RU2610298C1 - Controlled switch of voltages carrying information - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to information-measurement equipment, automation and industrial electronics. Controlled switch of voltages carrying an information comprises an input voltage source, a load resistor, an output voltage and a control voltage. First output of the input voltage source is connected to the first output of the load resistor and their common output is grounded, the second output of the load resistor forms the output of the controlled switch relative to the “ground”, it includes a set of elements: a non-inverting voltage repeater on an operational amplifier, two controlled electronic switches, two DC voltage sources of the positive and the negative polarities. Output of the last generator is connected to the control input of the second controlled switch, the input of the control voltage generator for the controlled switches is fed with the control voltage, the common bus of this generator is grounded.

EFFECT: technical result is providing the possibility of maintaining the switch in the closed state for a long time without deterioration of the parameters: residual voltage of the switch and its reverse resistance.

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Description

The invention relates to information technology, automation and industrial electronics. It can be used, in particular, for switching analog voltages that carry information in control, measurement, control or research devices.

A known detector with a transistor key (Gruzdev S.V., Pronin EM. Pulse tensometry. - M .: Energy, 1976, Fig. 32 on page 45 [1]), containing a series input resistor, a key on two compensated transistors and a capacitor, as well as a transformer, one of the terminals of the secondary winding of which is connected to the common output of the collectors of two transistors, and the other to the common output of the bases of two transistors, a control signal is supplied to the primary winding of the transformer.

Its disadvantage is the inability to maintain the transistor switch in a closed state for a long time. This is due to the presence of a transformer in the transistor control circuit. The transformer does not transform constant voltages. The transformation of long-term unchanging voltages leads to such large overall dimensions and weight of the transformer that it becomes structurally incompatible with the rest of the circuit and with the elements of the product.

A known measuring circuit of a narrow range bridge (Malinovsky VN Digital bridges. - M .: Energia, 1976, Fig. 3-7, p. 106 [3]), containing a four-arm bridge, two terminals for connecting the driver voltage supply bridge and the required number of parallel-connected circuits from a series-connected resistor and a key, these circuits are connected parallel to the shoulder resistor with balancing elements of the bridge circuit.

Its disadvantage is a decrease in the measurement accuracy due to error components from the real direct resistance of the key (key resistance in the closed state), from the real reverse resistance of the key (resistance of the key in the open state) and from the residual voltage of the key (voltage on the key in the closed state).

The closest in technical essence and the achieved result is the compensated key scheme selected as a prototype [Gusev V.G., Gusev Yu.M. Electronics and microprocessor technology. - M.: Higher School, 2004, Fig. 7.16 v, p. 558], which contains a series-connected load resistor and two transistors, an input voltage source is connected between the free terminal of the load resistor and the free terminal of the transistor, there is also a transformer, one of the terminals of the secondary winding of which is connected to the common terminal of the collectors of two transistors, the other its output through a resistor is connected to the base of the first transistor, and also this output through another resistor is connected to the base of the second transistor, a control system is fed to the primary winding of the transformer drove u _y .

Its disadvantage is the inability to maintain the key in a closed state for a long time.

The problem to which the invention is directed, is to provide the ability to maintain the switch in a closed state for a long (required) time without degrading the parameters: the residual voltage of the switch and its reverse resistance.

This is achieved by the fact that in a managed switch of voltages carrying information containing an input voltage source, a load resistor, an output voltage and a control voltage, the first output of the input voltage source is connected to the first output of the load resistor and their common output is grounded, the second output of the load resistor forms an output controlled switch relative to the "ground", a set of elements has been introduced: a non-inverting voltage follower on an operational amplifier, two controlled electronic keys, two source of a positive and negative polarity constant voltage source for supplying the operational amplifier and a control voltage generator for controlling electronic keys, in the non-inverting voltage follower the inverting input of the operational amplifier is connected to its output, the non-inverting input is connected to the output of the input voltage source, and the output of the operational amplifier is connected to an ungrounded output load resistor, the first controlled electronic key is connected between the output for positive constant voltage voltage of the operational amplifier and the output of the first source of supply DC voltage, the second between the output for the negative DC voltage of the operational amplifier and the output of the second source of supply DC voltage, the common buses of the sources of positive and negative voltage are grounded, the first output of the driver of the control voltage is connected to the control input of the first controlled key , the second output of the last driver is connected to the control input of the second managed key, at the input generator control voltages for the supplied keys managed by the control voltage generator common bus that is grounded.

The invention is illustrated in FIG. one.

The managed switch of the voltage carrying the information includes an input voltage source 1, the common bus of which is grounded, and the output is connected to the non-inverting input of the operational amplifier 2 of the non-inverting voltage follower. The inverting input of the operational amplifier is connected to its output. The output for the positive supply DC voltage of the latter through a controlled key 3 is connected to the output of the first source 4 of positive DC voltage. The common bus of this source is grounded. Control input key 3 is connected to a first output of the five control voltages for the electronic switches, a common bus which is grounded, and the input control voltage is supplied _from e. The output for the negative supply DC voltage of the operating voltage 2 through the controlled key 6 is connected to the output of the second source 7 of the negative DC supply voltage. Its common bus is grounded. The control input of the key 6 is connected to the second output of the driver 5 of the control voltage for electronic keys. The output of the operational amplifier 2 is connected to the first output of the resistor 8, the common output of which forms the output of the switch u _o . The second output of the load resistor 8 is grounded.

In the absence of control voltage (e _y = 0), the controlled commutator of voltages carrying information corresponds to an open state. To the controlled keys 3 and 6 from the output of the driver 5, the control voltages are not supplied, and they are open. Constant voltage supplies from sources 4 and 7 are not supplied to operational amplifier 2, and it is inoperative. Then the output voltage of the managed switch is absent (u _o = 0).

The managed switch voltage, carrying information, operates as follows. Under the influence of the control voltage (e _y ≠ 0) from the outputs of the driver 5, the inputs of the controlled keys 3 and 6 receive voltages that translate these keys into a conducting state. Then the operational amplifier 2 receives the positive and negative supply constant voltage from sources 4 and 7, and it goes into working condition. The non-inverting voltage follower assembled on it repeats the shape and amplitude of the voltage from the output of the input voltage source 1 and creates it at the output of the controlled voltage switch carrying the information. In this case, there are no restrictions on the duration of the signal of the source 1 input voltage and, accordingly, on the duration of the output voltage (u _o ) of the controlled voltage switch carrying information.

The residual voltage (u _ost ) of the managed switch of the voltage carrying information is determined by the voltage difference at the non-inverting input of the operational amplifier 2 (u _non-in ) and at the output of the switch. It is found by the formula

where k is the gain of the operational amplifier. In particular, with uout = 2 V and k = 10 ⁵ or k = 10 ⁶ u _ax = 20 μV or u _ost = 2 μV. For evaluative comparison of a chopper with compensated transistors K101KT1 (A, B, C, D), the residual voltage (voltage between emitters) is 100 or 300 μV [Nefedov A.V. Integrated circuits and their foreign analogues, RadioSoft, Moscow, 2001, p. 120].

In the considered circuit (Fig. 1) there is no electric current between the non-inverting input and the output of the operational amplifier 2. Therefore, there is no sense in the direct resistance of the managed switch. We can assume that it is absent here. Here the transmission coefficient makes sense (k _P )

The ideal transfer coefficient k _PI here is equal to unity

With the given values of k in the previous paragraph, the transmission coefficient for the considered circuit (Fig. 1) practically coincides with the ideal value

или

.

or

.

If the managed switch of the voltage carrying the information is in a non-conductive state, then the load resistor 8 is bridged by its inverse resistance. This reverse resistance is mainly determined by two parallel connected resistances. The first one consists of series-connected resistances of several pn junctions in the non-conductive state of the operational amplifier transistors and the inverse resistance of the controlled key 3. The second resistance is also series-connected resistances of several pn junctions in the non-conductive state of the transistors of the operational amplifier and the inverse resistance of a controlled key 6. If you use an operational amplifier with field-effect transistors at the inputs, the resistance of the part is essentially eliminated -n transitions to a non-conducting state of the transistors connected these inputs. In the General case, the inverse resistance of the controllable switch under consideration (Fig. 1) and the inverse resistance of the prototype (key on compensated transistors) have comparable values. In this case, in the considered state, the reverse resistance of the managed switch does not have a significant negative value, because output voltage (u _o = 0), the resistance value of the resistor 8 is much less than the value of the inverse resistance.

Thus, the managed switch of the voltage carrying information does not have a limitation on the duration of the control voltage (e _y ), it has a lower value of the residual voltage and there is no negative influence of direct resistance due to its absence.

Claims (1)

A managed switch of voltages carrying information containing an input voltage source, a load resistor, an output voltage and a control voltage, the first output of the input voltage source is connected to the first output of the load resistor and their common output is grounded, the second output of the load resistor forms the output of the managed switch relative to ground , characterized in that a set of elements is introduced into it: a non-inverting voltage follower on an operational amplifier, two controlled electronic keys, two and a positive and negative polarity DC voltage source for supplying the operational amplifier and a control voltage generator for controlling electronic keys, in the non-inverting voltage follower the inverting input of the operational amplifier is connected to its output, the non-inverting input is connected to the output of the input voltage source, and the output of the operational amplifier is connected to an ungrounded output load resistor, the first controlled electronic key is connected between the output for a positive constant voltage of the operational amplifier and the output of the first source of supply DC voltage, the second between the output for the negative DC voltage of the operational amplifier and the output of the second source of supply DC voltage, the common buses of the sources of positive and negative voltage are grounded, the first output of the driver of the control voltage is connected to the control input of the first controlled key , the second output of the last driver is connected to the control input of the second managed key, in od shaper control voltages for the supplied keys managed by the control voltage generator common bus that is grounded.

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