FREQUENCY DOMAIN COMPENSATION OF A DYNGEN TURBOFAN ENGINE MODEL.

R. M. Schafer; R. R. Gejji; P. W. Hoppner; W. E. Longenbaker; M. K. Sain

FREQUENCY DOMAIN COMPENSATION OF A DYNGEN TURBOFAN ENGINE MODEL.

R. M. Schafer^*, R. R. Gejji, P. W. Hoppner, W. E. Longenbaker, M. K. Sain

^*Corresponding author for this work

King Fahd University of Petroleum & Minerals

Research output: Contribution to conference › Paper › peer-review

Abstract

Following H. H. Rosenbrock's ideas regarding the advantages of dominance in linear multivariable control systems, a new graphical technique is used for the design of compensators that achieve dominance. The technique is illustrated with an application to the problem of designing compensators for a linear turbofan-engine model. The resulting design is put into perspective by examining it in the light of two other multivariable frequency-domain methods. One, MacFarlane's method of characteristic loci, is used to realize a final design for stability and low interaction. The other is a direct technique based upon the algebraic expansion of the determinant of the return difference in terms of its elements. Results from simulations carried out on the NASA DYNGEN software are included.

Original language	English
Pages	1013-1018
Number of pages	6
State	Published - 1977

ASJC Scopus subject areas

General Engineering

Cite this

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title = "FREQUENCY DOMAIN COMPENSATION OF A DYNGEN TURBOFAN ENGINE MODEL.",

abstract = "Following H. H. Rosenbrock's ideas regarding the advantages of dominance in linear multivariable control systems, a new graphical technique is used for the design of compensators that achieve dominance. The technique is illustrated with an application to the problem of designing compensators for a linear turbofan-engine model. The resulting design is put into perspective by examining it in the light of two other multivariable frequency-domain methods. One, MacFarlane's method of characteristic loci, is used to realize a final design for stability and low interaction. The other is a direct technique based upon the algebraic expansion of the determinant of the return difference in terms of its elements. Results from simulations carried out on the NASA DYNGEN software are included.",

author = "Schafer, {R. M.} and Gejji, {R. R.} and Hoppner, {P. W.} and Longenbaker, {W. E.} and Sain, {M. K.}",

year = "1977",

language = "English",

pages = "1013--1018",

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TY - CONF

T1 - FREQUENCY DOMAIN COMPENSATION OF A DYNGEN TURBOFAN ENGINE MODEL.

AU - Schafer, R. M.

AU - Gejji, R. R.

AU - Hoppner, P. W.

AU - Longenbaker, W. E.

AU - Sain, M. K.

PY - 1977

Y1 - 1977

N2 - Following H. H. Rosenbrock's ideas regarding the advantages of dominance in linear multivariable control systems, a new graphical technique is used for the design of compensators that achieve dominance. The technique is illustrated with an application to the problem of designing compensators for a linear turbofan-engine model. The resulting design is put into perspective by examining it in the light of two other multivariable frequency-domain methods. One, MacFarlane's method of characteristic loci, is used to realize a final design for stability and low interaction. The other is a direct technique based upon the algebraic expansion of the determinant of the return difference in terms of its elements. Results from simulations carried out on the NASA DYNGEN software are included.

AB - Following H. H. Rosenbrock's ideas regarding the advantages of dominance in linear multivariable control systems, a new graphical technique is used for the design of compensators that achieve dominance. The technique is illustrated with an application to the problem of designing compensators for a linear turbofan-engine model. The resulting design is put into perspective by examining it in the light of two other multivariable frequency-domain methods. One, MacFarlane's method of characteristic loci, is used to realize a final design for stability and low interaction. The other is a direct technique based upon the algebraic expansion of the determinant of the return difference in terms of its elements. Results from simulations carried out on the NASA DYNGEN software are included.

UR - http://www.scopus.com/inward/record.url?scp=0017597543&partnerID=8YFLogxK

M3 - Paper

AN - SCOPUS:0017597543

SP - 1013

EP - 1018

ER -

FREQUENCY DOMAIN COMPENSATION OF A DYNGEN TURBOFAN ENGINE MODEL.

Abstract

ASJC Scopus subject areas

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