SU995317A1 - Resistance-to-time internal converter - Google Patents

Description

The invention relates to electrical engineering and can be used in digital electrical appliances, automation devices.

A known converter containing measured resistors, the terminals of which are connected via transistor switches to the terminals of a decoder connected to a counter, a constant voltage source, a discharge resistor connected via a key to a capacitor, a threshold element, parametric stabilizers consisting of zener diodes ·, and a ballast resistor, a constant voltage source through a ballast p> resistor and zener diodes is connected to the first terminals of the measured resistors, the common point of the ballast resistor and zener diodes By connecting the one plate of a capacitor, the other plate of which is connected to the second terminals of the measuring resistor; the output of the threshold element is connected directly to one input of the counter, and to the other inputs through the delay element [1b Using zener diodes to fix the voltage level at the input of a chain consisting of a capacitor and a measured resistor, due to the spread of the zener diode parameters, the conversion error increases. ''

A known Converter containing an amplifier with a differential RC circuit of the OOS, the output of which is connected to one of the inputs of the comparison unit, two bipolar current stabilizers, separately connected to. inputs of a two-current current switch, the control input of which is connected to the output of the comparison unit, and the output is connected to the second input of the comparison unit and to the divider from the reference resistor and the measured resistor, the midpoint of the divider connected to the non-inverting input of the operational amplifier [2].

The presence of two bipolar current stabilizers and the requirement of their identity complicates the converter circuit and reduces the accuracy of the conversion.

The closest in technical essence to the proposed one is a converter that contains a bridge, the first branch of which is formed by subsequently connected measured and the first resistor, the second branch in series with the second and third resistors, a power source connected in parallel with the bridge branches, a capacitor connected in parallel resistor second branch adjacent to the measured resistor, the control unit, the output kotopervy contact which is connected to the common point> _and third resistors entry unit alignment, which is connected to the compound being measured and the output unit connected to the control cerned key input: Nia connected to first and second input of the second common point and a first resistor connected to the input of the comparison control unit [3].

A disadvantage of the known resistance converter in the time interval is the low accuracy of the conversion, due to the time and temperature drift of the zero level signal of the comparison unit.

The purpose of the invention is to increase the accuracy of the conversion of resistance into a time interval.

This goal is achieved in that in a resistance converter in a time interval containing a bridge, the first branch of which is formed by series-connected measured and first resistors, the second branch is series-connected by second and third resistors, a power source connected in parallel to the bridge branches, a capacitor connected in parallel to the resistor the second branch adjacent to the measured resistor, the control unit, the output of which is connected to the control input of the key, the first contact of which is connected to the common connection point of the second and third resistors and to the first input of the comparison unit, the output of which is connected to the input of the control unit, the output of the comparison unit is connected to the second key contact, the second input of the comparison unit is connected to the switching contact of the switch, the normally closed contact of which is connected to the common bus, normally open - to the common connection point of the measured and the first resistors, and the control input of the switch is connected to the output of the control unit.

The drawing shows a block diagram of the proposed device.

The resistance converter in the time interval contains a comparison unit 1, a single-position switch 2, a two-position switch 3, a control unit 4-65, a power supply unit 5, resistors

6-10, a resistor 11, the resistance of which is measured, and a capacitor 12.

The resistance measurement cycle is performed in two cycles. In the first cycle, when zero level correction is carried out, key 3 is closed to the series connection of resistors 8 and 9, key 2 is closed. The resistance value corresponds to the initial value of the measuring range of the measured resistor 11. In this cycle, the comparison unit 1 is covered by negative feedback (OOS), due to which the voltages at the inputs of the comparison unit 1 are aligned.

In the second cycle, the key 3 closes on the serial connection of the resistors 10 and 11 and at the same time the key 2 opens. The capacitor 12 starts to charge. At the moment of equal voltage on the resistor 11 'and the capacitor 12, the comparison unit 1 generates a comparison signal that is input to the control unit. The time interval "during which the charge of the capacitor 12 occurs is proportional to the value of the measured resistor 11.

When measuring the increment of resistance in the measuring range ZJR = R _n - R _Q 'where R _n is the nominal value of the resistance; RQ is the initial resistance value. The resistance of the resistor 9 is selected equal to R _o , and the resistance of the resistors 8 and 10 are equal. In this case, the voltage Ur corresponding to the beginning of the measurement range ^{0 is} stored in the first cycle on the capacitor 12. Therefore, in the second cycle, the capacitor 12 is charged not from zero, but from the voltage Ur _in and the time interval produced by the converter. will be proportional to the increment of resistance.

The correction of the time and temperature drift of the comparison unit allows to increase the resolution of the device, and therefore, increases the conversion accuracy and makes it possible to use non-precision consumer comparison units.

Claims (3)

1. USSR author's certificate No. No. 373870, class H 03 K 13/20, 1970. 2. Authors certificate of the USSR 470919, cl. H 03 K 13/20, 1971. 3. USSR author's certificate According to the application 2632979, cl. H 03 K 13/20, 5 1978 (prototype).