SU473195A1 - Functional converter - Google Patents

Description

(54) FUNCTIONAL CONVERTER

one

The invention relates to the field of computing and can be used in analog and hybrid computing systems.

A functional converter is known that contains memory blocks, the main inputs of which are connected to converter inputs, and a pulse generator, the output of which is connected to additional inputs of the first memory block through a step voltage generator and an additional input of the converter .

The disadvantage of such a converter is the complexity of its structural scheme.

The proposed functional converter is characterized in that, for the sake of simplicity, it contains a multivalued potential element, an additional pulse generator and a step voltage generator, as well as a time interval selection unit and a coincidence matrix, the first input and output layers of which are connected respectively to the outputs of the nerve memory block. and the first input of a multivalued potential element, the second input of which is connected to the input of the argument of the converter, its first output is connected to the output of the converter the second is input to the second input matrix of the match matrix, the third input

the tires of which are connected to the outputs of the second unit via a slot allocation unit. The outputs of the successively connected additional pulse generator and the step voltage generator are connected to the additional inputs of the second memory block and the multi-valued potential element. An input of an additional generator of pulses is connected to the output of a step-by-step generator.

The structural diagram of the functional converter is shown in the drawing.

The converter contains two memory blocks 1 and 2, implemented on universal multi-valued elements with feedback 3i-3p. Memory blocks 1 and 2 are designed to store the function value and the argument values in the nodes of annotation. In addition, the converter includes a pulse generator 4, a voltage generator 5, an additional pulse generator 6, an additional voltage generator 7, a block for allocating a time interval 8, a joint matrix 9 and an additional multi-valued potential element 10.

The functional instructor operates as follows.

The values of the specified function and approximation points are recorded in two memory blocks.

1 and 2. The accuracy of storing these values is determined by the number of states (t) of the elements 3i-3n. The values of the arguments of the approximation points Xi are supplied in the form of a phase-pulse code to the logical block of the allocation of time intervals 8, which performs the following transformations. At the first output of this block, an impulse is formed with a duration equal to the first approximation interval, at the second - the second and so on. The frequency of the additional pulse generator 6 is chosen equal to the frequency of the step voltage generator 5. As a result, the pulse width of the phase-pulse code in the elements of the second memory block 2 is t times larger, and the minimum value (Xi-Xi-) corresponds to exactly one step of the step-like generator 5. The converter input signal is converted in the additional potential element 10 into a phase-pulse code, which is fed further to the matrix 9. If the input signal is within J, then the match will occur only in element of matrix 9, to the other input of which impulse is received, proportional to (X -X {-i) The pulses arriving at the third input of this element, which correspond to the value of the function at this approximation interval, pass to the output of the matrix 9 and further in the multi-valued potential element 10 are transformed into the corresponding level; As a result, between the output and the input we obtain the desired functional dependence.

Subject invention

A functional converter, containing memory blocks, the main inputs of which are connected to the converter inputs, and a pulse generator, the output of which is connected to additional inputs of the first memory block through a step voltage generator, to the additional memory input, characterized in that, for the sake of simplicity, it contains a multi-valued potential element, an additional pulse generator and a step voltage generator, as well as an allocation unit temporarily о interval and coincidence matrix, the first input and output buses of which are connected respectively to the outputs of the first memory block and the first input of a multivalued potential element, the second input of which is connected to the input argument of the converter, its first output is connected to the output of the converter, and the second output to the second input buses third matrixes

the input buses of which are connected to the outputs of the second memory unit through a time slot allocation unit; outputs of series-connected additional pulse generator and step generator

the voltages are connected to the additional inputs of the second memory block and the multi-valued potential element; the input of the additional pulse generator is connected to the output of the step voltage generator. l l

Al.