Analysis of algorithms for velocity estimation from discrete position versus time data

Author

Brown, Ronald H. ; Schneider, Susan C. ; Mulligan, Michael G.

Author_Institution

Dept. of Electr. & Comput. Eng., Marquette Univ., Milwaukee, WI, USA

Volume

39

Issue

1

fYear

1992

fDate

2/1/1992 12:00:00 AM

Firstpage

11

Lastpage

19

Abstract

Algorithms for constructing velocity approximations from discrete position versus time data are investigated. The study is limited to algorithms suitable to provide velocity information in discrete-time feedback control systems such as microprocessor-based systems with a discrete position encoder. Velocity estimators based on lines per period, reciprocal-time, Taylor series expansion, backward difference expansions, and least-square curve fits are presented. Based on computer simulations, comparisons of relative accuracies of the different algorithms are made. The least-squares velocity estimators filtered the effect of imperfect measurements best, whereas the Taylor series expansions and backward difference equation estimators respond better to velocity transients

Keywords

digital simulation; discrete time systems; feedback; least squares approximations; microcomputer applications; parameter estimation; position control; series (mathematics); Taylor series expansion; algorithms; backward difference expansions; computer simulations; discrete position data; discrete position encoder; discrete-time feedback control; least-square curve fits; microprocessor-based systems; motion control systems; time data; velocity estimation; velocity transients; Algorithm design and analysis; Computer errors; Delay estimation; Least squares approximation; Motion control; Optical filters; Sampling methods; Taylor series; Time measurement; Velocity measurement;

fLanguage

English

Journal_Title

Industrial Electronics, IEEE Transactions on

Publisher

ieee

ISSN

0278-0046

Type

jour

DOI

10.1109/41.121906

Filename

121906