R1 - R24 inaccuracy indicators) of each power divider 301 - 312 represents a current limiting resistor for light emitting diodes, and the second resistor) R1 - R24, parity indicators) represents a resistor in the emitter circuit for communication photocells.

 The emitter of each communication photocell (PT1 - PT12) is also connected to the corresponding excitation coils of the relay 401 to 412 of the switching unit 400. Two points of the movable contact of the relay 401 are connected to the magnetic field controller 500, and its fixed contact points are connected to two input points of the magnetic field shift coil 601 block of shear coils of a magnetic field 600. Here, a coil of shear of a magnetic field moves vertically and horizontally in a magnetic field so as to be used both for composed by point elements and for glossy types.

 One side of the vertical displacement coil and horizontal displacement coil 601 are connected to two fixed points of the relay 401, and their other sides are connected together to the output of the magnetic field controller 500.

 Accordingly, the magnetic field controller 500 has only four outputs. Two pins are connected together with two ports of each magnetic field shift coil 601 - 612, and the other two pins are connected together with the other two ports of magnetic field shift coil 601 - 612 through corresponding relays 401 - 412. As described above, each of the twelve used pins of the decoder block 200 corresponds to one power divider, one relay and one magnetic field shift coil.

 According to the above diagram, the operation of the device for selecting the magnetic field shift coils will be described below.

 The central processor 60 generates a signal for selecting a magnetic field shift coil according to a predetermined control program, and the addressing controller 120 transmits clean and synchronizing signals to the trigger latch 110.

 The trigger latch 110 receives four data signals from the central processor 60 and latches them. The trigger latch 110 also generates output signals from the outputs Q1 to Q4, in accordance with a clock (clock) pulse from the address controller 120. The signals from three or four outputs (Q1, Q2 and Q3) represent the input signals to the three inputs A, B and C of each decoder 201 and 202. The output signal Q4 is supplied to the decoder 202 as a reference signal, and to the decoder 201 through an inverter 203 as a blocking signal. Accordingly, if the logical state of the trigger output Q4 of the latch 110 is “1”, the decoder 202 is selected to be driven. Conversely, if the logical state is “0”, decoder 201 is selected to be driven. The logical states of the outputs of the decoders 200 are shown in the table.

For example, when the outputs Q1 - Q4 of the trigger - latch 110 are the same as shown by N1 in this table, since only the logical state of the output on Y0 among the outputs Y0 - Y7 of the decoder 201 is "0", the logical "1" is applied to the photocell PT1 , through the inverter 11 so that the coupling photocell is driven and the light emitting diode D1 becomes luminous to be driven. Therefore, since the supply voltage V _cc on the side of the magnetic field shift coil is conducted to the PT1 communication photocell to be applied to the relay coil 401, and the power dividers 302-306 and 307-312 connected to other outputs Y1 to Y7 are turned off, only relay 401 is on. In this way, magnetic displacement appears only on the part where the magnetic field shear coil 601 is provided in front of the test screen that characteristics are measured at this point.

 As shown above, the magnetic field shift coil is selected by data signals d0 to d3 of the central processor 60, and vertically and horizontally moving coils from the magnetic field shift coils are selected and controlled by the selection of the output signal of the magnetic field controller 500.

 FIG. 7 is a side view of a test fixture showing how one column of cameras and a CRT system are installed to measure the characteristics of a CRT according to the present invention.

 As shown in FIG. 7, the test fixture 700 comprises a part for installing cameras 702, where cameras 701 are installed, a part for installing a CRT 704, where a CRT 703 is installed, and a support part 705 so as to rotate to support parts for installing cameras and a CRT 702 and 704.

 A CRT holder 706 for securing a CRT 703 is provided in the CRT mounting portion 704 and is bolted 707 so that the upper and lower parts of the holder 706 are removably attached to the mounting portion of the chamber 702. A support rotator 709 having bearings 708 is provided between the support 705 and the parts installation of cameras and CRTs 702 and 704.

 Meanwhile, as shown in FIG. 8, the installation part of the chambers 702 has a disk 716 in its central part, the center of which is attached to the support 711. The upper and lower parts of the support 711 are attached to the upper and lower parts of the installation part of the cameras 702, respectively, with bolts 713. A hole with a slot (not shown) formed for the bolt 713, allowing the support 711 to move back and forth at a certain distance.

 The first and second guide rods 715 and 717 are installed in a diagonal direction in the horizontal direction of the installation portion of the chamber 702, respectively. One side of the first guide rod 715 of the slide 721, provided on the periphery of the installation part of the cameras 702 and movable vertically and horizontally, like the first hinge 718, so as to provide mobility. The other side of the first guide rod 715 has a second guide rod 717 and a second hinge 719 to provide mobility. The other side of the second guide rod 717 is connected to the disk 716 and the third hinge 720 to provide mobility. The directions of rotation of the first and third joints 718 and 720 are the same and the directions of rotation of those and the second joint 719 are perpendicular.

 Meanwhile, one first guide rod 715 has at least two chambers 701 and camera holders 722 for mounting the chambers 701 are mounted on the first guide rod 715 and are movable from left to right and vice versa in the length direction of the first guide rod 715.

 As shown in figures 9, A and B, the camera holder 722 consists of a fixing part 723 for fixing the camera 701, a node 724 secured to the first guide rod 715, and a slider 725 in order to provide horizontal sliding of the fixing part 723. The node 724 is installed on the first guide rod 715 so that the holder of the chambers 722 slides along the first guide rod 715 and the slider 725 is brought into a sliding state back and forth by the control screw 726 so that the distance of the chamber 701 can be adjusted. A rotation hole 725a is formed in the slider 725 so that the locking part 723 is rotatable together with the part 725a.

 As shown in FIG. 7, in the device according to the present invention, the CRT installation part 704 is fixed in one housing by a bolt 707 so that when measuring on cathode ray tubes of the same size, there is no need to re-adjust the distance of the relative position between the CRT screen 703 and the camera 701, whereby the time for measuring CRT characteristics is reduced. If the bolt 707 is released to separate the CRT 703, the CRT installation part 704 is separated from the camera installation part 702.

 The support 711, vertically mounted on the camera mounting portion 702, has a slot provided with a slot on its upper and lower parts and is fixed with a bolt 713 through the slot provided with the slot so that the support 711 is movable back and forth some distance from the camera mounting portion 702 . Here, the disk 716 fixed to the support 711 can also be moved back and forth by the first and third hinges 718 and 720 so that the distance between the camera 701 and the CRT 703 is adjustable.

 Since the slider 721 connected to one side of the first guide rod 715 is movable vertically if the slider 721 moves in any direction, the first guide rod will rotate, centering the second hinge 719 so as to reposition the camera 701.

 Since the assembly 724 of the camera holder 722 is fixed to the first guide rod 715, the holder of the cameras 722 is movable along the first guide rod 715 to move the cameras and is rotatable around the axis of the first guide rod 715. In figures 9, A and B, when the control screw 726 is driven because the slider 725 is movable horizontally, the camera 701 is movable back and forth. Since the fixing part 723 secured to the chamber 701 is connected to the slider 725 by the fixing screw 727, the fixing part 723 is movable along the deep hole 725a formed in the slider 725, allowing the cameras to move in each direction.

 Accordingly, the camera 701 can be located in any desired location relative to the CRT 703 and, since each camera is movable in any direction, they can be freely adjusted relative to the screen of the CRT 703, whereby accurate measurements of the characteristics of the cathode ray tubes being tested can be carried out.

 Further, the parts for installing cameras and CRTs 702 and 704 are freely rotated by a supporting rotator 709 provided on a support 705, allowing measurement in the desired direction.

 As described above, in the apparatus for measuring the characteristics of a CRT according to the present invention, since the parts for mounting the cameras and the CRT are mounted in one housing, the preparation time for performing measurements is reduced. The CRT installation part can be separated from the camera installation part. Further, since the plurality of cameras mounted in part for installing the cameras is movable along the first guide rod and in any direction, it becomes easy to vertically adjust the cameras relative to the CRT screen and an accurate measurement of performance is achieved.

 As a result, the system for measuring the characteristics of a CRT according to the present invention can simultaneously measure the degree of thermal drift, according to the time period at many points of the CRT under the control of the central processor, using selector means, thereby reducing the time spent on measurement and obtain an accurate and standardized value measurements by quantifying (quantifying) the degree of thermal drift, taking microns as a unit of measurement.

 Although this invention has been particularly shown and described with reference to and preferred embodiments thereof, those skilled in the art will understand that various changes in form and detail may be made therein without departing from the spirit of the scope of the invention, as defined by the appended claims. inventions.

The inscriptions on the accompanying drawings
FIG. 1 (prior art)
1 - camera
2 - cathode ray tube (CRT)
3 - video processor
4 - video monitor
5 - central processor
6 - magnetic field controller
7 - video monitor
8 - printing device
FIG. 2
20 - selector
30 - video processor
40 - video monitor
50 - magnetic field controller
60 - central processing unit
70a - video monitor
70b - printing device
FIG. 3
30 - video processor
60 - central processing unit
110 - trigger - latch
120 - addressing controller
130 - camera selector
140 - stabilizing circuit of the output signals
FIG. 4
30 - video processor
110 - trigger - latch
131 - video multiplexer
132 - video signal multiplexer
FIG. 5
60 - central processing unit
110 - trigger - latch
120 - addressing controller
201 - decoder
202 - decoder
301 - power divider
306 - power divider
307 - power divider
312 - power divider
400 - relay
500 - magnetic field controller
600 - coil shift the magnetic field
FIG. 6
60 - central processing unit
110 - trigger - latch
120 - addressing controller
500 - magnetic field controller

Claims (15)

 1. A system for measuring the characteristics of cathode ray tubes (CRT), comprising a camera unit for receiving an image of a measured CRT, converting it into an electrical signal for shifting electron beams, a video processor that performs the function of converting an analog signal received from the camera into a digital signal, followed by storing the latter in the integrated memory (memory), the central processor, the input of which is connected to one of the outputs of the video processor, which performs the functions of controlling the addressing controller, gene signal control for selecting a deflecting coil of the magnetic field, analyzing the field of movement of the electron beam and calculating the point of impact of the electron beam, a magnetic field controller, the input of which is connected to one of the outputs of the central processor, and the output to the input of the video processor, which controls the shift of the electron beams of the control signal from the central processor, characterized in that a selector is introduced, which serves for sampling, under the control of signals from the central processor, analog and video signals, the nature temperature drift, and for transmitting, under the control of the specified central processor, the signal from the magnetic field controller to the deflecting coils of the cameras, the selector inputs being connected to the outputs of the cameras, the outputs of the central processor and controller, and the outputs to the video processor input, the outputs of the deflecting magnetic coils and to the controller, output means connected to the central processor and used to synchronize data analyzed by the central processor on a display or printer.  2. The system according to claim 1, characterized in that the camera unit includes a set of cameras, each of which is equipped with a lens for receiving images of the tested CRT, a set of deflecting coils mounted on the front of the lenses and configured to receive a control signal from controller and received on the basis of the video signal supplied to the camera lenses and converted by the latter into an electrical signal supplied to the selector, and the reduction of electron beams, camera holders, used for fixation Nia plurality of chambers arranged in accordance with a preselected scheme for measuring the characteristics of CRT.  3. The system according to claim 2, characterized in that the deflecting coils of the magnetic field of the camera unit are mounted on the necks of the transmitting tubes of the camera unit.  4. The system according to claim 3, characterized in that the selector includes a first sampling unit for selecting a plurality of cameras and a second sampling unit for selecting deflecting magnetic field coils.  5. The system according to claim 4, characterized in that the first sampling unit contains a trigger latch connected to the output of the central processor and to the input of the camera selector, which serves to fix the control signal from the central processor and generate a camera selection signal, an addressing controller connected to the output of the central processor and with the input of the trigger-latch and used to control the clock pulse of the trigger-latch, according to the control signal of the central processor, a camera selector connected to the trigger by its inputs Christmas tree and cameras and used to decode the output signal from the trigger-latch and select one of the set of cameras connected to the input port, and the output signal stabilization unit connected to the output of the selector and to the input of the video processor and used to stabilize the video signal of the camera selected by the selector, and filing the specified signal to the video processor.  6. The system according to p. 5, characterized in that the selector consists of two video signal multiplexers, the address inputs of which are paired with each other, connected to the corresponding outputs of the specified trigger-latch and which are activated in turn as they receive an enable signal from the trigger-latch and the outputs of these multiplexers are connected to the input of the stabilization block of the output signals.  7. The system according to claim 6, characterized in that the output signal stabilization unit contains two capacitors connected in parallel, connected by one of the outputs to the outputs of the video signal multiplexers for correcting the high-frequency component of the video signal converted by the cameras and eliminating its constant component, a non-inverting amplifier for amplifying a weak video signal introduced through two parallel capacitors, connected through the first resistor to the second terminals of two capacitors connected in parallel, divider feedback circuits on the fourth and third resistors and the third capacitor for creating the reference voltage of the non-inverting amplifier, connected to the output of the non-inverting amplifier, the fourth resistor for generating the bias voltage of the non-inverting amplifier, connected to the output of the non-inverting amplifier, the fourth capacitor for blocking the DC component of the video signal output from the non-inverting amplifier an amplifier connected between a non-inverting amplifier and a fifth resistor, a second and a sixth resistor for applying respective DC component to output a video signal, one of the terminals is connected to the noninverting input of the noninverting amplifier and the other - to the input of the video processor.  8. The system according to claim 4, characterized in that the second sampling means comprise an addressing controller connected to the output of the central processor and to the input of the latch trigger and used to control the address, according to the command to select the central processor, a trigger latch whose input is connected to the central computer and the addressing controller, which is used to fix the address signal of the addressing controller and the data transmitted from the central processor, a block of decoders whose inputs are connected to the corresponding outputs of the trigger latch, For decoding data, according to the output data and the enable signal from the trigger-latch, the power dividers unit, which includes a set of power dividers controlled by selectively energizing them from the decoder unit, in order to select a deflecting magnetic field coil according to a given program in the central processor, by selectively removing the control signal from the central processor and supplying power to the deflecting coils of the magnetic field, a switching unit including a plurality of relays connected in series to the respective power dividers to select one relay to be switched according to the control signal from the power divider block and generate a control signal from the magnetic field controller to the video processor, a block of deflecting magnetic field coils connected to the switching unit and to the magnetic field controller for receiving a control signal from the specified magnetic field controller through the switching unit for controlling the deflecting coil of the magnetic field in one chke.  9. The system of claim 8, wherein the decoder unit comprises a first decoder for receiving an unlocking signal from a latch trigger through an inverter and a second decoder for directly receiving an enable signal.  10. The system according to claim 9, characterized in that each power divider contains a series-connected light emitting diode to indicate the active output signal and a photocell, and the inputs of the power dividers are connected through inverters to the corresponding outputs of the decoders.  11. The system according to claim 1, characterized in that the device for testing and mounting cameras and a CRT has an element for mounting cameras and a unit for mounting a CRT, which are fixed in one housing and are detachable from each other, a support that is movable in direct and in the opposite directions and is placed in front of the camera mount with the possibility of supporting the disk, and a support rotator installed between the camera mount and the CRT mount and another support to support these parts.  12. The system according to claim 11, characterized in that the element for mounting the chambers comprises a set of first and second guide rods installed in the diagonal and horizontal directions of the disk, a set of first sliders connected to one end of the first guide rods and installed in the diagonal and horizontal directions disk, a set of first sliders connected to one end of the first guide rods and installed in the element for mounting cameras for moving in horizontal and vertical direction eniyah, and a plurality of holders cameras mounted on the first guide rods for rotating the camera in the horizontal and vertical directions.  13. The system according to p. 12, characterized in that the disk, the first and second guide rods and the first sliders are connected by the first, second and third hinges.  14. The system according to p. 13, characterized in that the first and third hinges and second hinges are made with the possibility of movement perpendicular to each other.  15. The system according to p. 12, characterized in that the camera holder contains a node fixed to the first guide rod, a second slider associated with a control screw installed in the node, and a fixing part fixed to the second slider with a fixing screw and movable along an elongated hole formed in the second slider for fixing the cameras.

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