SU679991A1 - Y=shx,y=chx functions analyzer - Google Patents

Description

The invention relates to the field of computer technology, in particular, to devices for reproducing and calculating functional dependencies by the method of modeling approximating functions, and can be used in automation, telemechanics, in control systems and in control of technical processes. A device for reproducing piecewise linear functions {1J, containing a controllable divider, counters, switches, AND elements, a descrambler, and OR elements is known. A disadvantage of this device in the case of reproducing functions is a significant amount of storage device at the same time reproducing them. The closest in technical drying to this invention is a device 2, which contains a pulse generator connected to the first input of a key, the second input of which is connected to the permissive output of the device, and the output to the input of the argument divider and the divider of the approximation section, the output of which is through a counter the number of approximation sections is connected to the first inputs of the AND elements of the first group, the outputs of which are connected to the inputs of the first OR element, the decoder and the memory block. The disadvantage of such a device is the limited Htc accuracy and non-optimal hardware costs, as well as a significant amount of memory and limited functionality, which do not allow to reproduce the functions of H-sliXHY-ctix simultaneously with high accuracy. The aim of the invention is to improve the accuracy and simultaneous reproduction of the I XiCttX functions. This is achieved by the fact that a device containing a pulse generator connected with an output to a first key input, the second input of which is connected to a device permitting input and an output from

At the end of the argument divider and doltal of the approximation section, the output of which through the counter of the number of approximation sections is connected to the first passes of the AND elements of the first group, the elevations of which are connected to the inputs of the first OR element, additionally contains counters, multipliers, adders, triggers, second

the group of elements is AND, the second element is OR, and the argument divider is connected to the third input of the key through the argument counter, the output of which is connected via the first counter to the second counter and the second passes of the AND elements of the first group,. the output of the second counter is connected to the first inputs of elements AND of the second group, the second passages of which are connected to the output of the counter of the number of approximation segments ,. and the outputs to the inputs of the second element OR, the outputs of the first and second elements OR are connected, respectively, through the first 1H second multipliers to the first passes of the adder and adder-reader and the second inputs of the adder and adder-subtractor, whose outputs through the first and second triggers respectively connected To the inputs of the first and second result counters. .

The drawing shows a block diagram of the proposed device.

The device contains a generator of 1 pulses, a key 2, allowing the return of 3, a divider of 4 arguments, a counter of 5 arguments, a divider 6 of the approximation section, a counter 7 of the number of approximation sections, the first counter 8, the second counter 9, the first and second groups of elements 10 and 11, the first and the first elements OR 12 and 13, the first and second multipliers 14 and 15, the adder 16, the adder-subtractor 17, the first and second triggers 18 and 19, the first and second counters of the result 2O and 21, the key 2 also contains the ban 22.

The device works as follows.

When a signal is sent to Tact 3, the key 2 is unlocked and the pulses from the generator 1 output go to the input of dividers 4,6 and counter 8. Through the 4 argument argument the pulse number equivalent of the variable X enters the argument counter 5, which is previously in the form of a code supplemented up to the total number of counter states, a digital analogue of the argument value is entered — 10 -X, where 1 is the factor of discreteness of the representation of the argument

one integer. Choria dolitol 6, orrrdel, the general length of the region of approximation, the division ratio of which is

 dx- K: r1o - K. Ivi 2, - (1 where Kj is the division factor of the divisor 4 argument determining the discreteness of representations. The pulses go to the counter 7 of the number of approximation segments, the total number of states of which corresponds to the size of the first and second groups Elements 1O and C. The first and second counters 8 and 9, associated with the rti-bit groups of elements I, have (t-1) bitness.When going to the next section of the approximation, control and ample of the counter from 7 sections of the approximation control are the work of the first and second groups of elm: ntov and 10 and 11 so m a way that with each new portion approximating twice increase the number of pulses received through a group of AND gates 10 and 11 by elements 12 and OR 13,

Using the connection of the counter 7, the approximation sections, the first and second counters 8 and 9 of the first and second element groups SE and 11 allows, at the output of the first multiplier 14, to obtain a relationship like Y C-I or taking into account the equality D 2, h is the number of approximation sections .

Before starting work, multipliers were entered into the first and second multipliers 14 and 15,

 10h, -IP ". k jt- 2

H & 6input of adder 16 will be

) -Ki-e-) e-e 2sfiK By splitting the resulting expression in two by turning on the output of the adder 16 of the trigger 18, the result counter 20 will be reproduced and the value 3li will be calculated.) The output of the subtractor 17 will be

() - (- e-) e -ve - 2cbx-2.

Dividing the resulting expression into two by switching on the output of the adder of subtractor 17 of trigger 19 and introducing a digital analogue of the unit into the second counter 21 of the result before launching the circuit, the counter CflX will be reproduced in the counter 21 of the result. transcendental functions -slx that allows you to use it as a