Title :
Recursive Digital Filters With Tunable Lag and Lead Characteristics for Proportional-Differential Control
Author_Institution :
Sch. of Eng., Univ. of South Australia, Adelaide, SA, Australia
Abstract :
Regression analysis using orthogonal polynomials in the time domain is used to derive a digital filter with an infinite impulse response that satisfies maximally flat design constraints near dc. The low-frequency phase, and high-frequency gain, may be adjusted for lead or lag compensation of plant dynamics. Simulated design examples are used to show how the compensating filter may be intuitively tuned for the desired closed-loop response. It is shown that the second-order instantiation of the compensating filter reduces to a proportional-differential plus filter controller, with improved noise attenuation; closed-form expressions for the filter coefficients, as a function of two design parameters, are provided.
Keywords :
IIR filters; PD control; closed loop systems; polynomials; recursive filters; regression analysis; time-domain analysis; closed-loop response; filter coefficients; high-frequency gain; infinite impulse response; lag compensation; lead characteristics; low-frequency phase; noise attenuation; orthogonal polynomials; plant dynamics; proportional-differential control; proportional-differential plus filter controller; recursive digital filters; regression analysis; second-order instantiation; tunable lag; Control design; Digital control; Finite impulse response filters; IIR filters; PD control; Control design; Savitzky--Golay (S-G) filtering.; Savitzky???Golay (S-G) filtering; digital control; digital filter design; infinite impulse response (IIR) filters;
Journal_Title :
Control Systems Technology, IEEE Transactions on
DOI :
10.1109/TCST.2015.2399436
