UA21929U - Model of corrected high-pass filter - Google Patents

Abstract

The model of high-pass corrected filter concern radio devises for signal filtering and may be used in processes of dynamic correction. The model of corrected filter having operated fractional rational transfer function includes n units (accordingly to filter order n) of an operational transformation connected in series. The operation of the model may be represents as a filter response with fractional rational transfer function - operator fractional rational transfer function , s- Laplace operator, n- filter order, f- the low cutoff frequency An operational transformation unit includes a differential amplifier, an adder, a delay element and a comparator of an input signal with delay element output signal. The differential amplifier input serves as input of the operational transformation unit. A negative input of the differential amplifier is connected with the adder output. The comparatoroutput is the output of the operational transformation unit. The input signal is delivered to summing input; the negative input is connected with the delay element output. The proposed model allows synthesizing a filter with the given cutoff frequency and correcting parameters. Such a construction extends functionality.

Description

Description of the invention

The model refers to the synthesis of radio technical signal filtering devices and can be used for 2 modeling of dynamic processes.

A known filter (1) based on discrete signal transformation. Its disadvantage is the complexity of implementation.

Pat. was selected as a prototype. UMUO03038999, IRS NOZOZI2O POMEAVIE RISTEK, 2003-05-08), containing an amplifier, a comparison and summation device. Its disadvantage is limited functionality.

The basis of the useful model is the task of expanding the functional capabilities of the model with an operator fractional-rational transfer function

THESE

UM(v) (et) 5th where MU(z) is the operator fractional-rational transfer function, 5 is the Laplace operator, n is the order of 75 of the filter, 7 is the lower limit frequency.

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 using n serially connected operational modules, which include a differential amplifier, an adder of the differential amplifier output with a delay signal and a device for comparing the output signal of the delay element with the input one.

Figure 1 shows a diagram explaining the essence of the proposed invention. It contains serially connected operational transformation modules 1, the number of which corresponds to the order of the filter n. The operational transformation module 1 consists of a differential amplifier 2, an adder C, a delay element 4 and a comparison device 5.

The input signal x is applied to the input of the differential amplifier 2 and the comparison device 5. The output signal of the differential amplifier 2 is applied to the input of the adder 3, the second input of which is connected to the output of the element

Delays 4. The output of the adder C is connected to the negative input of the differential amplifier 2. The input of the operational transformation module 1 is the summing input of the differential amplifier 2. The output of the module C of the operational transformation 1 is the output of the comparison device 5, to the summing input of which the input signal x is applied, and the negative input is connected to the output of the delay element.

The process performed by the filter is as follows. The input signal x is subjected to n-fold Ge»! transformation in accordance with the order of the filter n using n serially connected modules of operational transformation 1. Increasing the order of the filter n increases the steepness of its lower frequency limit, changing the coefficient of gain of the differential amplifier allows correcting the position of this limit. Ge")

The proposed model makes it possible to synthesize a filter for a given value of the lower limit of the filter's frequency range and carry out its correction, which expands the functionality. --

Sources of information: Ha 1. Ostapenko A.G. Analysis and synthesis of linear radioelectron circuits. Analog and digital filter!.

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

Claims (1)

Formula of the invention - c Model of a corrected high-pass filter with an operator fractional-rational transmission ;" function Pi mav) -( at) of the 8th o where UM(z) is the operator fractional-rational transfer function, 5 is the Laplace operator, n is the order of the filter, y is the lower limit frequency containing the amplifier, adder and delay element , which is distinguished by the fact that serially connected operational transformation modules are introduced, the number of which corresponds to the order of the filter n, and the operational transformation module consists of a serially connected differential GI 20 amplifier, an adder, a delay element, the output of which is connected to the second input of the adder, and a device comparison of the input signal with the output of the delay element, and the input of the operational transformation module c is the input of a differential amplifier, the negative input of which is connected to the output of the summing adder, and the output of the operational transformation module is the output of the comparison device, the input signal is applied to the summing input, and the negative input is connected to the output of the delay element. p. 60 b5