SU1003103A1 - Multiplier - Google Patents

Description

The invention relates to electrical computing devices and can be used in analog computers.

A multiplying device containing differential amplifiers, operational amplifiers is known. However, this device is characterized by low precision of operation.

The closest to the proposed is a multiplying device containing multipliers, a scale converter, an adder 2.

The key to this device is poor accuracy due to incomplete compensation of static and dynamic errors.

The aim of the invention is to improve the accuracy of operation by compensating for the static error and its dynamic components.

The goal is achieved by multiplying the device containing the first and second multipliers. Or the first scaler, the input of which is connected to the output of the first multiplier, the output of the first scaler is connected to the input of the adder, the output of which is

output multiply the device, entered VI-2 additional multipliers I-1 additional scale converters and 2I scaling blocks, the output of the second multiplier through the first; and the additional scale converter connected to the second input of the adder, the output of each of the I-2 additional

10 multipliers are connected via an appropriate additional scaler to the corresponding input of the adder, the first input of the multiplier is connected via the corresponding scaling unit to the first input of the multiplying device, and the second input of each multiplier is connected to the second input through the appropriate scaling unit.

20 multiplying device.

The drawing shows a functional diagram of the proposed multiplying device.

jc The circuit contains the first and second multipliers 1 and 2, the first scale converter 3, the adder 4, the scaling blocks 5-1, 5-2, ...., 5-2i, additional multipliers 6-1, ...,

SN 6- (I-2), additional scale converters 7-1, 7-2, ... , 7- (i-l).

the first and second inputs 8 and 9 and the output 9 of the multiplying device.

The multiplying device operates as follows.

Voltage K is applied to the first input 8, and voltage X / i is applied to the second input 9. These voltages, multiplied by the corresponding coefficients in the scaling blocks | 5-1, ..., 5-2i, are fed to the inputs of the multipliers 1,2-6-1, ..., 6- (vi-2). The transmission coefficient of each multiplier is described by the expression. . where (X, X) is the error of the multiplier, which includes a finite number of members of the first and higher order K, which are significantly different from zero, constant constants. Taking into account the transfer coefficients of the scaling blocks 5-1, ..., 5-2I the output of the i -th multiplexer we get -KS-С „, U, K, CC1X ,, SICUD C2 where C,. . . , С - transfer coefficients of the corresponding scaling units 5-1, ..., 5-2i. The output voltages of all multipliers are linearly independent values, so you can find such coefficients p,. .., pj / ,, that the linear combination of output voltages with these coefficients is equal to q. i.e. Jp-NjlcO lyy (r) and I. Practically such an operation is performed in the device by large-scale transformations when signals pass through scale converters 3.7-1, ..., 7- (i-1 and their summation in adder 4.

The absence of error in the output signal means its full mutual compensation as a result of weight summation.

Claims (2)

Thus, the proposed multiplying device, as compared with the known device, makes it possible to eliminate the static error of multiplication and a significant part of the dynamic error, which means a higher accuracy of operation. The multiply device containing the first and second multipliers, the first scale converter, the input of which is connected to the output of the first multiplier, the output of the first scale converter connected to the input of the adder, the output of which is the output of the multiplying device, is different in that / in order to improve the accuracy of multiplication, c-2 additional multipliers, -1 additional scale converters and 2 and scaling blocks are introduced into it, with the output of the second multiplier through the first The additional scale converter is connected to the second input of the adder, the output of each of the I-2 additional multipliers is connected to the corresponding input of the multiplier, the second input of each multiplier is connected to the first input of the multiplier, the second input of each multiplier is connected to the first input of the multiplier. input each multiply-. l through the appropriate scaling unit connected to the second input of the multiplying device. Sources of information taken into account in the examination 1. Reference nonlinear circuits. Ed. D. Sheingold, Mir, 1977, p. 234-235, FIG. 3.2,10. 2. The author's certificate of the USSR № 796864, cl. G 06 G 7/16, 1979 (prototype).