CS266037B1 - Simple digit-to-frequency converter - Google Patents

Abstract

The wiring relates to a simple number to frequency converter. The essence of the solution is that the input code combination corresponding to the converted number is supplied to a digital input of a digital-to-analog converter whose current output is switched by an electronic switch. If the digital output of the digital-to-analog converter is connected by an electronic switch to the inverting input of the second operational amplifier, the capacitor connected in the feedback of the second operational amplifier is directly charged by the digital-to-analog converter output current. After switching the electronic switch, the output current of the digital-to-analog converter is converted by a circuit consisting of a first operational amplifier, a feedback resistor, and a resistor from the resistor to a reverse polarity current, and the capacitor is discharged. Switching of the electronic switch is controlled by a comparator with hysteresis, which monitors the output voltage of the second operational amplifier so that after reaching the upper-level in the capacitor charging mode the capacitor will be discharged for as long as the voltage reaches the lower comparative level again. The entire process is repeated, wherein the frequency of the triangular oscillations at the first output terminal and the frequency of the rectangular oscillations at the second output terminal are directly proportional to the code combination fed to the digital input of the digital-to-analog converter. The wiring has a general application for instrumentation and industrial applications with moderate demands on number to frequency conversion accuracy. In particular, the connection is suitable for the construction of programmable frequency sources for controlling stepper motors.

Description

The invention relates to a simple number-to-frequency converter.

Several ways to convert a number to a frequency are known. In the first of these, the input code combination corresponding to the decimal number is first converted to a voltage in a digital-to-analog converter, and then this voltage is converted to a frequency in the voltage-to-frequency converter.

The disadvantage of this arrangement is the peripheral complexity and cost. Digital-to-analog converters are usually designed with a direct current output, such as Czechoslovak converters. produces MDACO8, MDAC565, MDAC566 and it is necessary to convert their output current to voltage by an external operational amplifier, which is connected as a current to voltage converter. The output voltage of the converter must then be converted to frequency in another converter.

The second way to convert a number to a frequency is provided by frequency synthesizers. Currently, the most commonly used synthesizers with a phase-locked loop, which contain a source of reference frequency, a programmable frequency divider, a voltage-controlled oscillator, a phase-frequency detector and possibly and output frequency dividers. The so-called direct frequency synthesis is also used to a limited extent.

The disadvantage of frequency synthesizers is also the circuit complexity and high cost.

Transducer arrangements are also known which use charging the capacitor in an integrator from the current output of a digital-to-analog converter. The output voltage of the integrator is compared in a comparator with a comparison level. After reaching the comparison level, a reference voltage source is connected to the resistor connected to the summing point of the integrator for a defined time determined by the time constant of the monostable flip-flop circuit, thereby discharging the integration capacitor. The whole process is repeated periodically, the frequency of the pulses at the output of the monostable flip-flop being directly proportional to the code combination at the digital input of the digital-to-analog converter. A similar arrangement uses a reference current source to discharge the integration capacitor. When higher conversion accuracy is required, the monostable flip-flop is in some cases replaced by a timing circuit in which the time of the generated pulse is derived from the frequency of the crystal-controlled oscillator.

Although these arrangements are relatively simple, they may not be suitable in all cases, especially if the low cost of the device is observed. In addition, a crystal-controlled oscillator must be used for transducers with a timing circuit. These types of converters also cannot be used in digitally controlled function generators, because the alternation of triangular oscillations at the output of the integrator and the alternation of rectangular oscillations at the output of a monostable or timing circuit is not 1: 1.

This disadvantage is to some extent eliminated by the connection of a simple number-to-frequency converter, the essence of which is that the input code combination corresponding to the converted number is fed to the digital input of a digital-to-analog converter whose direct current output is connected to the input of an electronic switch. The first output of the electronic switch is connected to the inverting input of the first operational amplifier, which has a feedback resistor connected between the inverting input and the output. The non-inverting input of the first operational amplifier is connected to a common conductor and its output is then connected to a resistor, the other end of which is connected to the inverting input of the second operational amplifier. The second output of the electronic switch is also connected there, and a capacitor is connected between the inverting input of the second operational amplifier and its output. The non-inverting input of this operational amplifier is connected to a common conductor and its output is then connected to the first output terminal and to the input of the hysteresis comparator.

The output of the hysteresis comparator is connected to the control input of the electronic switch and also to the second output terminal.

The advantage of connecting a simple number-to-frequency converter is the low cost while maintaining sufficient accuracy of the conversion. In this case, there is no reduction in accuracy due to the intermediate conversion of the output current of the digital-to-analog converter to voltage and its subsequent conversion to frequency, because the output current of the digital-to-analog converter is converted directly to frequency. It is also advantageous that the accuracy of the conversion is not affected by the final resistance of the electronic switch in the closed state, nor changes in this resistance depending on the flowing current or ambient temperature, because these quantities do not matter much in terms of switching the output current of the digital-to-analog converter. In addition, the converter can very easily be used as a basic building block in digitally controlled function generators, because the alternation of triangular oscillations at the first output and the alternation of rectangular oscillations at the second output is 1: 1.

The invention is described in more detail below with reference to the accompanying drawing, in which an exemplary embodiment of a simple number-to-frequency converter is shown. .

The input code combination corresponding to the converted number is fed to the digital input of the digital-to-analog converter 2. The direct current output of the digital-to-analog converter 1 is connected to the input of the electronic switch 2. and the output is connected to a feedback resistor 2.

Ibid is also connected to a second output of the electronic switch 2 and the inverting input of the second operational amplifier 2 ^and its output is connected capacitor 2 · The non-inverting input of the operational amplifier 2 3 ^e is connected to a common conductor £ and its output is then connected both to the first output terminal 10 and on the one hand with the input of the comparator 2 ^with hysteresis. The output of comparator 2 ^with hysteresis is connected to the control input of the electronic switch 2 and the second output terminal 11th

In operation, the code combination D corresponding to the converted number is applied to the digital input of the digital-to-analog converter 2. If, for example, we use a ten-bit binary digital-to-analog converter to implement a simple number-to-frequency converter according to the invention, the digital-to-analog converter 2 will supply current

I = I '

024 R 'where D, „is the decimal equivalent of a ten-bit binary number D from the range of integers 10 0 to 1 023 and I is the internal reference current of the digital-to-analog converter £. During the operation of the converter, the intervals of supplying the capacitor £ with positive and negative current alternate periodically. The transition from one mode to another is provided by an electronic switch 2, the operation of which is controlled by a comparator £ with hysteresis according to the voltage level at the output of the second operational amplifier £. Assume first that the direct current output of the digital-to-analog converter 1 is connected by an electronic switch 2 to the inverting input of the second operational amplifier 6. Then the voltage at the output of this operational amplifier increases linearly with time according to the equation u (t) = U _D + ít, where 1> _D is the lower level of the comparator voltage of the comparator £ with hysteresis, I the output current of the digital-to-analog converter £, C capacitance £ at means time. Once this voltage reaches the upper level of the comparative voltage U _H £ comparator with hysteresis, to flip the comparator £ and thus the switching of the electronic switch 2. The time required to make the output voltage of the second operational amplifier £ switched from level to level, is given by ^T 1 = ^(U H - ^U D> ^{C / I} 'where the meaning of individual quantities is the same as in the previous one. The second phase of the process follows. The output voltage of the second operational amplifier 2 ^{decreases linearly with} time according to the equation ^H 1 I. ^{U (t} > = ° H where is the resistance of the feedback resistor 2 * ^R 2 ^{from the} P ^or resistor and the meaning of the remaining quantities remains valid.The output voltage of the second operational amplifier _8 goes from the upper comparison level to the lower comparison voltage over

T ₉ = (U „- UJR.C / R.!, Z π DZ ± where the meaning of the quantities is the same as in the previous equation. After reaching the lower level of comparator voltage comparator 2 ³ hysteresis, it reacts again by flipping its output level. If we assume that the resistances of the feedback resistor 2 ^{and the} resistor 6 are the same, ie = R ₂ , we can deduce from the previous considerations that the action repeats with the period

T = 2 (U „- ϋ _η ) C / I. Π D

It is clear from the explanation of the operation that triangular oscillations against the common conductor 4 can be taken from the first output 10 and then rectangular oscillations against the second output 11. The frequency of the output oscillations f is directly proportional to the decimal equivalent D _{1Q of the} code combination D according to the relation

048 (U _u - U ^) C ^ιυ HD where the meaning of individual quantities has been clarified earlier. In addition, if we choose U-, = -U. _T and if we use D ti comparator, 9 with hysteresis with symmetrical output voltage, the circuit can easily be used as a digitally controlled function generator, because from the first output 10 we can take symmetrical triangular oscillations and from the second output 11 symmetrical rectangular oscillations with alternation.

1: 1. As a comparator 2 ^with hysteresis, for example, an integrated timer of type designation 555 can be used in the circuit.

The simple number-to-frequency converter according to the invention has a general use and can be advantageously applied wherever a simple method of direct number-to-frequency conversion is required. In particular, a simple number-to-frequency converter according to the invention can be used for instrumentation and industrial applications, e.g. for the construction of programmable frequency sources for stepper motor control.

Claims (1)

A simple number-to-frequency converter, characterized in that the output of the code combination corresponding to the number to be converted is connected to a digital input of a digital-to-analog converter (1), the direct current output of which is connected to the input of an electronic switch (2). ) is connected to the inverting input of the first operational amplifier (5), which has a feedback resistor (3) connected between the inverting input and the output, the non-inverting input of the first operational amplifier (5) being connected to a common conductor (4) and its output to the resistor (6), the other end of which is connected to the inverting input of the second operational amplifier (8), to which the second output of the electronic switch (2) is also connected and a capacitor (7) is connected between the inverting input of the second operational amplifier (8) and its output ), wherein the non-inverting input of the second operational amplifier (8) is connected to a common conductor (4) and its output is then connected on the one hand to the first output terminal (10) and on the one hand with the input of the comparator (9) with hysteresis, the output of which is connected on the one hand to the control input of the electronic switch (2) and on the other hand to the second output terminal (11).