RU2689199C1 - Flip-flop on transistors of opposite conductivity type - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to radio engineering, circuit engineering and industrial electronics. Disclosed is a trigger on transistors of opposite conductivity type, comprising a source of supply DC voltage, which common bus is grounded, in series connected first resistor, first transistor (npn) and second resistor, free terminal of first resistor is connected to output of constant voltage source, other terminal of this resistor is connected to collector of first transistor, and emitter of latter is connected to one of terminals of second resistor, and also there are series-connected third resistor, second transistor (pnp) and fourth resistor, output of the third resistor is connected to the common output of the DC voltage source and the first resistor, the other terminal of the third resistor is connected to the emitter of the second transistor, to the common terminal of the first resistor, collector of first transistor and base of second transistor capacitor is connected, free terminal of which forms trigger input and to which input pulses are supplied, and additional resistor is introduced and trigger output is determined, additional resistor is connected between "ground" and common output of second and fourth resistors.EFFECT: technical result is aimed at increase in the triggering load capacity without increasing the number of transistors in the circuit.1 cl, 1 dwg

Description

The invention relates to radio engineering, circuit design and industrial electronics. It, in particular, can be used in counters, registers and memory blocks.

The symmetric trigger is known [Gusev V.G., Gusev Yu.M. Electronics and microprocessor technology. - M .: Higher School, 2004, p. 615, fig. 8.17, a], containing two transistors, six resistors, two capacitors and constant voltage sources.

Its disadvantage is that it has a low load capacity. This is due to the fact that the electric current in the external load of the trigger is provided not by two symmetrical halves of the trigger circuit, but only by one half. External load is mainly connected to the collector of one of the transistors. If the electric current in the load would be provided by the second half of the trigger circuit, then the electric current in the load would increase significantly. But with the implementation of this, the trigger disappears the ability to perform its function. If both the selected electric currents and the first half of the trigger circuit and the second half could be directed to the external load, then the load capacity of the circuit would increase.

The counting decade is known on transistors [Shilov L.V., Tyutyunnik V.S. Counting decade on transistors. - Instruments and Experimental Technique, 1972, No. 3, p. 94-96], which contains sources of supplying constant voltages, a digital gas-discharge lamp, a capacitor, a common-elite resistor, ten triggers on transistors of opposite conductivity type, each of which includes two transistors, two resistors and a capacitor.

Its disadvantage is that each trigger in the counting decade has a low load capacity, since not all of the trigger circuit is involved in the creation of the electric current of their external load, but only a part of it (half), namely, the circuit on the npn transistor. The circuit on the pnp transistor in each trigger of the counting decade does not directly participate in the creation of the electric current of the external load.

The closest in technical essence and the achieved result is selected as a prototype, trigger with additional symmetry [Goldenberg LM Pulse and digital devices. - M .: Communication, 1973, p. 275, p.4.18, c], containing two transistors, four resistors and sources of constant supply voltage.

The disadvantage of it is that it has a low load capacity, because A relatively small part of the electric current consumed from a constant voltage source forms the electric current of an external load. The strength of this load current is only a fraction of the strength of the electric current consumed from the DC power supply source.

The problem to which the invention is directed, is to increase the load capacity of the trigger without increasing the number of transistors in the circuit and without increasing the value of the electric current consumed from the source of the supply DC voltage, and in the limit in the approximation of the value of the electric current of the external load to the value of the current consumed from a DC power supply source.

This is achieved by the fact that the trigger on transistors of the opposite conductivity type, which contains a DC power supply source, whose common bus is grounded, serially connected first resistor, first transistor (npn) and second resistor, free output of the first resistor is connected to the output of the DC power source, the other terminal of this resistor is connected to the collector of the first transistor, and the emitter of the latter is connected to one of the terminals of the second resistor, and there are also series-connected the third resistor, the second transistor (pnp) and the fourth resistor, the free output of the third resistor is connected to the common output of the source of the DC power supply and the first resistor, the other output of the third resistor is connected to the emitter of the second transistor, the collector of this transistor is connected to one of the terminals of the fourth resistor , and the base is connected to the common terminal of the first resistor and collector of the first transistor, the base of the first transistor is connected to the common collector terminal of the second transistor and the fourth cut torus, the free output of the last resistor is connected to the free output of the second, to the common output of the first resistor, the collector of the first transistor and the base of the second transistor is connected to a capacitor, the free output of which forms the trigger input and input pulses are fed to it, an additional resistor is inserted and the trigger output is defined, the resistor is connected between the “ground” and the common output of the second and fourth resistors, the output of the trigger relative to the “ground” forms the common output of the resistors of the second, fourth and complements ceiling elements.

The invention is illustrated in the drawing (Fig. 1).

Resistor 1, transistor (npn) 2, resistor 3 and resistor 4 are connected in series with each other. Resistor 1 is connected to the collector of transistor 2, its emitter is connected to resistor 3, and the free output of resistor 4 is grounded. Also resistor 5, transistor (pnp) 6 and resistor 7 are connected in series with each other. The free output of resistor 5 is connected to the free output of resistor 1, and the other output of resistor 5 is connected to the emitter of transistor 6, its collector is connected to resistor 7, and the free output of the latter connected to the common terminal of resistors 3 and 4. The base of transistor 6 is connected to the common terminal of resistor 1 and collector of transistor 2, and the base of the last transistor is connected to the common terminal of collector of transistor 6 and resistor 7. To common terminal of resistor 1, transistor collector pa 2 and the base of the transistor 6 is connected a capacitor 8. Free output of this capacitor forms a trigger input on the "land", at which input pulses are supplied. The trigger output relative to the “ground” forms the common output of resistors 3, 4 and 7. The source 9 of the supplying DC voltage is connected to the common output of resistors 1 and 5. The negative terminal of this source is grounded.

The trigger transistors of the opposite type of conductivity works as follows. It has two stable equilibrium states. In the first (conditionally) state, both transistors 2 and 6 are in a state that is non-conducting, and the output trigger voltage is almost zero. In the second (conditionally) state, transistors 2 and 6 conduct an electric current, which creates a relatively large voltage value at the output of the trigger. In the first state of the trigger, the zero values of the electric current in all circuit elements predetermines zero voltages, including at resistors 1 and 7. Zero voltage from resistor 1 is applied between the base and emitter of transistor 6, and zero voltage from resistor 7 is between the base and the emitter of the transistor 2. These zero values are smaller in absolute value of the threshold voltages of the two reduced transistors, and therefore they are maintained in a state that is not conductive to electric current.

The input pulse of negative polarity enters the base of the transistor 6 and translates it into an open state (conducting electric current). The electric current of this transistor creates a voltage drop across the resistor 7, which exceeds the threshold voltage of the transistor 2 and is applied to its base with a plus. Then the transistor 2 conducts an electric current, which on the resistor 1 creates a voltage drop, minus the applied to the base of the transistor 6. This voltage keeps the transistor 6 in the open state and after the end of the input pulse of negative polarity. The value of the voltage on the resistor 1 exceeds the threshold voltage of the transistor 6 in absolute value. Thus, the trigger is now in the second state and at its output there is a relatively large voltage value.

The input pulse of positive polarity translates the transistor 6 (npn transistor) to the closed state (not conducting electrical current). Then the zero voltage across the resistor 7, the transistor 2 is also closed and the trigger is again in the first state.

рассматриваемой схемы (фиг. 1) являются параллельно включённые сопротивление резистора 4

и сопротивление внешней нагрузки

, подключённой к выходу схемыEquivalent load

The considered circuit (Fig. 1) are in parallel with the resistor 4

and external load resistance

connected to the output circuit

(1)

(one)

изменяется в широком диапазоне значений, особенно если оно может иметь очень большое значение,

позволяет не превышать максимально допустимое значение эквивалентной нагрузки

. Имеется возможность выбирать сравнительно большие значения (и очень большие) сопротивления резистора 4 и тогда основная (большая) часть электрического тока обоих имеющихся транзисторов 2 и 6 замыкается на внешнюю нагрузку

и только небольшая (и даже весьма малая) часть этого электрического тока идёт на резистор 4. А в прототипе часть электрического тока только одной из двух имеющихся половин триггера замыкается на внешнюю нагрузку. Отсюда в рассмотренном триггере повышена нагрузочная способность без увеличения числа транзисторов в схеме и без увеличения значения силы электрического тока, потребляемого от источника питающего постоянного напряжения.Not a part of this load is closed, but the total electric currents of both existing transistors (Fig. 1).

varies over a wide range of values, especially if it can be very significant,

allows not to exceed the maximum permissible equivalent load

. It is possible to choose relatively large values (and very large) of the resistance of the resistor 4 and then the main (most) part of the electric current of both existing transistors 2 and 6 is closed to external load

and only a small (and even a very small) part of this electric current goes to resistor 4. And in the prototype part of the electric current of only one of the two existing halves of the trigger is closed to an external load. Hence, in the considered trigger, the load capacity is increased without increasing the number of transistors in the circuit and without increasing the value of the strength of the electric current consumed from the source of the supplying DC voltage.

Claims (1)

A flip-flop trigger of the opposite conductivity type, containing a DC power supply source, a common bus of which is grounded, the first resistor connected in series, the first transistor (npn) and the second resistor, the free output of the first resistor is connected to the output of the DC power supply, another output of this resistor is connected to the collector of the first transistor, and the emitter of the latter is connected to one of the terminals of the second resistor, and there are also series-connected third resistor, second transistor (pnp) and the fourth resistor, the free output of the third resistor is connected to the common output of the DC supply source and the first resistor, the other output of the third resistor is connected to the emitter of the second transistor, the collector of this transistor is connected to one of the fourth resistor's terminals, and the base is connected with the common terminal of the first resistor and collector of the first transistor, the base of the first transistor is connected to the common collector terminal of the second transistor and the fourth resistor, the free terminal after The single resistor is connected to the free output of the second, to the common output of the first resistor, the collector of the first transistor and the base of the second transistor is connected to a capacitor, the free output of which forms the trigger input and input pulses are supplied to it, characterized in that an additional resistor is inserted and the trigger output is defined , an additional resistor is connected between the "ground" and the common terminal of the second and fourth resistors, the output of the trigger relative to the "ground" forms the common terminal of the resistors of the second, fourth and additional tion.

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