SU930594A1 - Square-wave pulse generator - Google Patents

Description

The invention relates to a pulse technique and can be used in various automation devices, telemechanics and computer technology as a master generator of pulses of the millisecond and second ranges. A known generator of rectangular pulses, containing a trigger with separate inputs, two null-bodies, included in the diagonal of two bridge timing circuits l. The disadvantage of such a generator is the large amount of time of the driving capacitors. A known generator of rectangular pulses, containing a trigger with separate inputs, two zero-organs, each of which is made on two transistors of different conductivity, is given time (capacitors and two resistors, however, this generator of rectangular pulses has a low stability of the pulse frequency, because the trigger threshold of null-bodies depends on the load on the trigger, and the small range of generated frequencies, since the maximum values of the time of the setting resistors are limited by the magnitude of the switching current of the trigger The purpose of the invention is to increase the stability of the pulse frequency and expand the frequency range. For this purpose, a square pulse generator containing a symmetric trigger with cross-section collector-base resistor connections specifies the RC chain and two zero-organs, the time specifying the RC circuit is connected between the power supply buses, the signal inputs of the zero-organs are combined and connected to the midpoint of the time set by the RC circuit. the control inputs of the Hyjlb-organs are connected to the trigger outputs, and the outputs of the null-orgs are connected (by opposite trigger inputs. Each of the zero-organs is made on two transistors of different conductivity and a voltage divider on two resistors, with the emitter of the first transistor connected to the signal input the zero-body, its base and the collector are connected respectively to the collector and the base of the second transistor of opposite conductivity, the emitter of which is connected to the output of the zero-body, the first output of the resistor voltage divider connected to the power bus, its middle point is connected to the base of the first transistor, and the second output is connected to the control input of the zero-organ. To reduce the interference caused by the zero-organs at the Trigger outputs, the control inputs of the zero-organs can be connected to the outputs trigger through diodes. The drawing shows the electrical circuit diagram of a square pulse generator. The square pulse generator contains a symmetric trigger with separate inputs, made on transistors 1 and 2, 3-8i time, sets the resistor RC-c A pair of resistor 9 and a capacitor 10, two zero bodies 11 and 12, each of which contains two 13I T transistors with different conductivity, and a voltage divider of resistors 15 and 16. Each nullorgan has a signal input 17, a control input 18 and output 19. The generator is powered from the power bus 20, the generator has outputs 21 and 22. The diodes 23 and 2k can be entered into the generator circuit. The square-wave generator operates as follows. When the power is turned on, the trigger on transistors 1 and 2 is set to one of the stable states. Suppose that the trigger is set to such a state when transistor 1 is open and transistor 2 closes the potential at output 21 close to zero and output 22 is high. The operating voltage of the null organ 11 is approximately half the supply voltage, since the resistors 15 and 16 of the zero organ voltage dividers are equal and the zero organ divider 11 is connected to the common bus through the open transistor 1, and the actuation voltage the null organ 12 will be significantly higher, since the transistor 2 is closed and there will be no current through the voltage divider of this null organ, and therefore there will be no voltage drop across the resistor 15 of this divider. The capacitor 10 is charged from the power bus through a resistor 9. When the voltage on the capacitor 10 increases the voltage of the zero-body actuation 11, the transistors 13 and Ik of the latter open and enter saturation due to the positive feedback between the transistors 13 and 1. Condenser 10 is discharged through the saturated transistors 13 and 1 of the zero-body 11 and the transition emitter base of transistor 2, which leads to the opening of the latter and switching the trigger to the opposite state, in which transistor 2 is open and transistor 1 is closed. After the capacitor 10 is discharged, the transistors 13 and 1 of the null organ 11 are closed. In this state, the operation voltage of the null organ 12 is lower than that of the null organ 11 because the transistor 2 and the voltage divider on the resistors 15 and 16 of the zero organ 12 are connected to the common bus. Therefore, in the next charge cycle of the capacitor 10, transistors 13 and Z null organ 12 turn on and become saturated, which leads to the discharge of capacitor 10 through the base-emitter junction of transistor 1 and resetting the trigger to the initial state. Further, the trigger switching cycles are repeated. Connecting the zero-bodies to the trigger outputs in such a way that the zero-body connected to the open transistor triggers, significantly increases the frequency of the generator pulses and makes it independent from the load on the trigger, because the voltage on the collector of the saturated transistor is almost independent of the load on the trigger, and is determined by the voltage on the collector of the saturated transistor (i.e., the parameter of the transistor itself. In this rectangular pulse generator, an extended range of g neratsii (i.e. more DLI7 Tel'nykh pulse repetition period) because flip-flop switched current discharge time of capacitor master

(i.e., due to the energy stored in the capacitor), and therefore the maximum value of the time of the setting resistor is not limited by the condition of the magnitude of the switching current of the trigger.

With the values of resistors 15 and 16 of the voltage dividers of zero-organs commensurate with the size of the collector resistors 3 and 8, which can be observed in the region of small pulse periods, diodes 23 can be included to reduce the interference caused at the outputs of the tri1-ger by zero-organs. and 2A.

Claims (3)

1. A square pulse generator containing a symmetric trigger with cross collector base resistor connections, two null organs and an RC driver circuit, characterized in that, in order to increase the stability of the period of generated pulses, the RC clock circuit is connected between power supply, signal inputs of on-organs are combined and connected to the midpoint of the time of the driving RC circuit, control inputs of the zero organs are connected to the trigger outputs and outputs of the zero-organs are connected to opposite trigger inputs pa. 2. The generator according to claim 1, characterized in that, in order to expand the range of generated frequencies in the direction of increasing the oscillation period, each of the zero-op anov is made on two transistors of different conductivity and a voltage divider on two resistors, with the emitter of the first transistor connected to the signal input of the zero-organ, its base and collector are connected respectively. the collector and the base of the second transistor of opposite conductivity, the emitter of which is connected to the output of the zero-organ, the first terminal of the resistor voltage divider is connected to the power bus, its middle point is connected to the base of the first transistor, and the second terminal is connected to the control input of the zero-organ. 3. Generator on PP. 1 and 2, in order to increase the noise immunity, the control outputs of the null organs are coupled to the trigger outputs via diodes. I, Sources of information taken into account in the examination 1. Author's testimony: About the USSR M 3362it, cl. H 03 K 3/282, 1971. 2. USSR author's certificate number 39E02, cl. H 03 K 3/26, 1972.