SU697989A1 - Number-pulse function converter - Google Patents

Description

The invention relates to automation and computing, in particular to devices for the functional conversion of a number of pulse signals. Piecewise linear approximation digital function converters are known, containing frequency dividers, counters of the number of approximation segments, decoders, memory blocks, logic gates AND and OR 1 and 2. Known converters carry out piecewise linear approximations with uniformly divided by axis of argument. With this method of specifying approximations, the length of linear segments is determined on the part of the function with the greatest curvature and the number of sections increases dramatically with an increase in the approximation accuracy, and consequently, the volume of the converter's electronic device increases. The closest in technical essence to the present invention is a converter containing a frequency divider, the input of which is the converter input connected to the first outputs with the first inputs of the AND elements of the first group, and the second with the first inputs of the elements AND the second group, the second inputs of which are connected to the output the memory block and the second inputs of the elements AND of the first one, the outputs of which are connected to the inputs of the OR element, the output of which is the output of the converter 3. The pointer of the converter carries the piece a linear approximation of the variable-length sections approximating atsii.Vozmozhnost varying lengths approximating plots within wide limits allows to increase the conversion precision of a limited number of sites approximation. However, with a high approximation accuracy, the number of sections increases dramatically even with the optimal length of the approximating segments. An increase in the number of approximation plots requires an increase in the decfrator's bit size, and afterwards a sharp increase in the volume of electronic equipment.

. (Either of the invention - improving the accuracy of functional transformation.

Order 1P (and the pel is achieved by the fact that the digital functional converter contains a frequency divider whose input is the input of the converter connected by the first outputs c) with the first inputs of the AND elements of the first group and the second with the first inputs of the AND elements of the second group whose second inputs are connected to the output of the memory block and the second inputs of the AND elements of the first group, the outputs of which are connected to the inputs of the OR element, the output of which is the output of the converter, further contains a shift register, controlling second input coupled to a common output of the second group of AND gates, and outputs bits - to the inputs of the memory block.

The drawing shows a structural diagram of a python functional transform.

The function converter contains frequency divider 1; shift register 2, two groups of logical elehrgg And 3, 4, the element OR 5, the memory block 6.

The Converter operates as follows.

The input pulse sequence is passed to the counting input of the divider 1, which is a serial binary counter. With the help of a group of elements And 3, controlled by signals from the memory block 6 and the element OR 5, at each section of the approximation, the corresponding division factors of the frequency of the 11th pulses are set.

At the same time, the divider 1 serves to set the length of the approximation segment. When accumulating, the dividers 1 ptsla, equal to the first angle of approximation, at the output of the group of elements 4 And 4}, a signal that arrives at the input of the shift register 2, is output. As a result, the signal of the logical unit shifts from the first bit to the second. The latter, through the memory block b, opens to the open position a new combination of elements AND of group 3, which determine the coefficient.

plot of the approximation, as well as a new combination of elements AND group 4. defining the length of the second section of the approximation. Further operation of the device is similar.

Thus, the functional transducer reproduces the function in the form of an agglomeration broken-line with a variable length of apryuximadia sections, and the number of approximation sections is equal to the number of bits of the shift register, i.e. The volume of the electronic equipment of the shift register is a linear function of the number of approximation segments, while in known devices this function has a power-law character.

Claims (3)

1. Author's certificate of the USSR N 451989, cl. G 06 F 1/02, 1973. 2. USSR author's certificate number 532098, cl. G 06 F 15/34, 1976. 3. Author's certificate; 1st USSR No. 577532. class. G 06 F 15/34, 1976 (prototype).