UA19669U - Model for synthesizing a compensating filter - Google Patents

Abstract

It is proposed model for synthesizing a compensating filter with a fractionally rational transfer function: , where W(s) is the normalized fractionally rational transfer function, s is Laplace operator, n is the order of the filter, ai is the coefficient of the transfer function. The model of the filter contains functional converters connected in series, the number of which is equal to the order of the filter. Each functional converter contains a comparator, an addfer, and a time delay element.

Description

Description of the invention

The corrector synthesis model refers to the synthesis of radio engineering signal correction devices and can be used to model dynamic processes.

The well-known synthesis model of the corrector |1)Y) is based on discrete signal transformation. Its disadvantage is the complexity of its implementation.

As a prototype, patent UUO03038999, IRS NOZ.OZ/20 |Tipearie Riyeg, 2003-05-08) was chosen, which contains a comparator, an adder and a delay element. Its disadvantage is limited functionality.

The basis of the model is the task of expanding the functional capabilities of the normalized operator fractional-rational transfer function shkki anchnyi , . where UM(z) is the normalized operator fractional-rational transfer function, z is the Laplace operator, n is the order of the corrector, and! - coefficients of the transfer function operator.

The essence of the proposed model is expressed by a set of the following significant features: the input signal is subjected to n-fold transformation with the help of converters, which include a comparator, discretizer, adder connected in series, the second input of which is connected to the output of the delay element, which is the output of the converter, covered by feedback using sliders with transfer coefficients equal to the coefficients of the transfer function operator. The output signal of the corrector is the output of the last converter.

In Fig. there is a diagram explaining the essence of the proposed model. It consists of a sequence of converters, two of which correspond to the order of the corrector n. The converter contains a comparator 2, a discretizer Z, an adder 4 and a delay element 5. The inputs of the sliders 1, whose transfer coefficient is equal to the coefficients of the operator - transfer function, are connected to the output signal of the corrector Y, and their outputs are applied to the subtractive inputs of the comparators, forming a negative feedback.

The process carried out by the model is as follows. The input signal x is subjected to an n-fold Fu z transformation according to the order of the corrector n using n series-connected converters. The output of the last n-th converter is the output of the corrector U. (Se)

The proposed model allows for the synthesis of a corrector of a given order with the help of a single procedure, which simplifies the implementation of the model and expands the functionality, and the introduction of feedback on the output increases the stability of operation. (22) from Bibliographic list "- 1. Ostapenko A.H. Analysis and synthesis of linear radioelectron circuits. Analog and digital filter. -

M.: Radio and communication, 1985. - p. 250, fig. 7.29, p.

Claims (1)

The formula of the invention h - s Model of the synthesis of a corrector with a normalized operator fractional-rational transfer function and ov Z-th - where is a normalized operator fractional-rational transfer function, Y - the Laplace operator, Y. - the order of the corrector, SHI - coefficients of the transfer function operator, which contains a comparator, adder and F delay element, which is characterized by the fact that the input signal is subjected to n-fold transformation with the help of (2) converters, which include a serially connected comparator, sampler, adder, the second input of which is connected by 50 to the output of the delay element, which is the output of the converter, covered by feedback using sliders with transfer coefficients equal to the coefficients of the transfer function operator, Me, and the output signal of the corrector is the output of the last converter. p. 60 b5