SU953710A2 - Pulse shaper - Google Patents

Description

(5) PULSE FORMER

one

The invention relates to a pulse technique and can be used in amplifiers or oscillators to obtain output pulses with an amplitude exceeding several times the voltage of the power source.

According to the main auth. A no-name pulse generator is used to produce output pulses with an amplitude exceeding several times the voltage of the power supply, containing an input transistor with a collector resistor and a voltage multiplying circuit consisting of several cells, each of which contains a transistor and its base resistor, capacitor, shunt and charge diodes. In the known device, in one part of the pulse period, the capacitors are charged in parallel from the power source, and in another part of the period, the power source, the collector resistor of the input transistor and the charged capacitors are connected in series with respect to the external load, resulting in An output pulse is formed there, the amplitude of which can be several times higher than the voltage of the power source.

10 is that a significant part of the amplitude of the output pulse is lost on the collector resistor of the input transistor, especially when comparatively large current values of the load are lost, which leads to a decrease in the amplitude of the output pulse. In addition, on the specified collector resistor, a significant amount of power is consumed as in the pause between

Claims (2)

20 pulses, and during the formation. output pulse, which reduces the efficiency, efficiency) of the device. 3 The aim of the invention is to increase the efficiency and increase the amplitude of the output pulses of the device. This goal is achieved by the fact that an additional transistor and a diode are inserted into the pulse shaper, which is connected between the capacitor and the anode of the charge diode of the first cell, and parallel to the additional diode is included the base-emitter junction of the additional transistor whose collector is connected to the ungrounded power supply pole. The drawing shows the principle on the electrical circuit of the pulse shaper. The driver contains a transistor 1, a voltage multiplying circuit consisting of cells, each of which contains a transistor 2, a shunt diode 3, a capacitor t, a charging diode 5, a base resistor 6, a load 7, a collector resistor 8, a diode transistor switch for additional diode 9 and the transistor 10. The pulse shaper operates as follows. In the initial state, when there are no negative polarity input pulses, the transistor 1 is open by a positive voltage, for example, supplied through a resistor (not shown) to its base from the ungrounded power supply pole. At this time, transistors 2 and transistor 10 are closed by reverse bias at their base-emitter junctions created by direct voltage drops on diodes 3 and 9, and capacitors k are charged from the power source through diodes 3.5.9 and open transistor 1. The voltage on the external load 7 is equal to the voltage on the collective-emitter junction of the open transistor 1 and is close to zero. When a negative-polarity input pulse is applied to the base of transistor 1, transistor 1 closes and transistors 2 and 10 open. Transistor 10 opens due to the flow of a portion of the discharge current of capacitors k through the circuit: base-emitter junction of transistor 10, j pH sensor, emitter-base junction of transistor 2, resistor 6, resistor 8. Similarly, transistors are opened 2. Diodes 3.5 and 9 are closed at this time with voltages across capacitors Oi f applied to the diodes in the blocking direction. Thus, during an input negative pulse, power supply E, collector-emitter junction of transistor 10 and charged capacitors k through open transistors 2 are connected in series with respect to external load 7 and generate a voltage pulse at this load, the amplitude of which is close to 4E where E is the voltage of the power supply. With the end of the input pulse, transistor 1 opens and transistors 2 and 10 close, as a result of which the voltage at load 7 drops to the value viscous to zero. When the following negative-polarity input pulses are applied to the base of transistor 1, the pulse shaper operates in a similar way. The shaper can also operate from positive-voltage pulses if the base of transistor 1 is not applied with a positive, bias voltage. In this case, increased amplitude output pulses will form in the pauses between the input pulses. When using a negative-polarity power source, diodes 3.5 and 9 must be connected in the opposite direction, and transistors replaced with transistors of the opposite conductivity type. To speed up the process of opening the transistor 2 in parallel with the base resistor 6, a capacitor can be connected in each cell. By varying the number of cells in the voltage multiplying circuit, it is possible to obtain the necessary amplitude of the output pulses. In the device during the formation of the output pulse, the load current flows predominantly not through the collector resistor 8, but through the collector-emitter junction of the open transistor 10. The resistance of the collector-emitter junction of the open transistor 10 is small and, therefore, only a small part of the output amplitude is lost on it voltage and power. Due to the low resistance of the collector-emitter junction of the open transistor 10 and a small voltage drop across it in the device, the load capacity significantly increases, the efficiency and the amplitude of the output pulses increases, as compared with the known device. Claims pulse shaper: according to bus no., Characterized in that, in order to increase efficiency and increase the amplitude of output pulse 10, an additional transistor and a diode are inserted, which is connected between the capacitor and the anode of the charge diode of the first cell, and parallel to the additional diode A base-emitter junction of an additional transistor is connected, the collector of which is connected to the ungrounded pole of the power supply. Sources of information taken into account in the examination 1. USSR Author's Certificate No. Ц5138, cl. H 03 K 5/01, 29.05.72.