SU883936A1 - Device for reading-out information from interference patterns - Google Patents

Description

one

The invention relates to the field of automation and computer technology and can be used for automatic processing of interferograms when inspecting surfaces of large-sized optical components. A device comprising an image sensor, a video amplifier, a sweep generator, a clock generator is known, and the image sensor output is connected to the first input of a video amplifier whose output is connected. to the input of the threshold element, and the second and third elements respectively to the first and second outputs of the synchronizer, the input sync eratora connected to the output of the master oscillator, and a third output - to the input of the sweep generator, which outputs are connected to inputs of the image sensor, the first counter outputs connected to the inputs of the coincidence circuit, the other inputs of which are connected to the outputs of the second counter, and Videocontrol

block 1.

The disadvantage of this device is its low speed.

Closest to the present invention is a device comprising a video signal sensor connected to video

deamplifier and sweep generator connected to the synchronous generator, with dim generator, threshold elements connected to the video amplifier and a group of pulse drivers, video control unit connected to the video amplifier, memory blocks, pulse drivers, registers, delay elements, triggers

10 and elements AND, OR 2.

The drawback of the device lies in the insufficiently high speed of the device.

The purpose of the invention is to increase the speed of the device.

The goal is achieved by the fact that in a device for reading information from interference patterns, containing a master oscillator connected with a delay element, with the first element I, with the first frequency divider and with a synchronous generator, the outputs of which are connected to a sweep generator connected to the sensor

25 video signals, to the shift register, to the first and second counters, to the recording unit connected to the second counter, to the delay element, and to the first pulse shaper, the trigger and the OR element, the second pulse shaper connected to the delay element connected to the first and to the second trigger, with the second trigger and with a video amplifier, the inputs of which are connected to the video signal sensor and the synchronous generator, and the outputs are connected to the video control unit and to the noporoBfcuii elements of the group connected to the corresponding drivers groups, the third trigger connected to the control unit, to the first trigger and to the first pulse shaper, the first memory block connected to the second counter and trigger, the inverter, the second memory block and the third pulse shaper, are entered the second And element whose inputs are connected with the third pulse shaper and with the second trigger, and the output is connected to the second memory block., the third counter, connected to the second pulse shaper and the memory block, the third element And connected to the first and second counters, And the second element, connected to the first pulse shaper, with the third element And, and with the second trigger connected to the first element And, the second element OR, connected to the corresponding group shaper, with the first element OR, and with the inverter, the FIVE element And, inputs which is connected to the shift register connected to the first counter, and the output is connected to a video amplifier, the fourth trigger connected to the frequency divider connected to the second counter and the first trigger, the third memory block connected to the second And, the subtraction unit connected to the third memory block, the fourth counter, the inputs of which are connected. are connected to the subtractor, the fifth trigger is connected to the first OR element, to the third counter and the pulse former, the third OR element connected to the corresponding forg / pulse broker of the group and the fifth trigger , the sixth And element connected to the first And element connected to the first trigger, to the fifth trigger and to the fourth counter, fifth, the counter connected to the second OR element, to the sixth And element to the subtraction unit, and the sixth counter, log in the ports of which are connected to the second pulse shaper q with the first element I, and the output connected to the fourth counter.

The drawing shows the block diagram of the device.

The device includes a video signal sensor 1., a video amplifier 2, a group of threshold elements 3, a sync signal, a generator 4, a master oscillator 5, a generator 6, a sweep, a delay element 7, the first trigger 8, the first element OR 9, the first counter 10, a register 11 the shift, the second counter 12, the recording unit 13, the first pulse shaper 14, the frequency divider 15, the first element 16, the second trigger 17, the first memory block 18, the second element 19, the second memory block 20, the third memory block 21 , the third is a counter 22, subtraction unit 23, the fourth counter 24, the fifth counter 25, the third element AND 26, the fourth element AND 27 the third trigger 28, the control unit 29, the fourth trigger 30, the fifth element AND 31, the sixth counter 32, the second; pulse generator 33, the AND-34 sixth element, the second element OR 35, the inverter 36, the fifth trigger 37, the third pulse generator 38, the third element OR 39, a group of pulse shaper 40, and a video control unit 41.

In this case, the group of threshold elements 3 includes threshold elements 42-44, and the group of shapers 40 pulse shapers - 4550:.

The device works as follows.

The master oscillator 5 generates pulses fed to the input of the synchronous generator 4, to the first input of the frequency divider 15 to the first input of the delay element 7 and the first input of the And 16 element. In the synchronizing generator 4, a receiver synchronization signal, a receiver damping signal, an inverse frame damping pulse and special pulses designed to control the sweep generator 6, which are fed to the input of the generator 6. The sweep generator 6 generates pulse sequences arriving at the inputs of the sensor 1 of the video signal from the mapping. The output signal of the video image sensor 1 is fed to the input of the video amplifier 2. The trigger 37 is set by the damping signal of the receiver OR 9. At the same time, the signal from the sync generator 4 is fed to the input of the video amplifier 2, to the first input of the trigger 8, to the delay element 7. By a signal from the output of the delay element 7, the triggers 8 and 17 are set to zero and the pulse shaper 33 is started.

The shaper -33 pulses produce pulses, the duration of which is determined by the required vertical width of the measuring mark on the shaper 49. The counters 22, 24 and 32 zero the pulses from the shaper 33 output. At the same time, they arrive at the input of the video amplifier 2.

The synchronization signal of the receiver from the clock generator 4 is fed to the input

register 11 shift to the first input of the counter 10 and to the input of the video amplifier 2.

The inverse frame damping pulse of the synchronizing generator 4 records the code. From the output of the recording block 13 into the counter 12. and resetting the shift register 11, as well as synchronizing the operation of the pulse generator 14. After the end of the pulse holding the register 11 to zero, register 11 triggers are sequentially switched by the action of incoming pulses.

From the output of the penultimate bit of register 11, pulses are fed to the input of element I 31, to another input of which a signal is fed from the inverse output of the last bit of register 11. From the output of element I 31, a pulse intended to form a horizontal measuring mark is fed to the input of video amplifier 2. At a certain point in time, the signal from the output of the shift register 11 locks the AND 31 element and allows the registration of pulses by the counter 10.

In video amplifier 2, the signals received at its inputs are mixed. From the second output of the video amplifier 2 to the input of the video control unit 41, an image signal with impulses of the measuring marks, damping and synchronizing pulses mixed in it is applied.

The image under study, for example, the interferogram of the optical surface, is projected onto the image video sensor 1 in such a way that the direction of the interference fringes is perpendicular to the horizontal strip on the screen of the video control unit 41 (horizontal measuring mark) and parallel to the vertical strip (vertical measuring mark).

With the start of the measurement, for example, after the operator has switched on the corresponding control button, the trigger 28 from the control block 29 receives a positive potential, tilting the trigger 28,

From the output of the trigger 28 to the input of the pulse driver 14, a potential is applied that permits the formation of a measurement pulse.

Shaper 14 pulse-in produces a positive pulse, unlocking element VI 21. The counter 10 records the number of horizontal clock pulses corresponding to the number recorded in counter 12. From the output of the third element And 26 sigNss through element 27, it goes to the first input of the trigger 17. With trigger output 17 is signaled; And 16 and 19 unlocking elements and allowing to record the number from the outputs of the counter 12

block 18. Pulses from generator 5 pass through element 16 to counting input of counter 32 and elements 16 and 34 of counting inputs of counters 24 and 25. From the first output of video amplifier 2, the amplified signal from the interference band is fed simultaneously to the inputs of threshold elements. groups 3. The threshold elements are sequentially triggered by the input signal.

0 At the same time, each of the threshold elements produces a square-shaped pulse, on the leading edge of which one of the pulse formers 46, 47 and 48 is triggered, and on the back edge one of the formers 50, 49 and 45. Due to distortions of the image of the interference band caused, for example, the presence of a low-frequency background in some cases,

0, the threshold of one or several threshold elements does not capture the edges of the pulse of the image of the interference fringe, and the triggering or releasing of the threshold element is omitted. The pulses from the outputs of the threshold elements 44 and 42 trigger the formers 46 and 47 pulses, which produce short pulses that zero in through the OR element 35 of the counter 25. At the same time, the pulses from the output of the OR element 35 enter through the inverter 36 to the input of the counter 24 and through the element OR 9 to the input of the trigger 37. At the time of release of the threshold element 42 is triggered

5 driver 49 pulses. A short pulse from the output of the imager 49 overturns the OR elements 35 and 9 of the trigger 37. The signal from the second output of the trigger 37 locks the element AND 34. At the same time, the pulse from the first output of the trigger 37 is recorded in the counter 22 and starts the imager 38 of pulses. The impulse from the output of the imager 38 passes through the element. And 19 to the inputs of the blocks 21.

5 and 20, allowing recording from the counter

22 code number interference band in block 20, and from the outputs of the block

23code. Horizontal coordinate of the center of the interference band in

0 block 21. The horizontal coordinate code of the center of the interference fringe is obtained by subtracting in block 23 half of the number written in the counter

25 of the code recorded in the counter

5 24. On the leading edge of the next interference band, the threshold element 42 and the pulse shaper 47 are triggered, the pulse through the OR element 35 is zeroed by the counter 25 and is tilted through the elements OR 35

0 and 9 trigger 37. At the same time, through. the element OR 35 and the inverter 36 pulse passes to the input of the resolution of the preliminary recording of the counter 24 and the code is recorded from the counter

32 in the counter 24. For some time the same code will be recorded in the counters 32 and 24. Through elements 34, counting pulses are applied to the inputs of counters 24 and 25. Measuring the horizontal coordinate of the center of the next interference band is similar to measuring the coordinate of the previous band. The counters 24, 25 and .32 record the number of pulses produced by master oscillator 5. The horizontal coordinate of the center of the interference fringe is obtained by subtracting the code shifted by one bit from the outputs of the counter 25 from the code recorded in the counter 24.

At a given point in time, the readings of the counter 22 increase by one. With the end of the active part of the line at the input of the trigger 8 receives a positive potential. The trigger 8 is triggered on the front of the pulse coming from the output of the element 16. The pulse from the output of the trigger 8 resets the trigger 28 and the trigger 30. The signal from the output of the trigger 30 allows the frequency divider 15 to switch. From the output of the frequency divider 15, impulses are fed to the input of counter 12, the number of which corresponds to the measurement step of. verticals From the second output of the frequency divider 15, a pulse is sent to trigger 30, which changes the state of trigger 30. With the signal from trigger output 30, divider 15 is reset and held in this state until the next pulse appears. From the output of the element And 19 the impulse is again removed. In block 21, the next vertical coordinate of the centers of the interference fringes is recorded. The cycle of measurements on the line (the cycle of determining the horizontal coordinates of the centers of the interference fringes) is repeated. At a certain point in time, a pulse appears at the output of the trigger 8, tilting the triggers 28 and 30 and the transition to the next vertical coordinate is made.

Measurements continue in a similar manner until the measurement pulse ends at the end of the television field. Element And 27 is locked and the possibility of recording the results in blocks 18, 20 and 21 is eliminated until the control signal appears from the output of control block 29.

Thus, the proposed device provides a reading of a given number of coordinates of the centers of interference fringes during one television field, and the introduction of new units and connections made it possible to significantly increase the speed of the device, i.e. readout speed of the coordinates of the interference fringes. This makes it possible, when monitoring large-sized optics, to read

information directly from interference patterns, i.e. Mine is the process of photographing.

Claims (2)

Invention Formula A device for reading information. The interference patterns pattern containing a master oscillator connected to the delay element, the first And element, the first frequency divider and a synchronous generator, whose outputs are connected to a sweep generator connected to the video signal sensor, to the shift register, to the first and second counters, a recording unit connected to the second counter, to the delay element and to the first pulse shaper, the trigger and the OR element, the second pulse shaper connected to the delay element connected to the first and second t The second trigger and video amplifier, the inputs of which are connected to the video signal sensor and synchronizer, and the outputs are connected to the video control unit and the threshold elements of the group connected to the corresponding group of formers, the third trigger connected to the control unit to the first one: The first pulse generator, the first memory block connected to the second counter and the trigger, the inverter, the second memory block and the third pulse generator, characterized in that, in order to increase the speed Twi device, it contains the second element And, the inputs of which are connected to the third pulse shaper and the second trigger, and the output is connected to the second memory block, the third counter connected to the second pulse shaper and memory block, the third element And connected to the first and second counters, the fourth element And, connected to the first pulse shaper, with the third element And, and with the second trigger connected to the first element And, the second element OR, connected to the corresponding formers groups , with the first element OR and with the inverter 5m, the fifth element I, whose inputs are connected to the shift register connected to the first meter, and the output connected to the video amplifier, the fourth trigger connected to the frequency divider connected to the second counter, and the first trigger , a third memory block connected to the second AND element, a subtraction unit connected to the third memory block, a fourth counter, the inputs of which are connected to the inverter and the second pulse shaper, and the output connected to the subtractor block. the fifth trigger connected to the first OR element, to the third counter and pulse generator, the OR element connected to the corresponding group pulse generator and the fifth trigger, the sixth AND element connected to the first AND element connected to the first trigger, c the fifth trigger and the fourth counter, the fifth counter connected to the second element OR, to the sixth element AND to the subtractor, and the sixth counter, whose inputs are connected to the second pulse shaper and to the first element And the output connected to to the fourth counter. Sources of information taken into account in the examination 1.Koldakov K.I. and other devices and equipment of the experiment. 1976, 1, p. 59-61. 2. Japanese patent 51-36971, cl. 97 (7) B 62, 1976 (prototype).