SU984007A2 - Sawtooth voltage generator - Google Patents

Description

(54) CURRENT GENERATOR

The invention relates to a pulse technique and can be used in the development of sweepers of transmitting television cameras.

According to the main auth. No. 907780 is a sawtooth current generator, holding an input pulse amplifier, whose input is connected to the clock source bus, and an output to the input of a double-conductor key, the output of which is bridged by a capacitor and connected via a coupling capacitor to an inductive load, a pulse current amplifier and pulse amplifier, input which is connected to the clock source bus, and the output - to the input of the pulse current amplifier, the output of which is connected to the output of the double-sided conductor key Cl.

The disadvantage of the device is the absence in the inductive load of a constant component of a current, adjustable in magnitude and direction.

The aim of the invention is to provide the possibility of regulating the constant component of the sawtooth current.

The goal is achieved by the fact that a sawtooth current generator containing an input pulse amplifier, whose input is connected to the clock source bus, and an output to the input of a two-way conductor key, whose output is bridged by a capacitor and connected to an inductive load, is a pulse current amplifier and the pulse amplifier, the input of which is connected to the bus of the source of clock pulses, and the output to the input of the pulse current amplifier, the output of which is connected to the output of the switch ground conductivity, the first and second transistors, a high voltage source, a resistor, a diode, a dc amplifier, are made through a bridge; the first power supply bus of which is connected to the power supply bus, the input of the DC amplifier is connected to the bus

25 bias sources, output to inductive load, the second power bus through the diode to the bus of the second power source, and directly to the collector of the first transistor,

The emitter of which is connected to the output of the high voltage source, and the base through the resistor to the collector of the second transistor, the emitter of which is connected to the common bus of the device, and the base to the clock source bus.

 The drawing shows a structural electrical circuit of the device.

The device contains an input amplifier 1 pulses, a double-sided conduction switch made on transistor 2 and diode 3, capacitors 4 and 5, inductive load 6, pulse current amplifier 7, pulse amplifier 8, first and second transistors 9 and 10, high voltage source 11, resistor 12, diode 13, amplifier 14 dc, made by the bridge circuit on the trans. the resistors 15-18, the resistors 19-21, the first and second sources 22. and 23 power supplies of different polarities, the bus 24 of the bias source.

The device works as follows.

The sync pulses supplied to the input of amplifier 1 are amplified to a power level such that reliable unlocking (saturation) of transistor 2 is ensured during the forward sweep stroke and its locking during reverse. With open transistors 2 and diode 3 (forward sweep), an inductively applied voltage applied to the capacitor 5 is applied to the capacitor 5 for the first few sweep periods after turning on the generator. The current in inductive load b is changed by a law close to linear, first decreasing to zero, and then, reversing the direction, increases. During the forward stroke, the voltage on the capacitor 5 decreases. When the transistor 2 is locked at the input by the clock pulses in the circuit, the capacitor 4 - the load b is provided by an oscillatory process (reverse sweep).

The capacitance value of the capacitor 5 is many times greater than the capacitance value of the capacitor 4, and therefore the capacitor 5 influences the oscillatory process in the loop. The current in this circuit is first reduced, and then, changing the direction to the opposite, begins to increase. Voltage n load b varies sinusoidally, and the polarity of this voltage is such that under the action of its diode 3 is locked. The sync pulses received during the reverse run of the sweep to the input of the amplifier 8 pulses are amplified by this amplifier and fed to the input of the amplifier 7 of the pulsed current. Under

the action of these pulses at the output of the pulsed current amplifier flows almost constant current, closing on the capacitor 5 and the load b. With this current, the capacitor 5 is recharged and the voltage across it during the return stroke increases by the amount it decreases during the forward sweep stroke. The pulse current amplifier 7 does not have a shunting effect on the oscillating circuit, since its output impedance is chosen such that it significantly exceeds the characteristic impedance of the circuit.

In the absence of a direct current at the input of the amplifier 14, the direct current at the output of it, and hence in the load, the direct current does not flow: the flow of the constant component of the current in the load b from the amplifier 7 of the pulse current is prevented by a capacitor 5. During the reverse of the sweep transistor 10 is unlocked by clock pulses, and in the circuit the collector-emitter gap of transistor 10, resistor 12, the base-emitter junction of transistor 9 and high voltage source 11 carries pulsed current. If there is no current at the output of the direct current amplifier 14, its output transistors 15 and 16 are locked and the collector current in the transistor 9 does not flow,

The supply to the input of the amplifier 14 of direct current flowing in such a direction that unlocks

0 the output transistor 16 of the amplifier will cause a flow of direct current in the circuit of the power supply source 22 — the output transistor 16 — inductive circuit. on load b. The magnitude of this current

5 is determined by the current value at the input of amplifier 14.

 If the current of the other direction is supplied to the input of the direct current amplifier 14, then a direct current will flow in the circuit. Inductive load b - the circuit of the output transistor 15 of the direct current amplifier 14, and closes during the course of the diode 13 and the source 23 meals. During reverse, this current will close to the collector-emitter gap of transistor 9 and high voltage source 11, since during this period of the sweep period the diode 13 is blocked by a pulsed voltage due to this source 11 at the diode connection point. 13 with a DC amplifier 14 and a collector of an unlocked transistor 9. Since it is

the pulse voltage exceeds the magnitude of the pulse voltage appearing on the load 6 during the reverse sweep, then the output transistor 15 of the DC amplifier operates in a linear mode. For this reason, the output current of the indicated transistor during the reverse stroke will be almost the same as during the forward one, since the output current of the working in the linear mode of the transistor is determined by the input current and practically not from the value of the supply voltage.

The bridge-type DC amplifier, in the form of output transistors 15 and 16 and input transistors 17 and 1b, operates as follows.

In the absence of current at the input of the amplifier 14, the input transistors 18 and 17 are locked due to the absence of bias at their transitions to the base-emitter. The output transistors 15 and 16 are also locked, as there are no currents in their base circuits. The offset of the input current amplifier 14 of the base-emitter junction of one of the input transistors 18 or 17 causes current to flow in the collector circuit of transistor 18 or 17 and simultaneously to the base circuit of transistor 15 or 16. This, in turn, will cause the flow current of the output transistor 15 or 16, and hence the direct current at the output of the amplifier 14.

In this operation, the proposed sawtooth generator in deviating coils creates a constant current component that is adjustable in magnitude and direction without using inductors with cores having large dimensions and weight.

Claims (1)

1. USSR author's certificate 907780, cl. H 03 K 4/50, 12.26.79