SU1109765A1 - Function generator - Google Patents

Abstract

A FUNCTIONAL TRANSMITTER contains keys, the first of which is connected by a control input to the first output of the synchronization unit, and the output to the first input of an integrator connected by a second input to the output of a scaling resistor matrix connected by inputs. to the corresponding outputs of the switch connected by the information inputs to the first and second outputs of the reference voltage source, the integrator's output being connected to the information input of the sample-storage unit connected by the control input to the second output of the synchronization unit whose reference frequency input is connected to the first an output of the master oscillator, characterized in that, in order to spread out the field of application of the functional converter, a pulse distributor has been added to it, Vatel voltage in pulse duration, output .schetchik switch and the comparator, the first input coupled to the input of the functional argument transformation. bodies and with the signal input of the first key, the second input - with a bus of zero potential functional. the converter and the output from the control input of the switch connected by the signal inputs to the outputs of the source of the reference voltage (P, and the output to the signal input of the second switch connected to the third input of the integrator, and the control input to p. the output J of the voltage converter to the pulse duration gated by the input of the output counter and with the gate input of the synchronization unit connected by the third and fourth c outputs to the control input of the voltage converter j pulse and output reset output j 05 sd counter, respectively, and a group of outputs to the inputs of the distributor I pulses connected to the control inputs of the switch, the counting input of the output counter connected to the second output of the master oscillator, and the information input of the voltage converter to the pulse duration connected to the output of the sample-hold unit.

Description

The invention relates to automation and computing technology, in particular to devices for the functional conversion of analog signals to voltage, pulse duration and a digital code. A known functional converter comprising an analog-to-digital converter, a switching unit, a voltage converter in a pulse duration, a program block, pulse generators, AND elements and an output counter. The disadvantages of the functional converter are limited scope and structural complexity. A functional converter is also known, which contains a reference voltage source, keys, a decoder, scale resistor groups, a linear voltage divider, an operational amplifier and an output conversion unit to code 21. The disadvantage of this functional 5 converter is the limited scope. The closest to the invention is a functional converter containing keys, the first of which is connected by a control input to the first output of the synchronization unit, and the output is connected to the first input of the integrator connected by the second input to the output of a scaling resistor matrix connected by inputs to the corresponding outputs a switch connected by information inputs to the first and second outputs of the reference voltage source, the integrator output being connected to the information input of the sampling-storage unit, with A single control input with the second output of the synchronization unit, the reference frequency input of which is connected to the first output of the master oscillator, the control inputs to the inputs of the function converter arguments, the third input to the control input of the second switch and the control input of the switch, and the group of outputs is connected to the control input groups of the switch, the third output of the source of the reference voltage is connected to the signal input of the second switch connected by the output to the first input of the integrator, and the signal input of the first The key is connected to the output of the sample-hold unit. The synchronization block contains a counter and a time interval shaper, the counting input of which is connected to the clock frequency reference input and the counting counting input, the control inputs to the control inputs of the synchronization unit, the first, second and third outputs to the first, second and third outputs the synchronization block, and the fourth output - from the control input of the counter, the outputs of which are a group of outputs of the synchronization block D31. However, the converter, although it does allow non-linear conversions of the argument represented by the digital code to the output voltage, but does not allow the functional conversions of the argument, represented as voltage, to the output signals, represented as voltage, pulse duration and digital code, respectively. This limits the scope of the functional converter. The purpose of the invention is to expand the scope of application of the functional converter. The goal is achieved by the fact that a functional converter contains keys, the first of which is connected by a control input to the first output of the SYNCHRONIZATION unit, and the output to the first input of an integrator connected by a second input to the output of a scaling resistor matrix connected by inputs to the outputs of the switch connected by the information 7 inputs with the first and second outputs of the source of the reference voltage, the output of the integrator connected to the information input of the sampling-storage unit, A single control input with a second output of the synchronization unit, the reference frequency input of which is connected to the first output of the master oscillator, is additionally introduced a pulse distributor, a voltage to voltage converter, an output counter, a switch and a comparator connected by the first input to the argument input of the functional converter and with signal input of the first key, the second input -; WITH BUS A zero potential functional converter, and output with control

the input of the switch connected by the signal inputs to the outputs of the reference voltage source, and the output to the signal input of the second switch connected by the output, with: the third inputs of the integrator, and the control input - with the output of the voltage converter in the pulse width, the gate input of the output counter and with the gate input of the synchronization unit connected to the third and fourth outputs to the control input of the voltage converter in the pulse duration. And to the output input of the output counter, respectively and a group of outputs to the inputs of the pulse distributor connected by the outputs to the control inputs of the switch, the counting input of the output counter being connected to the second output of the master oscillator, and the information input of the voltage to voltage converter connected to the output of the sampling-storage unit

FIG. 1 is a block diagram of a functional converter; on. FIG. 2 - time diagrams for the work.

The proposed device (FIG. 1) contains a source 1 of a reference voltage, a switch 2, a scaling resistor matrix 3, an integrator 4, a sampling-storage unit 5, a synchronization unit 6, a pulse distributor 7, a master oscillator 8, a voltage-to-pulse converter 9 , output counter 10, the first key 11, the comparator 12, the switch 13 and the second key 14..

The key 11 is connected by a control input to the first output of the synchronization unit 6, and the output to the first input of the integrator 4. The integrator 4 is connected by a second input to the output of a resistor matrix 3 connected by inputs to the corresponding outputs of switch 2. The switch 2 is connected by information inputs to the first and second the outputs of the source 1 reference voltage. The output of the integrator 4 is connected to the information input of the sampling-storage unit 5, which is connected by a control input to the second output of the synchronization unit 6. The input frequency reference unit 6 is connected to the first output of the generator 8. Comparator 12

connected by the first input to the input argument of the functional converter and to the signal input of key 11, the second input to the zero potential bus of the functional converter, and outputs to the control input of switch 13. Switch 1.3 is connected by signal inputs to output sources 1, and output to the signal input the input of the key 14 connected by the output to the third input of the integrator 4, and the control input to the output of the voltage converter 9 to the pulse duration

sa gate input of the counter 10 and the gate input of the synchronization unit 6. Block 6 is connected by the third and fourth outputs to the control input of the converter 9 and

the reset input of the counter 10, respectively, and a group of outputs to the inputs of the distributor 7 pulses connected by outputs to the control inputs of the switch 2. The counting input of the counter 10 is connected to the second output of the generator 8, and the information input of the converter 9 is connected to the output of the sampling unit 5 - storage. Synchronization unit 6 contains counters 15

and 16, the counting inputs of which are connected to the input of the frequency reference of block 6, and the control input of counter 15 to the gate input of the block. The outputs of the counter 16 are connected to the inputs

decoder 17 whose outputs are the first, second, third and fourth outputs of block 6, and the outputs of counter 15 are a group of outputs of block 6.

 Functional converter operates cyclically.

In each cycle, the following is carried out: the integrator integrates the 4th voltage Tsu of the argument during the time Tc, specified by the synchronization unit 6; sampling of the output voltage of the integrator 4 blocks 5. sampling followed by memorizing it during the cycle time Tm; integration of the compensation voltage (or -E) of the source 1 of the reference voltage by the integrator 4 (the sign of this voltage is chosen opposite to the voltage of the argument voltage Ux using the comparator 12 and the switch 13) during the compensation time interval Tu. which is set by the voltage-to-pulse converter 9, alternately turning on each of the t.e3HCTopoB resistor matrix 3 between the source 1 of the reference voltage and the input of the integrator 4 during the compensation time% and filling the compensation time interval Tou with the reference frequency t setting generator 8. Assume that before starting P1) the voltage at the output of sampling-storage unit 5 is equal to an arbitrary value, then the voltage at the output of sampling-storage unit 5 after the end of a series of operation cycles tel i. in the steady state, with an appropriate choice of the capacitor of the integrator capacitor 4, ensuring the convergence of the process, it becomes equal: t to t. P | T. ,). (. fel.M |; gp Luy GG - 4 i-4 M Ya. - the time of time is resisted by the integrator A on its third input. (compensation input); 2 - the time is set by the integrator 4 by its first input (measurement input);, СЯ-г - transfer coefficient pre; generator 9, Е - voltage of source 1, connected to the matrix resistor 3; i - resistance of i-ro resistor of matrix 3; tt - number of inputs of matrix 3 -, t- is the time from the beginning of the cycle to the beginning of the h-th plot of approximation, the sign function. The duration of the next pulse T% at the output of the converter 9 in the the state becomes equal and the code at the output of counter 10 is determined by the expression Ny, M gS, p gLHfjEjM-fe) (.TR bo EoG. w2 Thus, the code at the output of the functional converter consists of two terms. The first term is proportional to. argument, and the second is determined by the values of the resistances -i of the resistors of the matrix 3 and the time f. they are connected.The connection of the resistors of the matrix 3 is terminated at the end of the compensation time interval Tu. As an example (Fig. 2), timing charts of currents are introduced. T T e coming to the inputs of the integrator, 4, respectively, through the keys 11 and 14 and the resistors Ry (matrix 3 at a certain compensation time interval, as well as curves of the functional dependence of the output code of the converter from the input parameter P of the sensor, the output voltage Oy of which serves as input to the converter (curve 1 - in the case of no-liter (curve 1 - in the case without linearization, curve 2 - in the case of linearization, curve 3) and i-ideal.) In this case, the required functional dependence is semi1, using a piecewise linear approximation that has tenth sections. Resistance and polarity of the voltage connected to it are selected depending on the angle of inclination of each section of the curve. Thus, using a functional converter, it is possible to realize different functional dependencies of the output the code from the sensor voltage at a relatively high accuracy and low hardware costs. The requirements for accuracy and stability of the resistors of the matrix 3 can be relatively low. For example, with non-linearity of the order of 5% (typical value for many sensors used in industry), the effect of the instability of the resistance of the matrix 3 resistors is reduced by approximately 20 times, which, with the required conversion error of 0.1%, allows the use of resistors with an instability of resistance within 2 %, i.e. low cost AMLT, C2-23, etc. resistors. The requirements for the newly introduced units are also low. Voltage converter 9 to pulse duration can be built according to the simplest scheme (integrator-comparator), since its error is not included in equation (1) and transformed, and measuring its transmission coefficient Kp can only affect the convergence of the conversion process. Thus The proposed converter performs nonlinear conversion of voltage to voltage, pulse duration, and digital code, which expands the area of its possible application in comparison with the known one. Conversion of the converter from one function to another can be performed based on the resistor rearrangement of matrix 3 or matrix replacement.

Claims (1)

FUNCTIONAL CONVERTER containing keys, the first of which is connected by the control input to the first output of the synchronization unit, and by the output - to the first input of the integrator, connected by the second input to the output of the scaling resistor matrix, connected by the inputs to the corresponding outputs of the switch, connected by information inputs with the first and the second outputs of the reference voltage source, and the integrator output is connected to the information input of the sampling-storage unit, connected by a control input to the second output a synchronization unit house, the reference frequency input of which is connected to the first output of the master oscillator, characterized in that, in order to expand the scope of the functional converter, a pulse distributor, a voltage to pulse width converter, an output counter, a switch and a comparator connected to the first are additionally introduced into it the input with the input of the argument of the functional converter and with the signal input of the first key, the second input with the bus of the zero potential of the functional transform phone, and the output - with the control input of the switch, sub-; connected by the signal inputs to the outputs of the reference voltage source, and the output to the signal input of the second switch, connected by the output to the third input of the integrator, and the control input - with the output of the voltage converter to the duration! the pulse by the gating input of the output counter and with the gating input of the synchronization unit connected by the third and fourth outputs to the control input of the voltage converter in the pulse duration and the reset input of the output counter, respectively, and by the group of outputs to the inputs of the pulse distributor connected to the control outputs the inputs of the switch, and the counting input of the output counter is connected to the second output of the master oscillator, and the information input of the voltage converter in duration and pulse connected to the output of sample-storage unit.