SU409648A1 - Converter for converting parameters of complicated electric circuits into time intervals - Google Patents

Abstract

1. CONVERTER PARAMETERS OF COMPLEX ELECTRIC CIRCUITS IN TIME INTERVALS, containing a bipolar constant voltage source, a switch, a null organ, a control unit, characterized in that, in order to improve the accuracy of the conversion, it has an input of a post amplifier, which is inserted into an input amplifier, a control unit, characterized in that, in order to improve the accuracy of the conversion, it has an input of a post amplifier, a control unit, characterized in that, in order to improve the accuracy of the conversion, it has an input of a post amplifier, a control unit, characterized in that, in order to improve the conversion accuracy, it has an input of a post amplifier, a control unit, characterized in that, in order to improve the accuracy of the conversion, it has an input of a post amplifier; capacitive feedback connected

Description

The invention relates to electrical measuring and control techniques and can be used both for measuring the values of elements parallel to Ry or R Jx, and for element-by-element control of the latter. Converters of parameters of complex electrical circuits at time intervals are known, which contain a bipolar constant-voltage source. switch, null organ, control unit. Known converters are complex and not highly accurate conversions. The aim of the invention is to improve the accuracy of the conversion. The goal is achieved by connecting a DC amplifier input with capacitive feedback to a converter through a parallel-connected measuring resistor and measured capacitor to one output of the switch and through a model resistor to another output of the switch, whose inputs are connected to the outputs of bipolar a constant voltage source and a common bus, the output of the dc amplifier is connected to the null organ. FIG. 1 shows a converter circuit; in fig. 2 - timing charts of signals at the outputs of the switch and at the output of the DC amplifier. The Converter operates as follows. According to the Start signal and the corresponding command of the control unit 1, the switch 2 connects the input of the DC amplifier 3 through the parallel-connected measuring resistor 4 and the measured capacitor 5 to the negative output of the bipolar constant-voltage source 6, and through the reference resistor 7 to the positive output of a bipolar constant voltage source 6. At the output of a DC amplifier 3 with a capacitor 8 in the parallel negative feedback circuit, a positive voltage jump appears as a result of a fast The redistribution of the charge between the capacitor 5 and the capacitor 8. Assuming that the resistance value of the reference resistor 7 is less than the resistance value of the measured resistor 4, the total current flowing through the capacitor 8 from the applied positive and negative voltages will be the discharge current, and the voltage at the output of the dc amplifier 3 will decrease. When the voltage at the output of the DC amplifier 3 decreases to zero, the nullorgan 9 (time B in the time diagrams) will work, and the control unit 1, at a predetermined time TQ, during which the discharge of the capacitor 8 continues, gives the command to switch the switch 2, as a result of which the discharge of the capacitor 8 is stopped and the charge of the capacitor 8 begins to flow with the current flowing through the measuring resistor 4. The output voltage of the DC amplifier 3 begins to increase and when it reaches the second time l, the second time the null-organ 9 is triggered (time diagram), and at the command from the control unit, switch 2 connects the measured resistor 4 and the measured capacitor 5 in parallel to the common bus, and the reference resistor 7 connects to the negative output bipol source of constant voltage. Due to the rapid redistribution of the charge between the capacitor 5 and the capacitor 8, the output voltage of the DC amplifier 3 abruptly decreases and then linearly increases as a result of the charge of the capacitor 8 with current flowing through the reference resistor 7. When this voltage is a third time reaches zero, for the third time the zero-body 9 operates, and at the command of the control unit, switch 2 will disconnect the input of the DC amplifier 3 from the applied actions (time tg in the time diagrams). This is where the conversion process ends. The time interval between the first and second zero-organ triggers 9 C) and depends linearly on the resistance value of the measured resistor 4 (R) is defined by the following expression: "fe -" M set time interval; the magnitude of the resistance of the reference resistor 7. The time interval tc between the second third zero-organ trips 9 linearly depends on the QM-value of the bone of the measured capacitor 5 (C) and is determined by the following expression:

ic-RoC ,,

In the case of converting Jvani parameters in parallel connected resistor and

the inductance in the parallel negative feedback circuit of the dc amplifier 3 must be placed a resistor, and instead of the exemplary resistor 7 used the sample inductance.

Claims (2)

1. CONVERTER OF PARAMETERS OF COMPLEX ELECTRIC CIRCUITS IN! TIME INTERVALS, comprising a bipolar DC voltage source, a switch, a zero-organ, a control unit, characterized in that, in order to increase the conversion accuracy, the input of the introduced DC amplifier with capacitive feedback is connected through a parallel connected measured capacitor and resistor to one output of the switch and through a model resistor to another output of the switch, the inputs of which are connected to the outputs of a bipolar DC voltage source and a common bus, the output of the amplifier the current is connected to the zero-organ. 2. The converter according to claim 1, characterized in that in it the input of the introduced DC amplifier with resistive feedback is connected through parallel connected measured inductance and resistor to one input of the switch and through the model inductance to the other input of the switch. Figure 1