SU955111A1 - Function converter - Google Patents

Description

(5) FUNCTIONAL TRANSFORMER

Claims (2)

The invention relates to analog computing and can be used in automation devices and information-measuring devices. A functional converter with a piecewise linear approximation, containing operational amplifiers, parallel-connected approximating transistor cells, a potentiometer CO, is known. The closest technical solution to the proposed is a functional converter containing a voltage divider on two series-connected resistors, the free output of the first resistor is the converter input and the free output of the second resistor is connected to the zero potential bus, h in parallel approximating transistor cells, each of which consists of a first potentiometer connected in series and a MIS transistor, the gate of which is connected to the moving contact of the second potentiometer 2. A disadvantage of the known converters is the dependence of the output voltage on the ambient temperature. The purpose of the invention is to expand the class of reproducible functions. . The goal is achieved by the fact that in a functional converter containing a voltage divider on two series-connected resistors, the free terminal of the first resistor is the input of the converter, and the free terminal of the second resistor is connected to the zero potential bus, parallel-connected approximator transistor cells, each of them which consists of serially connected first potentiometer and MIS transistor, the gate of which is connected to the moving contact of the second potentiometer, are introduced The temperature sensor, the first and second DC amplifiers, the drains and sources of MIS transistors are connected to the common output of a voltage divider, the drains of MIS transistors are connected through the corresponding first potentiometers to the converter input, the first terminals of the second potentiometers approximating transistor cells connected to the output of the first. DC amplifier (whose inverting input is connected via a temperature sensor to the output of a second DC amplifier, which is a converter output connected to the inverting input of a second DC amplifier and to the second terminals of second potentials, and a non-inverting input of a second CONSTANT amplifier current is connected to the common output of the voltage divider. The temperature sensor is made on a thermistor, a zener diode and two resistors, and the zener diode is connected in parallel to the connected terminals thermistor and the first resistor, the common output of which is the output of the sensor, is connected to the inverting input of the first DC amplifier, and the free output of the first resistor is connected to the first output of the second resistor and the first output of the Zener diode, the second output of which is free The output of the thermistor, which is the input of the sensor, is connected to the output of the converter, the second terminal of the resistor is connected to the power supply. The drawing shows a diagram of the functional converter. The functional converter contains a voltage divider on the first 1 and second, 2 resistors, converter 3 input, MOS transistors, first potentiometers, second potentiometers 6i (-6 |;, second amplifier 7, approximating transistor cells, first amplifier 9, sensor 10 temperature, thermistor And, zener diode 12, the first and second resistors 13 and H, power terminal .15. The functional converter operates as follows. 14 The functional converter is designed to form a temperature-dependent voltage curve, with positive second derivative aL .. Q dT40 (where Rj is the resistance of resistor 1 and parallel-connected approximation cells; R2 is the resistance of resistor 2. At zero input voltage, MOSFET transistors; - 4 are closed and the output voltage is determined by the ratio of resistors 1 and 2 voltage divider. When the input voltage reaches the setpoints of the MOS-Transistors-n, the sub-switch 5 / | -5p potentiometers parallel to the resistor 1 of the voltage divider are opened. The response thresholds of MOS transistors are set using potentiometers (and the output voltage is set using potentiometers. By appropriately selecting the response thresholds of MIS transistors and resistance of shunt potentiometers, you can reproduce with a given accuracy a function with a positive second derivative. Since the input of the first amplifier 9, a temperature sensor is connected, then a voltage will be created at the output of this amplifier, the value of which is proportional to the ambient temperature. The temperature sensor is made on a thermistor, a zener diode and two resistors, the zener diode being connected in parallel to series-connected thermistor and the first resistor, the common output of which, being the sensor output, is connected to the inverting input of the first amplifier. The output of the second resistor is connected to a power source. The second operational amplifier 7 performs isolation functions and is designed for isolating the circuits: the common output of a voltage divider is 1.2 and t glasses connecting the lower arms of the potentiometers and temperature sensors 10. The connection of the temperature sensor 10 to the output of the device is caused by the floating mode of the sources of the MOS transistors. Since the lower arm of the temperature sensor 10 is under the floating potential (power terminal 15), Zener diode 12 is connected to ensure the formation of temperature-dependent voltage parallel to the thermistor 11. Functional The converter is most promising for use in temperature compensation of the input analog voltage and can be widely used for temperature compensation. minutes depending sensors analyzers Analytical Instrument. The number of channels And in the device depends on the accuracy of the linearization, to the torus can be a value of about 0.2% on the upper scale range. Claim 1. A functional converter containing a voltage divider on two series-connected resistors, the free terminal of the first resistor is the input of the converter, and the free terminal of the second resistor is connected to a zero-potential bus, L parallel-connected approximating transistors, each of which consists of series-connected first a potentiometer and a MOS transistor, the gate of which is connected to the moving contact of the second potentiometer, characterized in that expanding the class of reproducible functions, including a temperature sensor, first and second DC amplifiers, and a drain. And the sources of the NDP transistors are connected to the common output of the voltage divider, the drains of the MOS transistors through the corresponding first potentiometers are connected to the input of the converter, the first outputs of the second potentiometers are apro; The i xing transistor cells are connected to the output of the first DC amplifier, the inverting input of which is connected via a temperature sensor to the output of the second DC amplifier, which is the output of the converter, connected to the inverting input of the second DC amplifier and to the second terminals of the second potentiometers, and the non-inverting input of the second DC amplifier is connected to the common output of a voltage divider. 2. The converter according to claim 1, differing in that the temperature sensor is made on a thermistor, a zener diode and two resistors, the zener diode being connected in parallel to a series-connected thermistor and a first resistor, the common output of which, being the output of the sensor, is connected to the inverting input of the first the DC amplifier, and the free terminal of the first resistor is connected to the first terminal of the second resistor and to the first terminal of the zener diode, the second terminal of which is the free terminal of the thermistor, which is th sensor, connected to the output converter of the second terminal of the second resistor connected to the source pi Tani. Sources of information taken into account during the examination 1. USSR author's certificate tf 296121, cl. G 06 G 7/26, 1968. 2. USSR author's certificate f, cl. G About G 7 / 2b, 1977 (prototype). BJI UO About Dm: