SU864539A1 - Driven multivibrator - Google Patents

Description

(54) WOMAN MULTI VIBRATOR

one

The invention relates to a pulse technique and can be used in microelectronic devices as a generator of single pulses.

Searched multivibrators with thermal coupling are known, containing a thermal-electronic element and a threshold element based on a Schmidt trigger, whose input is connected to the output of the thermal-electronic element, and one of the outputs to its input 1.

However, these devices are characterized by a long recovery time and low noise immunity.

The closest in technical essence to the present invention is a device comprising a thermoelectronic element with two inputs, a threshold and trigger elements, the outputs of which are connected to the inputs of the thermal electric element 2.

The launch of the circuit is controlled by a short trigger pulse, as a result of which the device has a low noise immunity. The recovery time of the device to its original state is determined by the time of the thermal electronic element, which is commensurate with the time of the generated pulse.

The aim of the invention is to reduce the recovery time of the circuit to its original state, increase the noise immunity and enhance the functionality.

The goal is achieved by the fact that in a waiting-multivibrator containing a thermal-electric element with two inputs and a threshold element

The output of which is connected to the input of the heat-electronic element is connected to an additional threshold element, and one of the inputs of the thermal-electronic element is separated from the output of the additional threshold element and the input of the device by the OR element.

In addition, the outputs of the threshold elements are separated from one of the outputs of the multivibrator element I.

20

Figure 1 shows the standby multivibrator; figure 2 - the timing diagram of the processes in the device.

Standby multivibrator contains

25 a heat-electronic element 1, to the output of which the inputs of the threshold element 2 and the additional threshold element 3 are crimped. The output of the threshold element 2 is connected to the first input 4 of the thermal-electronic element 1,

30 to one of the inputs of the element And 5 and through the inverter b to the first output 7 of the device. The output of the additional threshold element 3 is connected to the second output of the device 8, to the second input of the element AND 5 and to one of the inputs of the element OR 9. The output of the element AND 5 is connected to the third output 10 of the device. The other input of the element OR 9 is connected to the input 11 of the device, and the output to the second input 12 of the thermoelectronic element a 1. Figure 2 shows the laws of variation of the voltage at the input 11 of the device, at the second input 12 of the thermal electronic elec ment 1, at the first input 4 of the thermoelectronic element, the law of variation of the variable component power in the thermoelectronic element, the law of variation of the voltage at the output of the thermoelectronic element 1, at the first output 7 of the device, at the second output 8 and the third output 10 of the device. Short pulse 13 corresponds to the interference signal, pulse 14 is the triggering element, Thermoelectronic element 1 contains two heat sources, one of which is connected to the first one, and the second to the second input, and a temperature difference sensor that registers the difference between the heat sources. The allocation of power in the first source occurs when the first input 4 of the thermoelectronic element 1 is absent. Power allocation in the second source occurs when a voltage is applied at the second input 12. A higher power value can be dissipated in the first heat source than in the second. The voltage at the output-heat-electronic element is proportional to the temperature difference between the heat sources. The upper trigger threshold uj, threshold element 2 is higher than the trigger threshold, and threshold element 3. Both threshold elements have the same lower trigger threshold. In the initial state, the voltage at the inputs 11 and 12, the output of the thermoelectronic element and the outputs 7.8 and 10 of the device is zero. When a short forcing impulse device 13 (Fig. 2) appears at the entrance 11 of the device, a pulse of the same duration appears at the second input 12 of the thermal element. In the second heat source, power begins to dissipate. The temperature of the second source rises, and at the output of the heat-electric element 1, the voltage V begins to change in accordance with the law of variation of the temperature difference between the heat sources. The increment of voltage V during the action of a short pulse does not have time to reach the threshold of operation V additionally about the threshold element 3 and the output voltage of the device does not change. After the termination of the second impulse 13, the temperature of the second heat source decreases, and the voltage V at the output of the thermoelectronic element gradually decreases to zero. The duration of the trigger pulse. Sa 14 must be sufficient for the voltage at the output of the thermal element 1 to reach the response threshold Vy, the additional Threshold Device. At the moment when voltage V. reaches the value of V, a signal appears at the outputs 8 and 10 of the device. Through the element OR 9, this signal is transmitted to input 12 of the thermoelectronic element and even in the absence of an input signal, the heating / second source of the thermoelectronic element is subsided, during which the temperature difference between the first and second sources of the thermoelectronic element further increases and the voltage V increases. When this voltage reaches the value V, the threshold element 2 is triggered, the output voltage of which becomes zero. At this moment, a signal appears at the first output 7 of the device, the voltage at the third output 10 becomes zero. The zero value of the voltage is applied to the first input 4 of the heat-electronic element, as a result of which the first heat source begins to dissipate power, Since the power of the first heat source is much higher than the power of the second source, the temperature leveling process of the sources goes much faster. than the process of heating the second source. After a short period of time, the temperature of both sources becomes equal and the voltage at the output of thermal element 1 decreases to zero. At this moment i, the simultaneous return to the initial state of threshold elements 2 and 3 and the whole scheme occurs. The use of the proposed device allows preventing false positives of the device from short impulses of the interfering signal, eliminating the effect of the inertia of the process of cooling the heat sources of the thermoelectronic element to the circuit restoration time, improving the reliability of the equipment and improving its quality. In the proposed device there are three outputs, over which pulses of different duration are generated, which expands the functionality of the device and the scope of its application.

Claims (2)

1. A standby multivibrator containing a thermal input element with two entrances and a threshold element, the output of which is connected to the input of the thermal electronic element / characterized in that, in order to reduce the recovery time of the circuit to its initial state and improve the imo interfacibility, an additional |; i1 a threshold element, and one of the inputs of the thermoelectronic element is connected to the device input and the output of an additional threshold element through the OR element. , / g / 2. Multivibrator but claim 1, characterized in that, in order to improve the functionality, the outputs of the threshold elements are connected to one of the outputs of the device through element I. Sources of information taken into account in the examination 1. Author's certificate of the USSR 435584, cl. H 03 K 5/13, 08/14/73. 2.Druzhinin A.Ya. Pulse generator with thermo-dependent time setting1974,  I gch .. "f I 1 Q1 A mi elements. Energy with. 117. ъ  R 13 fff i p Ui un and. / z X