CS272492B1 - Digital pulse generator connection - Google Patents

Abstract

The pulse generator is intended mainly for bipolar control of four-quadrant pulse converters. It solves the problem of digital compatibility with digital control circuits, the problem of accurate repeatable adjustment of the duty cycle setpoint and its sufficient fineness of adjustment. The duty cycle setpoint is fed to the adjustment circuit (6) and the test circuit (3) via terminal (38). The test circuit (3) tests for inadmissible states and the adjustment circuit (6) adjusts them. The tested and adjusted duty cycle setpoint is fed to the input of the counter (10) and the driver. which reads from the set duty cycle values. After counting to zero, it generates a pulse. Both counters (14, 18) of safety gaps operate similarly. The flip-flops (27, 21, 24) generate a pulse of the desired value of the first safety gap, a pulse of the desired value of the duty cycle, an additional pulse to the pulse of the desired value of the duty cycle and a pulse of the desired value of the second safety gap. The product circuits (30, 32) generate from these pulses pulses of the desired and additional value of the duty cycle shortened by the pulses of the safety gaps. These signals are impedance-adjusted in the output circuits (33, 34).

Description

The present invention relates to a digital pulse generator that allows control of four-quadrant pulse converters. The output frequency of its signal can be up to 200 kHz and the minimum number of decrements per period at this frequency! to 256. Said connection solves the problem of precise repeatable AC setting, reliable generation of the output signal in the region of kHz and the compatibility of the generator with a digital microcomputer control loop.

Previous methods of connecting pulse generators for bipolar control of four-quadrant pulse converters use elements of analog technology to generate the output signal. The disadvantage of the mentioned solution is that it does not allow precise repeatable setting of the output signal and that when generating the output signal with frequencies of the order of hundreds of kHz, distortion, nonlinearity and faults occur, which are manifested mainly in the cooperation of the pulse generator with the power circuit. More modern methods of pulse generator solutions use digital circuits of microcomputers for this purpose. However, such a solution blocks the calculation time of the microcomputer, by which the calculation time required for the calculation of the control circuit is then depleted. The mentioned solution also has the disadvantage that the used digital circuits of the microcomputer do not allow the generation of the output signal with a minimum number of 256 decrements per period with frequencies more than 10 kHz.

The above-mentioned drawbacks are eliminated by the connection of a pulse generator according to the invention consisting of a pulse source, a conditioning circuit, a test circuit, an AC counter, a period counter, two safety gap counters, three flip-flops, two product circuits and two output circuits. that the AC setpoint terminal is connected to the input of the test circuit and the first input of the conditioning circuit. The output of the test circuit is connected to the second input of the conditioning circuit. The output of the conditioning circuit is connected together with the output of the period counter and the output of the pulse source to the first, second and third inputs of the AC counter. The first and second inputs of the first safety gap counter are connected to the output of the period counter and the output of the pulse source. In addition, however, the third input is connected to the setpoint terminal of the first safety gap. The output of the first safety gap counter together with the output of the period counter is connected to the second and first inputs of the first flip-flop, the output of which is fed to the first and second product circuits with the first output of the second flip-flop. The output of this circuit is connected to the input of the first output circuit, the output of which is the first output of the pulse generator. The first and the second input of the counter druhaj security Me Space bar to Jena _S p _is the output of the counter and the duty cycle output of the source pulse. Again, as with the counter of the first safety gap, the terminal of the setpoint of the second safety gap is also connected to its third input. The output of the second safety gap counter is connected together with the output of the alternating current counter to the first and second inputs of the third flip-flop, the output of which is connected to the first and second inputs of the second product circuit with the second output of the second flip-flop; the output of the product circuit is connected to the input of the second output circuit, the output of which is the second output of the pulse generator. The outputs from the AC counter and the period counter are connected to the first and second inputs of the second flip-flop circuit.

The advantage of this connection is that it allows to achieve an output signal with at least 256 decrements per period of frequency! up to 200 kHz. It also allows precise repeatable setting of the output signal and is compatible with a microcomputer control circuit.

The accompanying drawing shows a block circuit of a digital pulse generator for bipolar control of four-quadrant pulse converters with a switching frequency of up to 200 kHz, according to the invention.

The AC setpoint terminal 38 is connected to the first input 4 of the control circuit 6 and the input of the test circuit 3, the output of which is connected to the second input 5 of the control circuit 6. The output of the conditioning circuit 6 is connected to the first input 7 of the alternator 10, to the second input 9 of which the output of the counter 2 of the period and the third

CS 272 492 B1 2 th input 8 js connected output from the pulse source jL. The output of the alternating counter 10 is connected to the first input 22 of the second flip-flop circuit 24 and to the second input 20 of the reed flip-flop circuit 21. The second input 13 of the counter 14 of the first safety gap is connected to the output of the source j. impulses. The first input 12 of the counter 14 of the first safety gap is connected to the output of the counter 2 of the period. The third input 11 of the first safety gap counter 14 is connected to the first safety gap setpoint terminal 39. The output of the counter 14 of the first safety gap is connected to the second input 25 of the first flip-flop 27, to the first input 26 of which the output signal from the counter 2 of the output is connected. The output of the first flip-flop circuit 27 is connected together with the first output 35 of the second flip-flop circuit 24 to the first input 28 and the second input 29 of the first product circuit 30. The output of the first product circuit 30 is connected to the input of the first output circuit 33 whose output is the first output. from the pulse generator. An output from the shift counter 10 is connected to the first input 17 of the counter 18 of the second safety gap. The output from the pulse source 1 is connected to the second input 16 of the counter 18 of the second safety gap. The second safety gap setpoint terminal 40 is connected to the third input 15 of the second safety gap counter 18. The output of the second safety gap counter together with the output of the alternating counter 10 is connected to the first and second inputs 19, 20 of the third flip-flop 21, the output of the third flip-flop 21 and the second output 36 of the second flip-flop 24 are connected to the first and second inputs product circuit 32, the output of which is connected to the input of the second output circuit 34. The output of this circuit is also the second output of the pulse generator. The second input 23 of the second flip-flop 24 is connected to the output of the AC counter 10.

The binary form setpoint signal connected to the binary setpoint set terminal 38 enters the control circuit 6 through the first input 4. It also enters the test circuit 3. If the binary AC setpoint expression may have eight or more bits and may acquire limit states, i.e. zeros on all bits or units on all bits, which the proposed pulse generator cannot process, so the test circuit 3 evaluates these states. By its output via the second input 5 of the adjustment circuit 6, in case of detecting an illegal combination, the test circuit 3 activates the adjustment circuit 6, which adjusts the lowest weight bit of the digital form of the AC setpoint so that it changes to additional and thus does not disturb the pulse generator. of the invention. The setpoint value of the output from the output of the conditioning circuit 6 is connected to the first input 7 of the AC counter 10. The period counter 2 counts the pulses coming to its inputs from the source j. impulses. After counting to the final value and restarting the reading, since the period counter 2 operates cyclically, a pulse is generated at its output, which is fed to the second input 9 of the alternating counter 10 and which causes the alternating counter 10 to be set to the value given by the signal at the first input 7. A signal from the source j arrives at the third input 8 of the AC counter 10. pulses, which causes the shift counter 10 to read from the set value, by means of signals on the first and second ⁶ inputs 7 and 9 downwards. After reading to zero, the AC counter 10 generates at its output a pulse equal to one pulse of the source j. impulses. As well as the counter 10 of the shift, after reading to zero, it continues to read down cyclically from the highest possible value, which it jumps, so we must ensure the same time length of the cyclic reading of the counter 2 of the period and the counter 10 of the shift. We must therefore choose the connection of both mentioned counters so that the maximum value that can be obtained during cyclic reading, expressed by logical zeros and units on the individual counter bits of the counters, is exactly the same. As will be described below, the counter 14 of the first safety gap and the counter 18 of the second safety gap read cyclically and must therefore switch said connection condition as well. The first safety gap counter 14 operates similarly to the shift counter 10. The first input 12 of the counter 14 of the first safety gap also receives an output pulse from the counter 2 of the period, which causes the counter 14 of the first safety gap to be set to the value of the desired first safety gap expressed in binary form ti

CS 272 492 B1 and fed via the setpoint terminal 39 of the first safety gap in binary form to the third input 11 of the counter 14 of the first safety gap. The signal from the pulse source 11 fed to the second input 13 of the first safety gap counter 14 causes the counter 14 of the first safety gap to read downwards from the set value. When read to zero, the counter 14 of the first safety gap generates a pulse equal to one pulse from the source j at its output. impulses. The second safety gap counter 18 operates in the same way as the first safety gap counter 14, only the setting signal applied to its first input 17 is the output signal of the alternating counter 10. The second safety gap setpoint is fed through the second safety gap setpoint terminal 40 to the third input 15 and the signal from the pulse source JL to the second input 16. After reading the second safety gap counter 18 from the second safety gap setpoint to zero. the pulse is generated at its output equal to one pulse from the source of 1 pulses. An output pulse of a period counter 2 is applied to the first input 26 of the first flip-flop circuit 27, which flips the output of the first flip-flop circuit 27. Its output pulse is applied to the second input 25 of the first flip-flop circuit 27. flip-flop circuit 27 to the flooded state which it had before the arrival of the pulse from the output of the counter 2. This generates a time-length pulse by the desired value of the first safety gap at the output of the first flip-flop circuit 27. The second flip-flop circuit 24 operates in the same way as the first flip-flop circuit 27. It is first flipped by an output pulse from the period counter 2 to the second input 23. The flipping of its output to the flood state is caused by 35 generates a pulse of the AC setpoint from the second flip-flop 24. The second output 36 of the second flip-flop circuit 24 generates an additional pulse to the pulse at the output 35. The third flip-flop circuit 21 operates in the same way as the two previous ones. For the first time, it is flipped by an output pulse from the AC counter 10 applied to the second input 20 of the third flip-flop 21, to the original position it is flipped by an output pulse from the second safety gap counter 18 to the first input 19. of a time length equal to the value of the second safety gap. The output signal of the first flip-flop circuit 27 is connected to the first input 28 of the product circuit 30. The output signal from the first output 35 of the second flip-flop circuit 24 is connected to the second input 29 of the same circuit 30. The first product circuit 30 makes the product of these two input signals. at its output we get a signal as at the first output 35 of the second flip-flop 24, only at the beginning shortened by the time interval of the setpoint of the first safety gap. The first output circuit 33 adjusts this signal so that the first output from the pulse generator is short-circuit proof. The second product circuit 32 is the product of the output signal of the second flip-flop 24 sensed from the second output 36 and connected to the second input 37 of the second product circuit 32 and the output signal of the third flip-flop 21 connected to the first input 31 of the second product circuit 32. Output pulse from the second product circuit. 32 is equal to the output of the output pulse at the first output 35 of the second flip-flop 24 shortened at the beginning of the pulse by the duration of the desired second value of the safety gap. The output signal of the second product circuit 32 is adjusted in the second output circuit 34 so that the second output from the pulse generator is also short-circuit-proof. The setpoints of the AC and safety gaps are expressed in binary form and are actually combinations of logic zeros and units in binary code that specify a number in the decimal system that determines how many pulses from the pulse source must arrive at the counter to count these pulses. equal to the setpoint of the duration of the shift or of the individual safety gaps. The output frequency and the number of decrements per period is given by the frequency of the pulse source, which can be variable with the maximum value to which all counters read.

The connection of the pulse generator according to the invention can be used mainly for bipolar control of four-quadrant pulse converters.

Claims (1)

CS 272 492 B1 OBJECT OF THE INVENTION Connecting a bipolar digital pulse transducer to four quadrant pulse transducers with a 200 kHz switching friction consisting of a pulse source, an adjustment circuit, a test circuit, an alternator, a period counter, two counter safety gaps, three flip-flops, two product circuits, and characterized in that the setpoint terminal (38) is alternated by the first input (4) of the adjustment circuit (6) and the input of the test circuit (3), which output is connected to the second input (5) of the adjustment circuit ( 6), the output of which is connected to a first input (7) of the alternator reader (10), to which the second input (9) is connected to an output of a period counter (2) having an input connected to the output of the pulse source (1), is also connected to the third input (8) of the alternator reader (10), the output of which is connected to the first input (17) of the reader (18) a second security gap having a third input (15) coupled to a setpoint terminal (40) of a second security gap and to which second input (16) an output of the pulse source (1) is connected, also connected to a second input (13) of a first security gap reader (14), whose third input (11) is coupled to a setpoint terminal (39) of a first security gap whose first input (12) is connected to the output of the counter (2) period which is also connected to the first input (26) of the first flip-flop (27), the second input (25) of which is connected to the output of the first security gap reader (14) whose input (12) is connected to the second input (23) a second flip-flop (24) to which an output of an alternate reader (10) is connected to the first input (22), the output of which is also connected to a second output (20) of the third flip-flop (21) whose first input (19) is connected to the output of the flip-flop (21) second security gap detector (18) and that output from the third flip-flop (21) connected to the first input (31) of the second product circuit (32), the second input (37) of which is connected to the second output (36) of the second flip-flop (24) ) whose first output (35) is connected to a second input (29) of a first product circuit (30), the first input (28) of which is connected to the output of the first flip-flop (27), and the output of the first product circuit (30) is coupled to the first output circuit (33), the output of which is the first pulse generator output, and the output of the second circuit (32) connected to the input of the second output circuit (34), the output of which is the second output of the pulse generator. 1 drawing