SU1003307A2 - Pulse modulator - Google Patents

Description

The invention relates to a pulse technique.

According to the Main auth. No. 321929 is known a pulse modulator containing a power source, a charging device for a modulator connected to a switch, a drive, an output pulse transformer, a load in parallel to which a nonlinear correction circuit is connected, consisting of a series-connected capacitor and a diode, and a diode connected in parallel a leakage resistor and an additional switching element, the grid of which is connected to the submodule.

In the known modulator, the top and the front of the pulse are corrected simultaneously. However, the known device has the following disadvantages. The quality of the correction of the pulse top depends on the duty ratio, and when it changes by the order of magnitude, the circuit becomes inoperative. The modulator does not stabilize the amplitude of the pulses at the load, when changing the duty cycle, the supply voltage or the load resistance.

The purpose of the invention is to stabilize the amplitude of the pulses on the load and to ensure the correction of the peak of the pulses when changing the duty cycle.

The goal is achieved in a pulse modulator containing a power supply, a charger, a submodulator connected to a switch, a drive, an output pulse transformer, a load, in parallel to which a nonlinear correction circuit is connected, consisting of a series connected capacitor and a diode, with a leakage resistor and an additional switching element being parsed with the diode, a switching unit, a bias source, and a

20 comparison and the source of the reference voltage, and the output of the switching unit is connected to the grid of the additional switching element, the first input is connected to the submodule, the second

The 25th input is with the bias source, and the third input is with the output of the comparison unit, the first input of which is connected to the anode of the additional switching element, and the second input to the power source of the reference voltage.

The drawing shows a diagram of the proposed device.

The diagram shows the power source 1, charging device 2, submodulator 3, switch 4, drive 5, output pulse transformer 6, nonlinear correction circuit 7 consisting of capacitor 8, diode 9 and leakage resistor 10, load 11, additional switching element 12, switching unit 13, comparison unit 14, bias source 15, reference voltage source 16.

Parallel to the load And the modulator is connected a non-linear correction circuit 7, consisting of a series-connected capacitor 8 and a diode 9.

Parallel to the diode 9, a leakage resistor 10 and an additional switching element 12 are connected, to the grid of which the output of the switching unit 13 is connected. The first input of the switching unit 13 is connected to the submodulator 3, the second input to the bias source 15, the third input to the output of the comparison unit 14. The first input of the comparator unit 14 is connected to the anode of the additional switching element 12, and the second to the source 16 of the reference voltage.

The modulator, after establishing a stationary voltage on the capacitor 8 of the correction chain 7, operates as follows.

The positive-polarity start-up pulses from the submodulator 3 arrive simultaneously to the main switch 4 and through the switching unit 13 to the additional switching element 12, the discharge of the accumulator 5 begins. At the same time, the discharge of the capacitor 8 of the correction chain 7 to the load 11 starts through the additional switching element 12 and continues until the voltage of the main pulse (i.e. the pulse received on the secondary winding of the pulse transformer b due to the discharge of the accumulator 5) reaches the nominal nogo layer. Then, the current through the additional switching element 12 stops, since there is practically no anode voltage on it (equal to the direct voltage drop on the diode 9 of the correction circuit 7), and the load comes from the accumulator 5, while the capacitor 8 of the correction circuit 7 through diode 9 begins to charge, cutting off the irregularity at the peak of the pulse. After the accumulator 5 is discharged, the pulse at load 11 drops to zero. When the pulse of the submodulator 3 is decreasing, the additional switching element 12 is blocked by a negative bias voltage. - applied through the switching unit 13 to its grid. After the pulse drops at load 11, the voltage on the capacitor 8 of the correction chain 7 is compared with the voltage of the source 16 of the reference voltage and with the comparison unit 14 through the switching unit 13 and a signal is opened that opens the additional switching element 12. The capacitor 8 of the correction chain 7 is discharged an additional switching element 12 to a predetermined voltage level at the load, after which the additional switching element 12 is locked and the discharge of the capacitor 8 stops. As a result, the load will be A pulse is applied, the voltage of which is equal to the voltage on the capacitor 8, i.e. equal to the specified voltage on the load.

Thus, the proposed pulse modulator provides simultaneous correction of the front and the top of the pulses. In contrast to the well-known pulse modulator, it ensures the independence of the correction of the pulse peak when the duty ratio changes 200-250 times (from 2000 to 4) against 1.5-2 times in the prototype circuit and stabilizes the amplitude of the voltage pulses on the load with an accuracy of + 1- 2% when changing the duty cycle from 2000 to 4, the supply voltage by + 10% and the load resistance by + 20%.

Claims (1)

1. USSR author's certificate No. 321929, cl. H 03 K 3 / 53.21.05.70.