SU1195427A1 - Ternary bridge flip-flop - Google Patents

Abstract

A ternary bridge trigger containing (first, second, third, and fourth reverse transistor transistors, fifth and sixth direct conductor transistors, nine resistors and four diodes, the emitters of the first, second, third, and fourth reverse conduction transistors, The bases of the first and second reverse transistor transistors are respectively connected through the first and second resistors to a common bus and to collectors of the third and fourth transistors, respectively, of the reverse conductor, the bases of which The x are connected to the first trigger input and through the third resistor with a common bus, the direct and fifth transistor emitters are connected to the power bus, the bases through the fourth and fifth resistors respectively to the power bus, and the collectors through the first and second diodes with the collectors of the first and second reverse transistor transistors, between which the load is connected, the collectors of the first, second reverse transistor transistors and the fifth and sixth direct transistor transistors are connected to the first pins of the sixth, seventh, eighth and ninth resistors, which is due to the fact that, in order to (L increase the supply voltage range, the second pins of the sixth and seventh resistors are connected to the bases of the sixth and nth transistors of direct conduction, and the second conclusions of the eighth and ninth resistors, respectively, to the bases from the second N transistor of the first reverse transistor transistors and, respectively, through the third and fourth diodes, to the second and third trigger inputs. P1

Description

"The invention relates to a pulse technique and can be used in various electronic devices of automation and computer technology, for example, to control a reversing motor of a constant 1 cycle. The purpose of the invention is to expand the range of supply voltage. The drawing shows a schematic diagram of the ternary bridge three hera. The ternary bridge trigger contains four transses, tori 1-4 reverse conduction, fifth 5 and sixth 6 direct conduction transistors, nine resistors 7-15 and four diodes 16-1 U. The emitters of transistors 1-4 are connected to a common bus, the base transistors 1 and 2, respectively, through resistors 7 and 8 - with a common bus and with collectors, respectively, transistors 3 and 4, the bases of which are connected to perbom input 20 and through a resistor to a common bus. The emitters of transistors 5 and 6 are connected to the power bus 21, the base, respectively, through resistors 10 and 11, to the power bus 21, and the collectors, respectively, through diodes 16 and 17, with collectors of transistors 1 and 2, between which the load 22 is connected. 1,2, .5 and 6, respectively, through the resistors are connected to the bases of transistors 6,5,2 and 1. The bases of transistors 1 and 2, respectively, through diodes 18 and 19 are connected to the second and third inputs 23 and 24, and the collectors - from exits 25 and 26. The ternary bridge trigger works as follows. When the power is turned on, all the transistors are closed, the diodes 16 and 17 are biased in the opposite direction, the potentials at the outputs 25 and 26 are equal to each other and that is in the load 22 is absent. This first steady state can last indefinitely. When a positive input pulse arrives at the input 23, it passes through the diode 18 to the base of transistor 1, opens the latter and puts it into saturation mode. 7 The potential at the output 25 decreases, a current arises through the resistor 12 and the base of the transistor 6, which opens and enters saturation. This causes the diode 17 to be displaced in the forward direction, an increase in the potential at the output 26, and a current in the load 22 in the direction from the output 26 to the output 25. At the same time, a current flows through the resistor 15, which keeps the transistor 1 in a saturated state at the end of the input pulse at input 23. Thus, the trigger switches to the second steady state, in which transistors 1 and 6 are open, at output 26 is high, and at output 25 is low potentials, a current flows through load 22. When a positive pulse arrives at the input 20, transistors 4 and 3 open and enter; transistors 3 and 3 shunt the base current of transistor 1, since the voltage drop between the collector and emitter HacbmieHHoro of the transistor 3 is less than the voltage drop between the base and the emitter of the transistor t. As a result, transistor 1 closes and its collector current decreases. This will lead to a decrease in the current through the resistor 12 and the base of the transistor 6. The latter is closed and the flip-flop switches to the first stable state, in which all the transistors are closed. At the end of the pulse at the input 20, transistors 2 and 4 are closed. . Similarly, due to the symmetry of the device circuit, when a pulse arrives at the input 24, the opening and closing of transistors -2 and 5, i.e. The trigger switches to the third state, in which the input 26 is low and the potential 25 is high, in a load 22 the current flows in the opposite direction. If a positive pulse is then applied to the input 20, the trigger is similarly switched to the first state.

Claims (1)

Trinity bridge trigger containing the first, second, third and fourth reverse conductivity transistors, fifth and sixth forward conductivity transistors, nine resistors and four diodes, emitters of the first, second, third and fourth reverse conductivity transistors connected to a common bus, the base of the first and second transistors reverse conductivity through respectively the first and second resistors are connected to a common bus and to the collectors of the third and fourth reverse conductivity transistors, respectively, whose bases are connected with the first trigger input and through the third resistor with a common bus, the emitters of the fifth and sixth transistors of the direct conductors are connected to the power bus, the bases, respectively, through the fourth and fifth resistors to the power bus, and the collectors, respectively, through the first and second diodes with collectors the first and second reverse conductivity transistors, between which the load is connected, the collectors of the first, second reverse conductivity transistors and the fifth and sixth direct conductivity transistors are connected respectively to the first waters of the sixth, seventh, eighth and ninth resistors, characterized in that, in order to increase the supply voltage range, the second terminals of the sixth and seventh resistors are connected to the bases of the sixth and fifth direct conductivity transistors, respectively, and the second terminals of the eighth and ninth resistors are connected to the bases, respectively second and first reverse conductivity transistors and, respectively, through the third and fourth diodes, to the second and third inputs of the trigger.