SU955174A1 - Device for teaching radar station operators - Google Patents

Description

one

This invention relates to automation. ke and computing, in particular, to devices for training radar operators.

A device comprising a screen, a lens, blocks of photoelectric sensors associated with a logic unit, a control unit, alarms and a film projector, a selection unit, Q information code information connected to logic unit 1 is known.

The disadvantages of this device are the technical complexity as well as the complexity of operation. )five

A device is known comprising a circular view indicator connected respectively to matching units, reading data, azimuth sweep and distance sweep, an electric drive connected to an antenna simulator connected to an azimuth sweep unit and a synchronization unit connected via

the first trigger with the control input of the first valve connected to the measuring unit azimuth coordinates and the distance scanner connected via the second trigger to the control input of the second valve connected with the measuring unit of the coordinate coordinate and the range marker generator, calculator associated with unit measuring the coordinates of the azimuth and range 2.

A disadvantage of this device is its complexity, due to the presence of a subtractor.

Closest to the present invention is a device comprising a circular view indicator, connected respectively to blocks of matching, reading data, scanning in both range and azimuth, an electric drive connected to an antenna simulator connected to an azimuth scanner and a synchronizing unit connected through the first trigger with

the control input of the first valve, the output of which is connected to the input of the measuring unit, coordinates the azimuth, and the pulse input - to one of the outputs of the scanner in range, which is connected via a second trigger to the control input of the second V .ntil, whose output is connected to the input of the measuring unit of the coordinate range, and the pulse input is connected to the range marker generator, the calculator, one of the outputs of which is connected to the outputs of the azimuth and range coordinates measuring units, the block for setting the amplitudes of the signals of the circuits, the input of which is connected to the imp the first input of the first valve, the amplitude determination unit of the signal of the circuit, whose inputs are connected respectively to the outputs of the measuring unit of the distance coordinate, the setting of the amplitude of the CHI circuit cables and the calculator, and the output to the output of the matching unit, the fixing units of the coordinates of the azimuth and range, whose inputs connected to the outputs of the read blocks, data, measurements of the coordinates of the azimuth and range, and the output from other inputs of the calculator. The disadvantage of the device is its complexity, due to the malfunction of the computer - a computer. In the overwhelming majority of practical cases, there are no computers at the training points for operators, which makes it impossible to use the device. On the other hand, the main requirement for the operator is only the ability to read the coordinates of the moving target. Therefore, the significant complexity of the device is not in many cases justified. The purpose of the invention is to simplify the device. The goal is achieved by the fact that in a known device containing an antenna rotation simulator serially connected to an azimuth scanner and a circular view indicator, the second input of which is connected to the output of the scanner in range, the third input to the first output of the generator, the second output which is connected to the first input of the valve, and the third output to the input of the scanner in range and to the first input of the first trigger, the second input of the valve is connected to the output of the first trigger, and the third input of the valve to the output about the trigger, the serially connected scaling pulse shaper and the first frequency divider, the second frequency divider in series, the first counter and the second counter, and the switch, the input of which is connected to the third generator output, and the output to the second input of the second counter, the third input of connected to the output of the valve, and the output to the second input of the first trigger, the input of the second frequency divider and the fourth input of the circular view indicator, the fifth input of which is connected to the second output m ranging pulse shaper whose input is connected to the second output of the simulator rotating antenna, the first input of the second flip-flop connected to the output of the first frequency divider and the second input - with the output of the second frequency divider.

Claims (3)

. The drawing shows the block diagram of the device, the device contains a block 1 of development, simulator 2 ki in azimuth, simulator 2 of rotation of the antenna, shaper 3 scaling pulses (scale azimuth marks), indicator k of circular view, generator 5 (range marks), divider 6 Frequencies , block 7 sweep in range, the first 8 and second 9 triggers, valve 10, counter P, second frequency divider 12, counter 13 and switch 1. The device works as follows. The simulator 2 is mechanically connected with the azimuth sweep unit 1 and the former 3. The unit 1 provides for the circular rotation of the indicator beam 4. The imaging unit 3 provides for the formation of pulses that illuminate the indicator 4 beam every 5 and 3A. The beginning of the sweep in range coincides with the center of the screen of the indicator, Block 7 provides the movement of the indicator beam from the center of the screen from the periphery with subsequent return to the center of the screen. The generator 5 generates pulses of scale markers of the range corresponding to each 10, 50 and LLP km. Thus, a large-scale grid is formed on the screen of the indicator j, which makes it possible to read the coordinates of the air circuits in the polar coordinates of the azimuth-range. In addition, the generator 5 .5 generates a start pulse, which starts block 7, turns on trigger 8 in one state and ensures transfer of the number recorded by Q counter 13 to counter 11. Pulses The simulated mark is fed to indicator 4 from the counter output 11. Movement of impulse-mark occurs as follows. Divider 6 has several division factors, e.g., 359,360 or 3b1. If the dividing ratio is K-3B, then trigger 9 will fail on the same azimuth as in all previous periods of sweep rotation, i.e. fb where fj; the azimuth in the i-th sweep rotation period. If K-359, then p. fi, -l °, i.e. the pulse mark will move in azimuth counterclockwise. If, then (} + 1 °, i.e., the pulse-mark will shift in azimuth in a clockwise direction. By changing the division factor K, we can achieve a greater displacement of the pulse-pulse in azimuth. Since the initial state of divider 6 is arbitrary, then the initial azimuth The generated trajectory is arbitrary within 0-ЗБО ° Turning on the trigger 9 prepares the valve 10 for opening. At the time the sweep starts, a trigger 8 from the generator 5 output turns on the trigger 8 and the pulses following with a period of, for example, 2 km, will start to flow to meter-11. , started The state of the counter 13 was zero, and the capacity of the counter 11 is 30. For certainty, the initial state of the counter 11 will also be considered zero, then the overflow of the counter 11 on the first beam will occur 60 km, which will be fixed by the indicator t. A pulse is generated to form T pulses-marks on T mixed sweep rays in range. The pulses mark turns off trigger 8 and thereby stops the operation of counter 11 on the current beam. On the next beam, trigger 8 is turned on again and counter 11 is resumed. When it overflows, the next impulse mark is displayed on the screen of the indicator 4, a luminous signal is formed, which in appearance is the same as the echo signal from the ral target. In addition, the content of the divider 12 is increased by one. Since the contents of the counter 13 have not changed to the beginning of the beam in question, the impulse-mark will go to the indicator t at the same distance. After divider 12 overflows, the contents of counter 13 will increase by one, and trigger 9 will turn on, i.e. the formation of the luminous signal on the indicator screen in the current period of the rotator is over. The capacity of the divider 12 is equal to 10-I, which corresponds to the size of the mark on the screen of the round-trip indicator from the real target. In the next period of rotation, the sweep will shift the luminance mark by range by an amount of, for example, 2 km, since the number recorded in the counter 13 differs from the similar number in the next period of rotation. The transfer of the number from the counter 13 to the counter 11 is made by a start pulse from the output of the generator 5 with the switch k closed. Switching counter 11 from Addition mode to Subtraction mode changes the direction of the loudness mark towards the periphery or toward the center of the screen. The device allows for the following trajectories of motion of the elevation marks: (radial azimuth is fixed, distance varies), circular (switch k is open, range fixed, azimuth varies), complex (azimuth and distance changes). Since the initial states of the dividers 6 and 12, as well as the counters 11 and 13 are arbitrary, the number of trajectories generated is almost infinite. The device is performed on 10–15 serial microcircuit packages. Thus, the proposed device allows for the maintenance of operators, but by much simpler technical means as compared with the prototype. The invention The device for training radar operators, containing serially connected antenna rotation simulator, azimuth sweep unit and circular view indicator, the second input of which is connected to the output of the spanner of the inverter in range, the third input to the first output of the generator, the second output of which is connected to the first input of the valve, and the third output - with the input of the scanner in range and with the first input of the first trigger, the second input. fan is connected to the output of the first trigger, and the third input or - to the output of the second trigger, characterized in that, in order to simplify the device, it contains serially connected scaling pulse generator and the first frequency divider connected in series. the second frequency divider, the first counter and the second counter, as well as the switch, the input of which is connected to the third generator output, and the output to the second input of the second counter, the third input of which is connected to the output of the valve, and the output to the second input of the first trigger, input the second frequency divider and the fourth INPUT of the circular view indicator, the fifth input of which is connected to the second output of the scaling pulse generator, the input of which is connected to the second output of the antenna rotation simulator, the first input of the second flip-flop nen with output of the first frequency divider and the second input - with the output of the second frequency divider. Sources of information taken into account in the examination 1. Rall 10. V. and others. Simulators and simulators of the Navy. M., Military Publishing, 1968, p. 51. 2. US patent W, cl. G 09 B 9 / QP, published in 1970. 3. USSR author's certificate №, cl. G 09 B 9/00, 1976 (prototype). 7 l / / / g ten g / // v / h 75