In a multivariable servomechanism design, it is required that the output vector tracks a certain reference vector while satisfying some desired transient specifications, for this purpose a 2DOF control law consisting of state feedback gain and feedforward scaling gain is proposed. The control law is designed using block pole placement technique by assigning a set of desired Block poles in different canonical forms. The resulting control is simulated for linearized model of the HAVE DASH II BTT missile; numerical results are analyzed and compared in terms of transient response, gain magnitude, performance robustness, stability robustness and tracking. The suitable structure for this case study is then selected.
%0 Journal Article
%1 noauthororeditor
%A Belkacem", "BEKHITI
%A Abdelhakim", "DAHIMENE
%A Bachir", "NAIL
%A Kamel", "HARICHE
%D 2016
%J International Journal of Information Technology, Modeling and Computing (IJITMC)
%K BTT Block Controller DASH Feedback Feedforward Form HAVE II Left MIMO Matrix Placement Pole Poles Right State Technique and/or gain missile polynomials scaling
%N 2
%P 18
%R 10.5121/ijitmc.2016.4202
%T 2-DOF BLOCK POLE PLACEMENT CONTROL APPLICATION TO:HAVE-DASH-IIBTT MISSILE
%U http://aircconline.com/ijitmc/V4N2/4216ijitmc02.pdf
%V 4
%X In a multivariable servomechanism design, it is required that the output vector tracks a certain reference vector while satisfying some desired transient specifications, for this purpose a 2DOF control law consisting of state feedback gain and feedforward scaling gain is proposed. The control law is designed using block pole placement technique by assigning a set of desired Block poles in different canonical forms. The resulting control is simulated for linearized model of the HAVE DASH II BTT missile; numerical results are analyzed and compared in terms of transient response, gain magnitude, performance robustness, stability robustness and tracking. The suitable structure for this case study is then selected.
@article{noauthororeditor,
abstract = {In a multivariable servomechanism design, it is required that the output vector tracks a certain reference vector while satisfying some desired transient specifications, for this purpose a 2DOF control law consisting of state feedback gain and feedforward scaling gain is proposed. The control law is designed using block pole placement technique by assigning a set of desired Block poles in different canonical forms. The resulting control is simulated for linearized model of the HAVE DASH II BTT missile; numerical results are analyzed and compared in terms of transient response, gain magnitude, performance robustness, stability robustness and tracking. The suitable structure for this case study is then selected. },
added-at = {2017-12-15T12:17:57.000+0100},
author = {Belkacem", "BEKHITI and Abdelhakim", "DAHIMENE and Bachir", "NAIL and Kamel", "HARICHE},
biburl = {https://www.bibsonomy.org/bibtex/2f395688794676801a26ed463e0e79b17/ijitmc},
doi = {10.5121/ijitmc.2016.4202},
interhash = {a79e84e220fb84dd1a92c5fcee707505},
intrahash = {f395688794676801a26ed463e0e79b17},
journal = {International Journal of Information Technology, Modeling and Computing (IJITMC) },
keywords = {BTT Block Controller DASH Feedback Feedforward Form HAVE II Left MIMO Matrix Placement Pole Poles Right State Technique and/or gain missile polynomials scaling},
month = may,
number = 2,
pages = 18,
timestamp = {2017-12-15T12:17:57.000+0100},
title = {2-DOF BLOCK POLE PLACEMENT CONTROL APPLICATION TO:HAVE-DASH-IIBTT MISSILE},
url = {http://aircconline.com/ijitmc/V4N2/4216ijitmc02.pdf},
volume = 4,
year = 2016
}