SU959264A1 - Complex resistance simulator - Google Patents

Description

(5) SIMULATOR OF COMPLEX RESISTANCES

Claims (2)

The invention relates to electrical measuring equipment and can be used to construct exemplary measures of inductance and capacitance used, for example, to test bridge and compensating alternating circuits; current. A complex impedance simulator is known, containing an operational amplifier and four model elements, the first terminals of the first three elements are interconnected and connected to the inverting inputs of the operational amplifier, the fourth model element is connected between the first input of the simulator AND the output of a one-amplifier, the non-inverting input of which is connected to a common bus . and is the second input of the simulator, and the second output of the first exemplary element is connected to the first input of the simulator. E) However, the known complex resistance simulator is not sufficiently LLL due to the influence of undesirable capacitive connections with respect to the housing and the simulator zero bus. The purpose of the invention is to improve the accuracy of the impedance simulator. To achieve this goal, the well-known impedance simulator containing an operational amplifier and, four exemplary elements, the first terminals of the first three elements are interconnected and connected to the inverting input of the operational amplifier, the fourth exemplary element is included between the first input of the simulator and the output of the operational amplifier, the non-inverting input of which is connected to the common bus and is the second input of the simulator, and the second in The water of the first model element is connected to the first input of the simulator; two voltage dividers are added, the inputs of which are interconnected and connected 39 to the output of the operational amplifier, and the outputs are connected to the second terminals of the second and third exemplary elements, voltage dividers are in the form of digital-analogue converters. The drawing shows the principal electrical circuit of the proposed simulator. The simulator contains an operational amplifier 1, four exemplary elements 2-5, a fourth exemplary element 5 is connected between the first input 6 of the simulator and the output of the operational amplifier 1, the non-inverting input of which is connected to a common bus and is the second input 7 of the simulator, two voltage dividers 8 and 9. simulator complex resistance works as follows. The input current 3 of the simulator flows through the element 5 and is determined by the difference of the input voltage of the device and the output voltage of the operational amplifier applied to it. The effect of the input voltage V is compensated by one of the known methods by means of an additional amplifier device and here is considered. Therefore, the input MMkijaTopa is determined by the equality: where j is the input current of the simulator 6; output voltage of op amp 1; the resistance of the fourth exemplary element 5 Then, based on the principle of operation of the operational amplifier, we can write: Sf Ya RCI XR. - respectively soo: g resistance elements 2, 3 and i. - n - voltage at the output of the divider 8; V-, V / p. - voltage on the output of divider 9; n, j is the division factor of the voltage of the divider 8; n is the division factor of the voltage divider 9. Equivalent resistance of the simulator is equal to the same time from (2) you can get the following: After substituting the expression, the decrease (3) is obtained: - (, -) by simulating the resistance of an inductive character 2e V (R7 where Lg 3 equivalent inductance of the simulator; t R / equivalent resistance of the simulator. Independent regulation of inductance values of 1dI resistance Rg is provided by adjusting the division factors n "and n dividers 8 and 9. voltage, respectively. Compared with the known The impedance impedance simulator provides increased accuracy by eliminating the need for storing capacitances and resistors and simplifying switching to set the required resistance values. The equivalent inductance and impedance loss of the simulator are controlled by adjusting the voltage divider transfer coefficients, which, if implemented, are Digital to analogue converters can be obtained fairly accurate. Claim 1. A simulator of complex C9 resistances containing an operational amplifier and four exemplary elements, the first terminals of the first three elements are interconnected and connected to the inverting input of the operational amplifier, the fourth exemplary element is connected between the first input of the simulator and the output of the operational amplifier, the non-inverting input of which is connected to the common bus and is the second input of the simulator, and the second output of the first model element is connected to the first input of the simulator, characterized in that In order to increase accuracy, two voltage dividers were added to the complex impedance simulator, the inputs of which are interconnected and connected to the output of the operational amplifier, and the outputs are connected to the second terminals of the second and third reference elements, respectively. 2. A simulator according to claim 1, characterized in that the voltage dividers are made in the form of digital-analog converters. Sources of information taken into account in the examination 1, Marché J. Operational amplifiers and their application. L., Energie, IS, s.Ill, fig. 6-103 (prototype)