Development of a nonlinear predictive control algorithm and its application to flotation

Development of a nonlinear predictive control algorithm and its application to flotation

Bibliography: leaves 118-123. === This study consists of four clearly defined and interlinked objectives. The first is the development of a method of solving nonlinear optimal control problems. This method is then used to solve the underlying optimal control problems. This method is then used to sol...

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Main Author: Knights, Benjamin D H
Other Authors: Swartz, Chris
Format: Dissertation
Language:English
Published: University of Cape Town 2014
Subjects:
Chemical Engineering
Online Access:http://hdl.handle.net/11427/5305
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spelling ndltd-netd.ac.za-oai-union.ndltd.org-uct-oai-localhost-11427-53052020-12-10T05:11:13Z Development of a nonlinear predictive control algorithm and its application to flotation Knights, Benjamin D H Swartz, Chris Langson, Wilbur Chemical Engineering Bibliography: leaves 118-123. This study consists of four clearly defined and interlinked objectives. The first is the development of a method of solving nonlinear optimal control problems. This method is then used to solve the underlying optimal control problems. This method is then used to solve the underlying optimal control problem in a nonliear model predictive control (NMPC) strategy. By way of a case study, and to further understanding of the mechanisms of flotation, a dynamic model of a flotation circuit is developed. This nonlinear dynamic model is then used in the NMPC strategy to simulate the nonlinear predictive control of a flotation cell. An indirect approach is used in the method for solving optimal control problems, applying the Euler-Lagrange equations to transofrm the optimal control problem into a two-point boundary value problem (BVP). Conventionally these problems have been solved using the multiple shooting differential equation solver, or variants of it. In this work the BVP is solved by orthogonal collocation, using the FORTRAN package COLSYS. Stragegies are developed to solve a number of different classes of optimal control problems, including problems with constraints on the control trajectory, and terminal state constraints. An important aspect of this solution method is that it produces a continuous control trajectory over the entire solution horizon. The use of this optimal control problem in the nonlinear model predictive control strategy of Chen and Algöwer (1998) is then shown. This strategy is a quasi-infinite horizon NMPC strategy making use of a stabilising terminal penalty cost and terminal state inequality constraint. Stability is guaranteed if the optimal conrol problem is feasible. 2014-07-31T11:09:04Z 2014-07-31T11:09:04Z 2001 Master Thesis Masters MSc http://hdl.handle.net/11427/5305 eng application/pdf University of Cape Town Faculty of Engineering and the Built Environment Department of Chemical Engineering
collection NDLTD
language English
format Dissertation
sources NDLTD
topic Chemical Engineering
spellingShingle Chemical Engineering
Knights, Benjamin D H
Development of a nonlinear predictive control algorithm and its application to flotation
description Bibliography: leaves 118-123. === This study consists of four clearly defined and interlinked objectives. The first is the development of a method of solving nonlinear optimal control problems. This method is then used to solve the underlying optimal control problems. This method is then used to solve the underlying optimal control problem in a nonliear model predictive control (NMPC) strategy. By way of a case study, and to further understanding of the mechanisms of flotation, a dynamic model of a flotation circuit is developed. This nonlinear dynamic model is then used in the NMPC strategy to simulate the nonlinear predictive control of a flotation cell. An indirect approach is used in the method for solving optimal control problems, applying the Euler-Lagrange equations to transofrm the optimal control problem into a two-point boundary value problem (BVP). Conventionally these problems have been solved using the multiple shooting differential equation solver, or variants of it. In this work the BVP is solved by orthogonal collocation, using the FORTRAN package COLSYS. Stragegies are developed to solve a number of different classes of optimal control problems, including problems with constraints on the control trajectory, and terminal state constraints. An important aspect of this solution method is that it produces a continuous control trajectory over the entire solution horizon. The use of this optimal control problem in the nonlinear model predictive control strategy of Chen and Algöwer (1998) is then shown. This strategy is a quasi-infinite horizon NMPC strategy making use of a stabilising terminal penalty cost and terminal state inequality constraint. Stability is guaranteed if the optimal conrol problem is feasible.
author2 Swartz, Chris
author_facet Swartz, Chris
Knights, Benjamin D H
author Knights, Benjamin D H
author_sort Knights, Benjamin D H
title Development of a nonlinear predictive control algorithm and its application to flotation
title_short Development of a nonlinear predictive control algorithm and its application to flotation
title_full Development of a nonlinear predictive control algorithm and its application to flotation
title_fullStr Development of a nonlinear predictive control algorithm and its application to flotation
title_full_unstemmed Development of a nonlinear predictive control algorithm and its application to flotation
title_sort development of a nonlinear predictive control algorithm and its application to flotation
publisher University of Cape Town
publishDate 2014
url http://hdl.handle.net/11427/5305
work_keys_str_mv AT knightsbenjamindh developmentofanonlinearpredictivecontrolalgorithmanditsapplicationtoflotation
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