State feedback with fractional integral control design based on the Bodes ideal transfer function

U. M. Al-Saggaf; I. M. Mehedi; R. Mansouri; M. Bettayeb

doi:10.1080/00207721.2015.1034299

State feedback with fractional integral control design based on the Bodes ideal transfer function

U. M. Al-Saggaf, I. M. Mehedi, R. Mansouri^*, M. Bettayeb

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

42 Citations (Scopus)

Abstract

State feedback technique through a gain matrix has been a well-known method for pole assignment of a linear system. The technique could encounter a difficulty in eliminating the steady-state errors in some states. Introducing an integral element can effectively eliminate these errors. State feedback with fractional integral control is proposed, in this work, for pole placement of a linear time invariant system. The proposed method yields simple gain formulae. The paper presents the derivation of the design formulae. The method is applied to stabilise an inherently unstable inverted pendulum-cart system. Simulation and experimental results show the effectiveness of the proposed method for set-point tracking, disturbance rejection and stabilising the inverted pendulum. Comparison with the results obtained from applying Achermanns formula is also presented.

Original language	English
Pages (from-to)	149-161
Number of pages	13
Journal	International Journal of Systems Science
Volume	47
Issue number	1
DOIs	https://doi.org/10.1080/00207721.2015.1034299
Publication status	Published - 2 Jan 2016
Externally published	Yes

Keywords

Bode's ideal transfer function
fractional order controller
robust control
state feedback control
state feedback with fractional integral control
state space representation

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10.1080/00207721.2015.1034299

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title = "State feedback with fractional integral control design based on the Bodes ideal transfer function",

abstract = "State feedback technique through a gain matrix has been a well-known method for pole assignment of a linear system. The technique could encounter a difficulty in eliminating the steady-state errors in some states. Introducing an integral element can effectively eliminate these errors. State feedback with fractional integral control is proposed, in this work, for pole placement of a linear time invariant system. The proposed method yields simple gain formulae. The paper presents the derivation of the design formulae. The method is applied to stabilise an inherently unstable inverted pendulum-cart system. Simulation and experimental results show the effectiveness of the proposed method for set-point tracking, disturbance rejection and stabilising the inverted pendulum. Comparison with the results obtained from applying Achermanns formula is also presented.",

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AU - Al-Saggaf, U. M.

AU - Mehedi, I. M.

AU - Mansouri, R.

AU - Bettayeb, M.

PY - 2016/1/2

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N2 - State feedback technique through a gain matrix has been a well-known method for pole assignment of a linear system. The technique could encounter a difficulty in eliminating the steady-state errors in some states. Introducing an integral element can effectively eliminate these errors. State feedback with fractional integral control is proposed, in this work, for pole placement of a linear time invariant system. The proposed method yields simple gain formulae. The paper presents the derivation of the design formulae. The method is applied to stabilise an inherently unstable inverted pendulum-cart system. Simulation and experimental results show the effectiveness of the proposed method for set-point tracking, disturbance rejection and stabilising the inverted pendulum. Comparison with the results obtained from applying Achermanns formula is also presented.

AB - State feedback technique through a gain matrix has been a well-known method for pole assignment of a linear system. The technique could encounter a difficulty in eliminating the steady-state errors in some states. Introducing an integral element can effectively eliminate these errors. State feedback with fractional integral control is proposed, in this work, for pole placement of a linear time invariant system. The proposed method yields simple gain formulae. The paper presents the derivation of the design formulae. The method is applied to stabilise an inherently unstable inverted pendulum-cart system. Simulation and experimental results show the effectiveness of the proposed method for set-point tracking, disturbance rejection and stabilising the inverted pendulum. Comparison with the results obtained from applying Achermanns formula is also presented.

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KW - fractional order controller

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KW - state space representation

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State feedback with fractional integral control design based on the Bodes ideal transfer function

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Keywords

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