CS265590B1 - Voltage to frequency converter with high input resistance and with separated inputs for positive and negative polarity of input voltage - Google Patents

Abstract

The wiring relates to a voltage to frequency converter with high input resistance with separate positive outputs and negative input voltage polarity. Input voltage from the input terminal is brought directly to the non-inverting terminal operational amplifier input. The same voltage is repeated on inverting operational amplifier input and capacitor it will be charged with current proportional to the input voltage. If on a positive voltage is applied to the input terminal the first comparator to reach the comparison level activates the first monostable flip-flop. For the duration pulse at the output of the first monostable flip circuit is closed first electronic switch and capacitor is discharged by a constant current from the first reference source current. The whole process is repeated all the time the pulse frequency on the first output terminal is directly proportional to the input voltage. The essence of the solution is that negative input voltage applied to input terminal activates a second branch consisting of a second comparator with the source of comparative voltage, the second monostable flip-flop, second electronic switch and a second reference current source. Activity is similar to the first branch, with the output signal is now available on the second output terminal. Engagement can be used wherever a simple voltage to frequency converter is needed with a large input resistor with separate outputs for positive and negative input voltage. In particular, he finds use in measuring and instrumentation as input converter in multimeters, digital correlators or spectrum analyzers, digital integrators etc.

Description

BACKGROUND OF THE INVENTION The present invention relates to a voltage to frequency converter with high input resistance with separate outputs for positive and negative polarity of the input voltage.

Several connection methods are known which make it possible to convert the input voltage to a frequency and at the same time distinguish whether the input voltage is positive or negative polarity. Most commonly, two complementary converters are used, each of which is designed for only one polarity of the input voltage. The actual voltage to frequency converters usually operate by controlling the frequency of the multivibrator using a current proportional to the input voltage, or for more precise purposes, feedback converters are used comprising an integrator, a comparator, and a timing circuit that determines the discharging time of the integration capacitor by a defined current.

The disadvantage is the considerable circuit demands because each branch contains a complete circuit arrangement of the voltage to frequency converter.

Another way to process the input voltage of the converter of both polarities is to add a constant voltage greater than the maximum voltage to the input voltage, thus shifting the conversion characteristic. A certain intermediate frequency corresponds to zero input voltage. Depending on the polarity of the input voltage, the frequency of the output signal decreases or increases relative to the center frequency. The output signal is divided according to polarity by a voltage or frequency comparator, which switches the demultiplexer downstream of the converter output.

The disadvantage is that the zero input voltage corresponds to the middle frequency, which should usually be considered in further processing.

The simplest known arrangement of a voltage to frequency converter with two separate outputs for positive and negative input voltage utilizes the integration of the input voltage in the integrator. The integrator output voltage is monitored and, depending on whether the converter input voltage is positive or negative, a positive or negative reference voltage source is connected to the integrator summing point for a defined period of time, discharging or charging the integration capacitor with a defined current. The whole process is repeated and its frequency is proportional to the input voltage.

A common disadvantage of all these wiring is the relatively low input resistance of the inverting integrator, given essentially by the resistance of the resistors that is connected at the integrator input. This may be disadvantageous in many applications. It is of course possible to incorporate a separating stage with a high input resistance in front of the converter, but in this way the peripheral complexity and cost-effectiveness of the whole converter is increased.

Known connection of a voltage to frequency converter with a large input resistance, in which the input voltage is applied to the non-inverting input of an operational amplifier. A CR article is involved in his feedback. The capacitor of this cell is charged by a current proportional to the input voltage.

When a certain voltage at the amplifier output is reached, the capacitor is discharged by the reference current for a defined time. The frequency of the whole process is directly proportional to the input voltage.

The disadvantage of this converter is that it allows to process only one polarity of the input voltage.

These disadvantages are largely eliminated by connecting the voltage to high frequency converter with separate outputs for positive and negative polarity of the input voltage of the present invention, consisting of an op amp, resistors, capacitor, first comparator, first comparator voltage source, first monostable flip-flop The first electronic switch, the first reference current source, the essence of the invention is that the first input of the second comparator is also connected to the output of the operational amplifier, the second input of which is connected to the second comparative voltage source. The output of the second comparator is coupled to the input of the second monostable flip-flop whose output is connected to the second output terminal and also to the control input of the second electronic switch when the first output of the second electronic switch is connected to the inverting input of the op amp. to a second reference current source.

The advantages of connecting a voltage converter to a high input resistor with separate outputs for positive and negative polarity of the input voltage according to the invention are in particular that in a very simple way an output signal can be obtained on separate outputs according to the polarity of the input converted voltage. . The main advantage is that the converter has a large input resistance, as in the single-channel version. The entire wiring of the converter is cost-effective.

The invention is described in greater detail below with reference to the drawing showing a circuit of an exemplary voltage to high frequency converter with separate outputs for positive and negative polarity of the input voltage.

The input terminal 1 is connected to the non-inverting input of the operational amplifier 2, the first end of the resistor 3, the first end of the capacitor 3, and the first terminal of the first electronic switch J5 and the first terminal of the second electronic switch J7. The other end of the resistor 2 is connected to a common conductor 9. The output of the operational amplifier 2 is connected to the second end of the capacitor 10 and also connected to the first input of the first comparator 10 and the first input of the second comparator 14.

The second input of the first comparator 10 is connected to the first comparator voltage source 12 and the second input of the second comparator 14 is connected to the second comparator voltage source 13.

The output of the first comparator 10 is connected to the input of the first monostable flip-flop 11 and likewise the output of the second comparator 14 is connected to the input of the second monostable flip-flop 15. The output of the first monostable flip-flop 11 is connected to the first output terminal 16 and to the control input of the first electronic the output of the second monostable flip-flop 15 is connected to the second output terminal 17 as well as to the control input of the second electronic switch 17, the second output of which is connected to the second source jj of the reference current. current.

In operation, the input voltage U is applied to the input terminal 11 against the common conductor 9. The same voltage is repeated as a result of the operation of the operational amplifier 2 at the inverting input of the amplifier, and therefore the capacitor 6 will be charged with current.

where U indicates the input voltage applied to the input terminal 11 against the common conductor 9 and R indicates the resistance of resistor 2- In operation, the output voltage of the operational amplifier 2 is monitored by the first and second comparators 10 and 14. Tension. The second comparator 14 has the second comparator level U _{R2 set by the} second comparator voltage source 13. The first comparison level is higher than the second comparison level, i.e. U _R1 i> U _K2 . The first comparator 10 operates at a positive input voltage and the second comparator 14 operates at a negative converter input voltage.

If a positive voltage is applied to the input terminal 11, the comparator 10 is switched over when the output voltage of the operational amplifier 2 reaches the comparative level given by the source 12 of the first comparative voltage. As a result, the first monostable flip-flop 11 is turned over for the time T1. given by its time constant. The output signal of the first monostable circuit 11 is applied to the control input of the electronic switch 15, which is closed and, in addition, the first reference current source 11 is connected to the inverting input of the operational amplifier. In this manner, will discharge the capacitor 6 of the reference current I _R1 - Following překlopení.prvního monostable multivibrator 11 to the quiescent state of the electronic switch 5 opens and the whole process is repeated. The frequency of charging and discharging the capacitor 6 is linearly proportional to the input voltage value. Frequency output signal taken from the first output terminal 16 to ground terminal 2 J®, ^assuming that the input voltage d1d therefore · linearly dependent on the input voltage according to the relationship

AT.

Here I _R1 denotes the current supplied by the first reference current source 2, T _{R1 the} duration of the pulse generated by the first monostable flip-flop 21 » ^{R the} resistance of the resistor 2 ^and U the input voltage applied to the input terminal 2 against common conductor 2 ·

The connection works similarly when the negative terminal is applied to the input terminal 2.

However, a second branch is now in operation, consisting of a second comparator 22, a second monostable flip-flop 15, a second electronic switch T and a second reference current source 2. The frequency of the output signal taken from the second output terminal 17 against the ground terminal 2 θθ, provided that the input voltage U = = 0 is given by the relation where I _R2 denotes the value of the current supplied by the reference current source 2, ^T R2 the pulse duration generated by the second monostable flip-flop 15 and the meaning of other variables is the same as in the previous one.

In order for the frequency-to-frequency converter to be equal for both input voltage polarities, I _R1 = I _R2 and T _R1 = T _R2 · θ ^ Υ ^ Ιθ are also chosen U _R2 = - U _R ^.

A minor disadvantage is that the accuracy of the transmission depends on the sensitivity of the comparators 10 and 14, which determine the moment of activation of the monostable flip-flops 11 and 15, and the stability of the time constants of the monostable flip-flops 11 and 15, respectively. charging the capacitor S from the reference current sources 4 and 4, respectively. j ?. However, with a suitable selection of circuit elements, this disadvantage can be overcome at a relatively low cost of the entire converter.

High Input Resistance Frequency Converter with Separate Outputs for Positive and Negative Polarity Input Voltage of the Invention is of general use and can be advantageously applied wherever a simple high voltage resistor frequency converter with separate positive outputs is required and negative polarity of the input voltage. In particular, the converter according to the invention can be used in measuring and instrumentation technology, for example in multimeters, digital correlators or spectrum analyzers, digital integrators and the like.

Since the circuit solution of the converter according to the invention is relatively simple, the circuit is suitable for realization in integrated or hybrid form.

Claims (1)

OBJECT OF THE INVENTION ‘ High-input voltage to frequency converter with separate outputs for positive and negative polarity input voltage consisting of opamp, resistor, capacitor, first comparator, first comparator voltage source, first monostable flip-flop, first electronic switch and first reference current source, characterized in that the output of the operational amplifier (2) is connected to the first input of the second comparator (14), the second input of which is connected to the second comparator voltage source (13), the output of the second comparator (14) connected to the input of the second monostable flip-flop (15), the output of which is connected to the second output terminal (17) and simultaneously to the control 265 ^ 90 through the input of the second electronic switch (7) when the first terminal of the second electronic switch (7) is connected to the inverting input of the operational amplifier (2), the second terminal of which is connected to. a second reference current source (8).