CS265459B1 - Exact voltage to frequency converter - Google Patents

Abstract

The voltage to frequency converter consists of an operational amplifier whose inverting input is connected via a resistor input terminal and an auxiliary resistor reference voltage source, then the cathode of the first diode of the electronic switch and also the first end of the integrating capacitor, the other end of which is connected with the output of the operational amplifier, the non-inverting input of the operational amplifier is coupled to the auxiliary voltage source and the output is connected to the first input of the comparator, the second input of which is connected to the source of the comparative voltage. The comparator output is coupled to a flip-flop blocking input whose clock input is coupled to a reference time source and an output terminal output. The output terminal is also connected to the cathode of the second diode of the electronic switch. The anodes of both diodes of the electronic switch are coupled to a reference current source.

Description

The present invention relates to a precise voltage to frequency converter.

Several connections of voltage to frequency converters are known. The simplest voltage to frequency converters work on the principle of integrating the input voltage in the integrator, where the output voltage of the integrator is monitored by a comparator, which when the comparator level reaches the integrator is reset. Since the frequency of charging and resetting the integrator depends on the magnitude of the input voltage, the frequency of the output signal from the comparator is directly proportional to the input voltage.

The main disadvantage of this arrangement is the final discharging time of the integrator capacitor of the integrator by means of a parallel connected electronic switch. Since the instantaneous discharge would cause irreversible changes in the integration capacitor, the discharge is carried out via a resistor connected in series with the electronic switch. However, the resistance of the closed switch is non-zero and, moreover, its resistance varies depending on the flowing current. Therefore, the discharging of the integrating capacitor is not precisely defined not only by the resistor connected in series with the switch, but also by the variable resistance of the closed switch. This drawback excludes the use of this type of converter for low-end applications.

Somewhat better results can be achieved by arranging a +1 inverter in front of the integrator itself. A comparator circuit is placed downstream of the integrator, which sets the inverter's transmission to + 1 when the positive comparator level is reached and changes the inverter's transmission to -1 when the negative comparator level is reached. The frequency of charging and discharging of the integrator integrator is therefore proportional to the input voltage.

The disadvantage of this arrangement is that discharging of the integrator capacitor of the integrator is carried out directly by the input voltage and it is therefore very important that the input voltage does not change during the conversion. Another problem is the realization of a precision inverter that has to be integrated upstream of the integrator.

The best results are currently achieved with converters where, as in previous cases, the input voltage is integrated and the comparator compares the output voltage of the integrators with the comparator level. However, when the comparative voltage is reached, a reference voltage source is connected to the resistor connected to the integrator summing point for a precisely defined time, thereby discharging the integrating capacitor.

The disadvantage is that the electronic switches used for connecting the reference voltage source have a non-zero resistance in the closed state, which in addition varies again depending on the current flowing and the ambient temperature. Since diode switches are most often used due to the higher switching speed, their so-called threshold voltage needs to be further compensated. However, the temperature dependence of the threshold voltage of the diodes is usually not fully compensable. Similarly, when using transistor switches, the temperature dependence of the resistance of the closed switch cannot be fully compensated.

Another transducer arrangement uses a reference current source to discharge the integrator capacitor of the integrator, thereby suppressing the real properties of the diode switch. A digital circuit is directly connected to the integrator output which controlled the connection of the reference current source by the diode switch to the integrator summing point.

The disadvantage of this arrangement is that the output voltage of the integrator is controlled directly by the digital circuit, which usually has an input insensitivity of up to 1.4 V. to significantly reduce conversion accuracy.

These disadvantages are largely eliminated by the wiring of a precise voltage to frequency converter according to the invention, consisting of an operational amplifier to which an input terminal is connected via an inverting input. There, the reference voltage source and the cathode of the first electronic switch diode and the first end of the integrating capacitor are connected via an auxiliary resistor, which is connected to the output of the operational amplifier by its other end. The non-inverting input of the operational amplifier is connected to an auxiliary voltage source. The circuit further comprises a flip-flop having a blocking and clock input and output, wherein the clock input is coupled to a reference time interval source and an output to the output terminal and simultaneously to the cathode of the second electronic switch diode. The anodes of the two electronic switch diodes are connected to a reference current source. It is an object of the invention that the output of an operational amplifier is coupled to the first comparator input, the second comparative voltage input and the comparator output being coupled to the latch input of the flip-flop.

The advantages of connecting the exact voltage to frequency converter according to the invention are in particular that the input insensitivity of the flip-flop does not apply and at the same time the possible distortion of the operational amplifier output voltage due to the flip-flop input circuits is eliminated. In doing so, all the advantages of discharging the integrating capacitor from the reference current source for a precisely defined time are retained.

The invention will now be described in more detail with reference to the accompanying drawing, in which a circuit diagram of an exemplary embodiment of a precise voltage to frequency converter according to the invention is shown.

The inverting input of the operational amplifier 6 is through a resistor R connected between the input terminal 2> forth therein is connected via an auxiliary resistor _Rp connected reference source 2 voltage and the cathode of the diode D ^ electronic switch 2 · Between the inverting input of the operational amplifier 2 ^and its output is connected integral capacitor C when the non-inverting input of the operational amplifier 2 is connected to the auxiliary power supply 2. The output of the operational amplifier 6 is connected to the first input of the comparator 2 »the second input of the comparator 2 3 ^e is connected to a source of voltage comparator T_. The output of the comparator 2 is connected to the latch input of the flip-flop 2. The clock input of the flip-flop 2 is connected to the source 10 of the reference time interval. The output of the flip-flop 2 ³ and simultaneously the output terminal 11 of the whole arrangement. The output terminal 11 is also connected to the cathode of the second diode D ₂ of the electronic switch 2 · anodes of both diodes D ^, D ₂ of the electronic switch 2 are connected to a source 2 of the reference current.

In operation, the accurate voltage-to-frequency converter is fitted with a differential operational amplifier 2. In addition, an additional current is applied to the inverting input of the operational amplifier 2 via an auxiliary resistor 2θ and a reference voltage source 2, which allows to shift the conversion characteristic of the entire voltage converter to a frequency so that both input voltage polarities can be processed. The auxiliary power supply 2 connected to the non-inverting input of the operational amplifier 2 allows a voltage shift of the inverting input of the operational amplifier 6 to be at a potential favorable to the operation of the electronic switch 2. the moment when the output voltage of the operational amplifier 6 reaches the comparative level given by the comparative voltage source 7. This will release the blocking input of the flip-flop 2 ^, but this flips only after the arrival of the rising edge of the pulse supplied from the reference time interval 10. The output of flip-flop 2 closes the second diode D _{2 of the} electronic switch 4 and the first electronic switch 2 of the reference current source 2 is closed. In this way, the integrating capacitor C is discharged by the reference current. The falling edge of the reference time interval causes the flip-flop 2 to flip to its original state and the reference current source 2 is disconnected from the inverting input of the operational amplifier 6. The frequency of charging and discharging the integrating capacitor C is linearly proportional to the input voltage. The frequency of the output signal taken from the output terminal 11 against the common conductor 12 is therefore linearly dependent on the input voltage according to the formula: U denotes the input voltage applied to the input terminal 1, F is the signal frequency at the output terminal 11 of the converter; ° ^F = O ^{= 'I} R ^{and T} R ^U H ^<+ ϊζ 1>

and F is the frequency deviation converter where I _R is the current supplied by source 3 and the reference current, and T _R for the duration of the pulse supplied from the source of the reference interval 10 ϋθ voltage reference source 2 voltage Rq resistance auxiliary resistor Rq, _LR voltage of the auxiliary voltage source 5, R resistor R

If the condition U => O is fulfilled, I _R = O can be selected U _Q = 0 and R _Q If the output of flip-flop 9 operates at TTL levels, the auxiliary power supply 5 must have a voltage of approx. 1.5 V. However, if the output of flip-flop 2 is adjusted by means of a voltage level converter so that its output is at a level of about + 1.5 V, it is possible to choose the voltage of the auxiliary power supply 2 zero. As a diode, it is suitable to use Schottky diodes in the electronic switch 4 because they are characterized by a very short recovery time in the reverse direction.

A somewhat more complicated solution of the discharging time interval generator formed by the flip-flop 9 and the reference time interval source 10 is given by the fact that due to the high accuracy of the conversion the time interval is derived from the frequency of the crystal controlled oscillator. it is therefore not exactly proportional to the input voltage. In the integrating capacitor, however, the error of each transmission is remembered and as soon as the error accumulates above a certain limit, the converter corrects the output frequency. Therefore, the voltage to frequency conversion is very accurate over a longer period of time.

The precision voltage to frequency converter of the present invention is of general use and can be advantageously applied wherever a very accurate voltage to frequency conversion is required. In particular, the precise voltage to frequency converter according to the invention can be used in measuring and instrumentation technology, for example in precision digital voltmeters and ammeters, in digital correlators or in devices for harmonic signal analysis based on the modified Fourier analysis principle.

Since the circuit design of the converter according to the invention is not very complex, the circuit is suitable for implementing hybrid technologies.

Claims (1)

Precision voltage to frequency converter consisting of an operational amplifier, the inverting input of which is connected via an input terminal through a resistor, a reference voltage source connected via an auxiliary resistor, and a cathode of the first electronic switch diode and the first pole of the integrating capacitor connected with the output of the operational amplifier while the non-inverting input of the operational amplifier is connected to an auxiliary voltage source and further comprising a flip-flop having a blocking and clock input and output, where the clock input is connected to the reference time interval source and output to the output terminal electronic switch diodes, wherein the anodes of both electronic switch diodes are connected to a reference current source, characterized in that the output of the operational amplifier (6) is connected to the first input of the comparator (8) at wherein the second comparator input (8) is coupled to a comparator voltage source (7) and the comparator output (8) is coupled to a latch input of the flip-flop (9).