Structural and predictive aspects of proportional-integral-plus (PIP) control

C.j. Taylor; P.C. Young; A. Chotai; Roger Dixon

doi:10.1049/cp:19960753

Structural and predictive aspects of proportional-integral-plus (PIP) control

C.j. Taylor, P.C. Young, A. Chotai, Roger Dixon

Mechanical Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

3 Citations (Scopus)

Abstract

Shows how the non-minimal state space (NMSS)-based PIP-LQ control system design can be constrained to yield exactly the same control algorithm as both GPC and standard, minimal state, LQG design methods. However, while NMSS includes these other approaches as special cases, it is less constrained and so more flexible in general terms: for example, while PIP-LQ has the simplicity of GPC, it is formulated in the powerful context of state variable feedback (SVF) control, like LQG, which allows for ready access to modern robust control methods, including H/sub /spl infin// and associated risk sensitive optimal control. But, unlike conventional minimal state LQG controllers, the NMSS design does not require the introduction of an observer or Kalman filter, with the concomitant disadvantage of reduced robustness. Furthermore, the NMSS methodology is particularly appropriate for solving multi-objective optimisation problems.

Original language	English
Title of host publication	UKACC International Conference on Control '96 (Conf. Publ. No. 427)
Publisher	Institution of Engineering and Technology
Pages	1374-1379
ISBN (Print)	0-85296-668-7
DOIs	https://doi.org/10.1049/cp:19960753
Publication status	Published - Sept 1996

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title = "Structural and predictive aspects of proportional-integral-plus (PIP) control",

abstract = "Shows how the non-minimal state space (NMSS)-based PIP-LQ control system design can be constrained to yield exactly the same control algorithm as both GPC and standard, minimal state, LQG design methods. However, while NMSS includes these other approaches as special cases, it is less constrained and so more flexible in general terms: for example, while PIP-LQ has the simplicity of GPC, it is formulated in the powerful context of state variable feedback (SVF) control, like LQG, which allows for ready access to modern robust control methods, including H/sub /spl infin// and associated risk sensitive optimal control. But, unlike conventional minimal state LQG controllers, the NMSS design does not require the introduction of an observer or Kalman filter, with the concomitant disadvantage of reduced robustness. Furthermore, the NMSS methodology is particularly appropriate for solving multi-objective optimisation problems.",

author = "C.j. Taylor and P.C. Young and A. Chotai and Roger Dixon",

year = "1996",

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doi = "10.1049/cp:19960753",

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T1 - Structural and predictive aspects of proportional-integral-plus (PIP) control

AU - Taylor, C.j.

AU - Young, P.C.

AU - Chotai, A.

AU - Dixon, Roger

PY - 1996/9

Y1 - 1996/9

N2 - Shows how the non-minimal state space (NMSS)-based PIP-LQ control system design can be constrained to yield exactly the same control algorithm as both GPC and standard, minimal state, LQG design methods. However, while NMSS includes these other approaches as special cases, it is less constrained and so more flexible in general terms: for example, while PIP-LQ has the simplicity of GPC, it is formulated in the powerful context of state variable feedback (SVF) control, like LQG, which allows for ready access to modern robust control methods, including H/sub /spl infin// and associated risk sensitive optimal control. But, unlike conventional minimal state LQG controllers, the NMSS design does not require the introduction of an observer or Kalman filter, with the concomitant disadvantage of reduced robustness. Furthermore, the NMSS methodology is particularly appropriate for solving multi-objective optimisation problems.

AB - Shows how the non-minimal state space (NMSS)-based PIP-LQ control system design can be constrained to yield exactly the same control algorithm as both GPC and standard, minimal state, LQG design methods. However, while NMSS includes these other approaches as special cases, it is less constrained and so more flexible in general terms: for example, while PIP-LQ has the simplicity of GPC, it is formulated in the powerful context of state variable feedback (SVF) control, like LQG, which allows for ready access to modern robust control methods, including H/sub /spl infin// and associated risk sensitive optimal control. But, unlike conventional minimal state LQG controllers, the NMSS design does not require the introduction of an observer or Kalman filter, with the concomitant disadvantage of reduced robustness. Furthermore, the NMSS methodology is particularly appropriate for solving multi-objective optimisation problems.

U2 - 10.1049/cp:19960753

DO - 10.1049/cp:19960753

M3 - Conference contribution

SN - 0-85296-668-7

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EP - 1379

BT - UKACC International Conference on Control '96 (Conf. Publ. No. 427)

PB - Institution of Engineering and Technology

ER -

Structural and predictive aspects of proportional-integral-plus (PIP) control

Abstract

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