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Poles-zeros placement and decoupling in dicrete LQG systems

Poles-zeros placement and decoupling in dicrete LQG systems

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© The Institution of Electrical Engineers
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A design algorithm is introduced to synthesise a discrete time LQG optimal controller subject to design constraints requiring (i) complete and arbitrary stable poles placement, (ii) some zeros assignment, and (iii) input-output decoupling. The zeros placement is partially used to deal with the deterministic reference tracking and disturbances rejection problems. In the paper, the Wiener-Hopf technique is employed and two weighting matrices are shaped by the inverse optimal control method, so that the controller is optimal with respect to the chosen weighting matrices and achieves the above three goals simultaneously.

Inspec keywords: discrete time systems; poles and zeros; optimal control; control system synthesis

Other keywords: zeros assignment; control system systems; design algorithm; weighting matrices; disturbances rejection; Wiener-Hopf technique; discrete time LQG optimal controller; poles placement; decoupling; input-output decoupling; deterministic reference tracking

Subjects: Control system analysis and synthesis methods; Optimal control; Discrete control systems

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