SU1446632A1 - Modular element of network model - Google Patents

Abstract

The invention relates to analog computing and can be used to model spatial objects obtained by discretizing the space and time of boundary value problems of field theory. The purpose of the invention is to improve the accuracy of the solution. The goal is achieved by introducing a key, a resistor, and a scaling amplifier into the node element. The nodal element allows to increase the accuracy by setting a current to the nodal point, which compensates for the leakage current of the keys of the coding resistors. To reduce the effect of the voltage-to-current converter on the potential of the nodal point, the switch disconnects the nodal point from the output of the voltage-to-current converter. 1 PC. with $

Description

The invention relates to analog computing and can be used to model spatial objects (approximating grids obtained by discretizing the space and time of boundary value problems of the field theory.

The purpose of the invention is to improve the accuracy of the solution.

The drawing shows the node element of the grid model.

The nodal element of the grid model includes the first to fifth codeodicable. resistors 1-5, matching (code-controlled) resistor 6, nodal point 7, voltage follower 8, resistor 9, switch 10, voltage converter 1 1 voltage to current, scale-up amplifier 12, code converter 13 to voltage, register 14.

The nodal element is included in the grid model. Before starting work, in the node elements into which, according to the condition of the problem being solved, currents will not be injected and voltages will be compensated for leakage currents. For this value, the resistances of the first, second, third, fourth, fifth, code-resistive resistors and the terminating resistor 1-5 and 6 are set to | infinity (zero conductivity. Zero information is written to register 14. 1Switch 10 is opened by disconnecting converter 1 from the output of the converter 13 of the code to the voltage to the node 1, a zero potential is set and the potential value at the output of the voltage follower 8 is measured. IF the potential at the output of the repeater, voltage 8 zero then The leakage current is not compensated. If the potential at the output of the voltage follower 8 is not equal to zero, then a sign code opposite the sign of the potential at the output of the voltage follower 8 is written to the digit of the register 14. A register from the output 14 is written. I4 is transformed into voltage in code converter 13 into voltage, and from its output voltage is fed to the input of a scalable amplifier 12, from the output of which the amplified voltage through a resistor 9 enters the node point 7. Scaling amplifier 12 amplifies the voltage The voltage at the output of the code converter 13 is ten times that allows you to apply a high resistor 9. The potential at the nodal point 7 is measured at the output of the voltage follower 8. If the potential at node 7 does not f is zero, then the contents of register 14 are incremented by one and the node element works as described. If the potential at node 7 is zero, the leakage current compensation is stopped and a code corresponding to the value of the compensating voltage is fixed in register 14. Then, according to the condition of the problem, the required values of the first, second, third, fourth, and fifth code-controlling resistors 1, 2, 3, 4, and 5 are set, after which the node with compensated leakage current is ready for operation as part of the grid model. In the node elements, in which, by the condition of the problem being solved, current and voltage are applied, the JO key is closed, and the leakage current is automatically compensated by entering into the register 14 of the code the required voltage and current. The high impedance circuit of the series-connected scaling amplifier 12 and the resistor 9 has almost no effect on the potential value at the nodal point 7, since the low impedance matching (code-controlled) resistor 6 bypasses this circuit.

Claims (1)

Invention Formula The node element of the grid model, which contains five code-controlled resistors, the first terminals of which and the first terminal of the matching resistor are connected to the input of the voltage follower, the output of which is the output of the node element, the register output is connected to the second terminal of the matching resistor and from the entrance; voltage to current converter; the input of the register is the input of the setting of the boundary conditions of the node element, the control inputs of the first, second, third, fourth, fifth coding coefficients of the resistors and the terminating resistor are a group of information inputs of the node element, characterized by that, in order to increase the accuracy of the solution, a key that is scaled is entered into it; an amplifier and a resistor, the first terminal of which is connected to the input of the voltage repeater, the output of the converter code to the voltage through a scaling amplifier is connected to the second output of the resistor, the output of the voltage to current converter is connected to the information input of the switch, the output of which is connected to the input of the repeater The control key input is an additional information input for the node element group, the second terminals of the coding control resistors are the input group of the node element. //