SU1167705A1 - Versions of rectangular pulse generator - Google Patents

Abstract

1. A square pulse generator containing two operational amplifiers, a capacitor, the output of a separate operational amplifier through the first resistor is connected to the non-inverting input of the same operational amplifier, to the inverter module to the input of the second operational amplifier and through the corresponding parallel-connected first diode and the second resistor to. one of the capacitor plates, while each capacitor plate through a second diode is connected to the corresponding input of one of the operational amplifiers, non-inverter The input of each of the operational amplifiers is connected via a third resistor to a common bus, characterized in that, in order to increase frequency stability, two transistors are added to it, each of which is connected in series with the second resistor, the collector of the transistor is connected to one of the plates the capacitor, the emitter of xyssh I :: .. - --naf shsh-i with the corresponding -second resistor, and the bases of the transistors are connected to the common bus. 2. A square pulse generator containing two operational amplifiers, the first capacitor, the output of each operational amplifier through the first resistor is connected to the non-inverting input of the same operational amplifier and through the first diode to the corresponding plate of the first capacitor, the non-inverting input of each of the operational amplifiers through the corresponding second A resistor is connected to a common bus, characterized in that, in order to increase the frequency stability of the CO, to the output of each operational amplifier via a co vetstvukitsy second diode connected to the collector of the first further transistor, whose emitter is connected through a resistor to the first supply bus of: a base - the second plate of the first capacitor | through the corresponding first diode to the output of another operational amplifier, the co-reflector of each first additional transistor is connected to the emitter of the corresponding second additional transistor, the base of each additional transistor is connected to the base of the corresponding first additional transistor, the collector of each second additional transistor is connected through a resistor to the second power bus and through the corresponding second capacitor is connected to its inverting input

Description

and non-inverting input of another operational amplifier, each of the plates of the first capacitor connected to the collector of the corresponding third additional transistor, the emitter of each of which through the corresponding resistor is connected to the second power bus, and the base is connected to the emitter of the corresponding second additional transistor and through the third capacitor the base of the third additional transistor.

3. A square pulse generator containing two operational amplifiers, the first capacitor, the output of each operational amplifier through the first resistor is connected to the non-inverting input of the same operational amplifier and to the inverting input of the other operational amplifier and through a corresponding parallel-connected diode and the second resistor to one of the plates of the first capacitor, the inputs of the operational amplifier through the third resistors are connected to the common pshnoy, characterized in that, in order to increase stability, often you,

Two transistors are inserted into it, and the plates of the first capacitor are connected to the emitters of transistors, the collectors of which are connected to the power bus through resistors, and through separation capacitors to the inverting inputs of operational amplifiers, the bases of the transistors are connected to the midpoint of the resistive divider connected between the power bus and common pshnoy.

4. A square pulse generator containing two operational amplifiers, the first capacitor, the output of each operational amplifier through the first resistor is connected to the non-inverting INPUT of the same operational amplifier and to the inverting input of the other operational amplifier and in parallel the first diode connected in parallel

and the second resistor is connected to one of the plates of the first capacitor, the inputs of the operational amplifiers are connected via a third resistor to a common bus, characterized in that, in order to increase frequency stability, the output of the operational amplifier is again through 67705

The corresponding corresponding parallel-connected second diode and fourth resistor are connected to the plates of the second capacitor, and the first and second diodes are connected to the output of each operational amplifier with opposite electrodes, and to the plates of the first and second capacitors of the same name, in addition, between each plate of one capacitor and the opposite relative the outputs of the operational amplifiers by the plate of another capacitor, the emitter and the base turn on the transistor, the collector of which is connected via a fifth resistor to The power supply source and, via the third capacitor, to the input of the operational amplifier, with the base of the transistor connected to the cathode of the second diode, and the collector to the inverting input of the operational amplifier, the output of which is connected to the anode of the same diode.

5. A square pulse generator containing two operational amplifiers, the first capacitor, the output of each operational amplifier is connected to the anode of the first diode and through the first resistor is connected to the non-inverting input of the same amplifier and to the inverting input of another operational amplifier, the input of each operational amplifier through A corresponding third resistor is connected to a common bus, characterized in that, in order to stabilize the frequency of the expansion of the functionality, the cathode of each of the first Odov connected to the collector of the first additional transistor, the emitter of which through the fourth resistor is connected to the output of its operational amplifier, the bases of both first additional transistors are combined and connected to the common bus, and the collector of each of them is connected to the emitter of the corresponding second additional transistor of the opposite conductivity type, the collector of which through the corresponding resistor is connected to the power supply PIN and through the corresponding second capacitor to the non-inverting input of the About its operational amplifier, the base of the second additional transistors are interconnected through a third capacitor, through the corresponding second diodes are connected to

the control bus and through the third diodes are connected to the emitters of the second additional transistors.

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The invention relates to a pulse technique and can be used in radio-electronic equipment for generating rectangular pulses.

A known generator of rectangular pulses on two operational amplifiers with cross-feedback between their amplifiers with differential inputs through resistive dividers and integrating KS circuits l

The frequency stability of this generator is low due to the considerable temperature sensitivity of the constant time and switching threshold.

Closest to the proposed generator of rectangular pulses on two operational amplifiers, which contains the time master bridge, resistive dividers in the positive feedback circuits of the operational amplifiers.

The principle of operation of the known device is based on recharging capacitor 2}

Switching of operational amplifiers in this generator occurs in accordance with the magnitude and polarity of the voltage on the capacitor plates, the reference voltage being set by resistive dividers in the circuit, the feedback of the operational amplifiers and for normal operation of the latter should be small. This factor determines the low rate of change of voltage on the capacitor plates at the time of the overturning of operational amplifiers, and hence the low stability of the frequency of the generated pulses. In addition, the generator has insufficient functionality, since electronic frequency control is impossible in it.

The purpose of the invention is to increase the stability of the following frequency, the output pulses of the generator and the expansion of functionality.

The goal is achieved by the fact that a square pulse generator containing two operational amplifiers, a capacitor in which the output of each operational amplifier is connected via a first resistor to the non-inverting input of the same operational amplifier, to the inverting input of the second operational amplifier and through a corresponding parallel connected in parallel. the first diode and the second resistor are connected to one of the capacitor plates; in this case, each capacitor plate is connected via a second diode to the corresponding input of one of the operational amplifiers, noninverting the input of each operational amplifier through the third resistor is connected to the common bus; In addition, two transistors are introduced, each of which is connected in series with the second resistor, the collector of the transistor is connected to one of the capacitor plates, the emitter is connected to the corresponding second resistor, and the bases of the transistors are connected to a common bus.

In the second variant of the square pulse generator, the increase in stability is achieved by connecting the first additional transistor to the output of each operational amplifier through a corresponding second diode, the collector is connected to the first power supply through the resistor through a resistor through a resistor and the first diode through the resistor to the output of another operational amplifier, the collector of each first additional transistor is connected to the emitter of the corresponding second additional the base of each additional transistor is connected to the base of the corresponding additional transistor, the collector of each second additional transistor is connected via a resistor to the second power supply bus and through the corresponding second capacitor is connected to the inverting input of its own and non-ventilation input of another operating amplifier, each of the plates the first capacitor is connected to the collector of the corresponding third additional transistor, the emitter of each of which through the corresponding Enikeev resistor connected to the second power bus, and the base connected to the emitter of the corresponding second additional transistor and through a third capacitor - from the base-third additional transistor. In the third variant of the square-wave generator, an increase in the frequency stabilization is also achieved by introducing two transistors, the plates of the first capacitor are connected to the emitters of the transistors, the collectors of which are connected through resistors to the power supply bus, and to the inverting inputs of operational amplifiers, the transistors are connected to the midpoint of the resistive divider connected between the power rail and the common bus. In the fourth embodiment of the square pulse generator, the increase in frequency stability is achieved by. the output of each operational amplifier through the additionally inserted corresponding parallel-connected second diode and fourth resistor is connected to the plates of the second capacitor, with the first and second diodes connected to the output of each operational amplifier with opposite electrodes, and to the plates of the first and second capacitors besides, between each lining of one capacitor and the opposite side of the outputs of the operational amplifiers the lining of the other capacitor is connected to the emitter and base by tr a resistor whose collector is connected via a fifth resistor to a power source, and through a third capacitor to an input operating voltage of 054 bodies, the base of the transistor connected to the cathode of the corresponding second diode, and the collector to a non-inverting input of an operational amplifier whose output is connected to the anode same diode. In the fifth variant of the pulse generator, the increase in frequency stability and expansion of functionality is achieved due to the fact that the cathode of each of the first diodes is connected to the collector of the first additional transistor, the emitter of which is connected through the fourth resistor to the output of its operational amplifier, connected to a common bus, and the collector of each of them is connected to the emitter of the corresponding second additional transistor of the opposite type conduction, the collector of which is connected via a corresponding resistor to the power bus and through a corresponding second capacitor to the non-inverting input of its operational amplifier; second additional transistors. FIG. 1 is a schematic diagram of the device, the first embodiment of FIG. 2 - the same, the second option-, in FIG. 3 - the same; the third option; in fig. 4 - the same, the fourth option; in fig. 5, the same, fifth variant. The device according to the first embodiment contains operational amplifiers 1 and 2, capacitor 3, first resistors 4 and 5, first diodes 6 and 7, second resistors 8 and 9, second diodes 10 and 1-1, third resistors 12 and 13, additionally introduced transistors 14 and 15, terminals 16 and 17 for connecting a common bus. The output of each of the operational amplifiers 1 2 through the corresponding first resistor 4, 5 is connected to the non-inverting input of the same operational amplifier and to the inverting input of the second operational amplifier and through the corresponding.

The first diode 6, 7 and the second resistor 8, 9 are connected in parallel to the capacitor plate 3. Each of the capacitor plates 3 through the second diode 10, 11 is connected to the corresponding input of its operational amplifier 1, 2. Non-inverting input of each silo of operational amplifiers through the third resistor 12 or 13 is connected to a common bus. The bases of the transistors 14, 15 are also connected to the common bus, their collectors to the plates of the capacitor 3, and the emitters to the second resistors 8, 9.

The pulse generator (the second option) contains operational amplifiers 18 and 19, the first capacitor 20, the first resistors 21 and 22, the first diodes 23 and 24, the second resistors 25 and 26, the second diodes 27 and 28, the first additional transistors 29 and 30, the first bus power supply 31, second additional transistors 32 and 33, second power supply bus 34, second capacitors 35 and 36, third additional transistors 37 and 38, third capacitor 39, common bus 40.

The output of each of the operational amplifiers 18 and 19 through the first resistor, respectively, 21 or 22 is connected to the non-inverting input of the same operational amplifier and through the first diode, respectively 23 or 24, is connected to the plates of the first capacitor 20. The non-rotating input of each of the operational amplifiers through the second 25 or 26 resistor

connected to common bus 40. In addition, the output of each of the operational amplifiers 18, 19 through the corresponding second diode 27 and 28 is connected to the collector of one of the second additional transistors 29, 30, whose emitters are connected to the first power bus through resistors, and the bases are connected to the plates of the first capacitor 20 and through the corresponding first diode 23 or 24 to the output of another operational amplifier. The collector of each of the two first additional transistors 29, 30 is connected to the emitter of one of the two second additional transistors 32, 33, the bases of which are combined with the databases of the first 67705. 6

transistors. The collector of the second additional transistor is connected via a resistor to the second power supply bus 34 and connected via the corresponding second capacitor 35 or 36 to the inverting input of one and the non-inverting input of another operational amplifier. Each of the plates of the first capacitor 20 is connected to the emitter of the corresponding third additional transistor 37 or 38. The collector of each of the two thirds of the additional transistors is through the сt5 the corresponding resistor is connected to the second power bus 34, and the base is connected to the emitter of the second additional transistor 32 and 33 And the third capacitor 39 - with the base of the third additional transistor.

In the third embodiment, the pulse generator contains two operational amplifiers 41, 42, the first capacitor 43, the first resistors 44, 45, diodes 46, 47, the second resistors 48, 49, the third resistors 50, 51, transistors 52, 53, common W.1NU 54 , power bus 55, coupling capacitors 56, 57, resistive divider 58. The outputs of operational amplifiers 41, 42 through the first resistors 44, 45 are connected to the non-inverting inputs of operational amplifiers, which are connected to common bus 54 through third resistors 50, 51.

In addition, the output of each operational amplifier is connected via a parallel jj but connected second resistor, respectively 48 or 49, and diode 46 or 47 are connected to the plates of the first capacitor 43. The emitters are connected to the same plates and the collectors are connected to the power bus via resistors 55 and through the separation capacitors 56, 57 are connected to the inverter inputs of the operational amplifiers. The transistor bases are combined and connected to the midpoint of the voltage divider 58.

In the fourth embodiment, the device also contains two operational amplifiers 59, 60, the first resistors 61, 62, the second resistors 63, 64, the first capacitor 65, the first diodes 66, 67, the third resistors 68, 69, the second diodes 70, 71, the fourth resistors 72 , 73, second capacitor 74, transistors 75, 76, third capacitors 77, 78, common bus 79 and power bus 80, fifth resistors 81, 82. The output of each opamp is connected via its corresponding first resistor 61 or 62 to its non-inverting input, which in turn through the corresponding third resistor 68 or 69 p dklyuchen to a common bus 79. Furthermore, the output of each operational amplifier connected in parallel across the second. resistor 63 or 64 and the first diode 66 or 67 are connected to different plates of the first capacitor 65, as well as through parallel connected fourth resistor 72 or 73 and the second diode 70 or 71 are connected to different plates of the second capacitor 74, which are connected to the bases of transistors 75 and 76, the emitters of which are connected to the opposite plates of the first capacitor 65, and the collectors are connected via resistors 81 and 82 to the supply bus 80 and through third capacitors 77 and 78 connected to the non-inverting inputs of operational amplifiers 59 and 60. Ntu device contains two operating. Amplifier 83, 84, the first resistors 85, 86, the second resistors 87, 88, the first diodes 89, 90, the third resistors 91, 92, the first capacitor 93, the second capacitors 94, 95, the second diodes 96, 97, the third diodes 98, 99, the first additional transistors 100, 101, the second additional transistors 102, 103, the common bus 104, the power bus 105, the control bus 106. The output of each operational amplifier is connected to the anode of the first diode, respectively Y9 or 90, and through the first resistor 85 or 86 is connected to the non-inverting input of the same operational circuit Itel and invertiruyusche th input of another operational amplifier. The input of each of the operational amplifiers through the corresponding third resistor 91, 92, is connected to a common bus. The cathode of each of the first diodes is connected to the collector of the corresponding first additional transistor 100 or 101, the emitter of which through a resistor 87 or 88 is connected to the output of its onepaii ioHHoro amplifier. The bases of both of the first additional transistors are combined and connected to the common bus 104. The collector of each of them is connected to the emitter of the corresponding second additional transistor of opposite conductivity type 102 or 103, the collector of which is connected via a corresponding resistor to the power bus 105 and through the corresponding second capacitor 94 or 95 connected to the input of its op amp. The bases of the second additional transistors 102 and 103 are connected through a third capacitor 93, through the second diodes 96, 97 - connected to the control bus 106 and through the third diodes 98, 99 connected to the emitters of the second additional transistors. The pulse generator in the first embodiment works as follows. Suppose that the output of the operational amplifier 1 has a positive polarity approximately equal to the supply voltage, and the output of the operational amplifier 2 has the same negative voltage. Then the capacitor 3 is charged through the output of the amplifier 1, diode 6, transistor 15, resistor 9, output amplifier 2, striking a voltage of approximately equal to twice the supply voltage. As the capacitor 3 is charged, the potential of the cathode of diode 11 decreases, tending to the magnitude of the negative supply voltage. At the point in time when it becomes more negative than the midpoint potential of the resistive divider in the feedback circuit of operational amplifier 2, the operational amplifiers switch. Subsequently, the capacitor 3 is recharged through the diode 7, the transistor 14, the resistor 8, trying to charge up to a voltage equal to twice the supply voltage. When the voltage across the capacitor reaches its maximum value, the operational amplifiers return to their original state. In this way, the processes are repeated, and anti-phase sequential ones are formed at the output of the operational amplifiers.

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these are rectangular pulses. Diode 10, 11 prevents overvoltages at the inputs of the operational amplifiers.

The introduction of additional transistors in the capacitor recharging circuit, connected according to the current stabilizer circuit, determines the constant charge current of the capacitor, which means the linear law of voltage variation on its plates. This made it possible to significantly improve the stability of the time parameters of the formed pulse sequence. Physically, this is explained by an increase in the steepness of the time of the driving voltage at the time of switching the operational amplifiers.

The pulse generator according to the second variant works in the same way with the only difference that as one capacitor recharges, the potential of its lining changes, which leads to an increase in the charge voltage and, hence, the slope of the potential change of the lining of the other. This, in turn, increases the charge current, which means that the slope of the change in potential of the lining of the first capacitor, etc.

Thus, as the capacitors charge, the charge current rises. This determines the maximum steepness of the potential change on the capacitor plates at the time of the circuit tipping, which determines the high stability of the generation frequency.

Similarly, the pulse generator according to the third option.

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According to the charge factor of the capacitor 43, the emitter potential of the transistor 52 increases. At the moment when it reaches the value of the reference voltage 5, the transistor 52 opens and a positive voltage from its collector through a coupling capacitor 56 connected to the inputs of the operating terminals -1 causes the terminals to overturn. Subsequently, the capacitor 43 is recharged through the resistor 49, the diode 46. At the time when the voltage across the capacitor has reached, there is no tilt threshold value

IS opens the transistor 53 and the operational amplifiers are returned to the initial state.

Features of the pulse generator on the fourth option

0 are associated with the use of a dual RC bridge in it, which provides a high rate of voltage change at the emitter transitions of the transistor due to the oncoming recharge

5 capacitors 65 and 74 is the time of the master RC-bridge, which provides an increase in frequency stability.

The features of the pulse generator according to the fifth variant are connected with the possibility of controlling the frequency, along with an increase in stability, and consist in the fact that the capacitor 93 is recharged through the diodes and the stable current generator

5 across the transistors 100, 101 to the level determined by the voltage on the control bus 106, which allows the oscillation frequency to be varied by changing the control voltage.

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Claims (5)

1. A square-wave generator containing two operational amplifiers, a capacitor, the output of each operational amplifier through a first resistor is connected to a non-inverting input of the same operational amplifier, to the inverting input of the second operational amplifier and through the corresponding parallel-connected first diode and second resistor to one of the plates capacitor, with each capacitor plate through a second diode connected to the corresponding input of one of the operational amplifiers, a non-inverting input to each of the operational amplifiers is connected through a third resistor to a common bus, characterized in that, in order to increase the frequency stability, two additional transistors are introduced into it, each of which is connected in series with the second resistor, the collector of each transistor is connected to one of the capacitor plates, the emitter with the corresponding second resistor, and the base of the transistors are connected to a common bus. 2. A rectangular pulse generator containing two operational amplifiers, a first capacitor, the output of each operational amplifier through a first resistor is connected to a non-inverting input of the same operational amplifier and through the first diode to the corresponding plate of the first capacitor, non-inverting input of each of the operational amplifiers through the corresponding second resistor connected to a common bus, characterized in that, in order to increase frequency stability, to the output of each operational amplifier through the corresponding the second diode is connected by a collector to the first additional transistor, the emitter of which is connected through the resistor to the first power bus, and the base to the lining of the first capacitor and through the corresponding first diode to the output of another operational amplifier, the collector of each first additional transistor is connected to the emitter of the corresponding second additional transistor , the base of each additional transistor is connected to the base of the corresponding first additional transistor, the collector of each second will complement A transistor is connected through a resistor to a second power bus and, through a corresponding second capacitor, is connected to an inverting input of its own and a non-inverting input of another operational amplifier, each of the plates of the first capacitor is connected to the collector of the corresponding third additional transistor, the emitter of each of which is connected through the corresponding resistor to the second power bus, and the base is connected to the emitter of the corresponding second additional transistor and through the third p - with the base of the third additional transistor. 3. A square-wave generator containing two operational amplifiers, a first capacitor, the output of each operational amplifier through a first resistor is connected to the non-inverting input of the same operational amplifier and to the inverting input of another operational amplifier and through the corresponding parallel-connected diode and second resistor to one of the plates the first capacitor, the inputs of the operational amplifier through the third resistors are connected to a common bus, characterized in that, in order to increase the frequency stability, two transistors are introduced, and the plates of the first capacitor are connected to the emitters of the transistors, the collectors of which are connected through the resistors to the power bus, and through the isolation capacitors to the inverting inputs of the operational amplifiers, the base of the transistors are connected to the midpoint of the resistive divider connected between the power bus and the common by bus. 4. A square-wave generator containing two operational amplifiers, a first capacitor, the output of each operational amplifier through a first resistor is connected to a non-inverting input of the same operational amplifier and to an inverting input of another operational amplifier and through the corresponding parallel connected first diode and second resistor to one of the plates of the first capacitor, the inputs of operational amplifiers through third resistors are connected to a common bus, characterized in that, in order to increase the stability of currents, the output of each operational amplifier through the newly introduced corresponding parallel connected second diode and the fourth resistor is connected to the plates of the second capacitor, and the first and second diodes are connected to the output of each operational amplifier by unlike electrodes, and to the plates of the first and second capacitor by the same name, except In addition, between each lining of one capacitor and the opposite relative to the outputs of the operational amplifiers, the lining of the other capacitor by the emitter and the base includes a trans a torus whose collector is connected through a fifth resistor to a power source and through a third capacitor to an input of an operational amplifier, the base of the transistor connected to the cathode of the corresponding second diode and the collector with a non-inverting input of an operational amplifier, the output of which is connected to the anode of the same diode. 5. A rectangular pulse generator containing two operational amplifiers, a first capacitor, the output of each operational amplifier is connected to the anode of the first diode and is connected through a first resistor to the non-inverting input of the same amplifier and to the inverting input of another operational amplifier, the input of each of the operational amplifiers through the corresponding the third resistor is connected to a common bus, characterized in that, in order to increase the stability of the frequency of expansion of functionality, the cathode of each of the first diodes connected to the collector of the first additional transistor, the emitter of which is connected through the fourth resistor to the output of its operational amplifier, the bases of both first additional transistors are combined and connected to a common bus, and the collector of each of them is connected to the emitter of the corresponding second additional transistor of the opposite type of conductivity, the collector of which through the corresponding resistor_connected to the power bus and through the corresponding second capacitor to the non-inverting input of its ion amplifier ,, the bases of the second additional transformers 1167705 of the tori are connected to each other through the third capacitor, through the corresponding second diodes are connected to the control bus and through the third diodes are connected to the emitters of the second additional transistors.