SU417904A1 - - Google Patents

Description

one

The invention relates to scaling circuits and can be used in high-speed automation and computing devices.

Known multistable triggers built on identical cascades and containing emitter followers, triggers on tunnel diodes and an inverter on a transistor.

However, these triggers require, in order to prepare for the launch of the first stage, a complete return of the circuit to the initial state, which limits the frequency of operation of the device.

The purpose of the invention is to increase the speed and reliability of the circuit.

This is achieved by the fact that in a multistable trigger each trigger on the tunnel diode, except the trigger on the tunnel diode of the first stage, is connected to the load circuit of the emitter follower, whose input is connected to the anode of the tunnel diode of the previous trigger on the tunnel diode, and to the output of the trigger diode of the tunnel diode. The last stage is connected to the base of the inverter transistor, the collector of which is connected through resistors to the anode of each tunnel diode of the trigger on the tunnel diode and through another resistor to the power supply .

FIG. 1 shows the electrical circuit

2

multistable trigger; in fig. 2-volt ampere characteristic of a tunnel diode.

A multistable trigger contains n identical stages and a reset stage (). Each stage of a multistable trigger consists of an input capacitor, a trigger on a tunnel diode, a load resistance of a trigger, a transistor acting as an emitter follower, a load resistance of a trigger of a subsequent stage.

The reset stage includes a transistor inverter, the base of which includes a trigger on the tunnel diode, and collector resistance.

In the initial state, a current flows through the resistances 1-5 and through the triggers on the tunnel diodes 6-10. The current passing through the tunnel diode 6 is equal to / l (point L in Fig. 2). The currents flowing through the remaining tunnel diodes are equal in magnitude, and the magnitude of the current / a flowing through a separate diode (point a. In Fig. 2) is greater than the current value of the minimum of the tunnel diode, but less than the current / l. All tunnel diodes are in a low voltage state. Electronic keys formed by transistors 11-15 are closed.

Thus, the trigger. On the tunnel diode 6 is prepared for start, as in the outgoing position a current close to the current of the maximum of the tunnel diode flows through it.

With the arrival of the first counting pulse, the tunnel diode 6 switches to a high voltage state (point B in Fig. 2). At the same time, the current flowing through the tunnel diode 7 rises to the value of / A, i.e., it is prepared for start.

With the supply of its next pulse, the trigger on the tunnel diode 7 switches to the high voltage state and the transistor 11 closes, the triggers on the tunnel diodes 6 and 7 remain in the high voltage state, since the currents passing through them through the circuits 1 6 and 7-2, greater than the minimum current of the tunnel diode.

This process is repeated until the arrival of tt + 1th pulse, which switches the tunnel diode 10 of the last stage to a high voltage state. A transistor inverter (15) opens and shunts tunnel diodes. The amount of current flowing through them is reduced to a value less than the minimum current of the tunnel diode, which causes the circuit to return to its original position. In this case, all tunnel diodes are switched to the low voltage state. This return is achieved by simultaneously switching only the tunnel

diodes from high to low state, as in the process of recalculation the electronic keys are closed.

Thus, the device provides an increase in speed and greatly simplifies the electrical circuit of the multistable trigger.

Subject invention

Multistable trigger built on identical cascades and containing emitter repeaters, triggers on tunnels

diodes and an inverter on the transistor, characterized in that, in order to increase speed and reliability, each trigger on the tunnel diode, in addition to the trigger on the tunnel diode of the first stage, is included in

the load circuit of the emitter novater, whose input is connected to the anode of the tunnel diode of the previous trigger on the tunnel diode, and a base is connected to the output of the trigger on the tunnel diode of the last cascade

an inverter transistor, whose collector through resistors is connected to the anode of each tunnel diode of a trigger on the tunnel diode and through another resistor to the source of the thread.

FIG. 2