Difference between revisions of "User talk:AndreC"

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(SAIChE Postgraduate Student Symposium Abstract)
 
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Abstract for Masters project up for discussion/comments.<br/>
 
Abstract for Masters project up for discussion/comments.<br/>
Current word count: 266 [250 max]
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Current word count: 249 [250 max]
  
 
<!--Paragraph with reference (Georgakis) feels bulky - maybe the specific reference should be dropped? -->
 
<!--Paragraph with reference (Georgakis) feels bulky - maybe the specific reference should be dropped? -->
  
<center>'''<big>Systematic Multivariable Predictive Controller Constraint Handling: Rigorous Geometric Methods</big>'''</center><br/>
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<center>'''<big>Systematic Model Predictive Controller Constraint Handling: Rigorous Geometric Methods</big>'''</center><br/>
 
<center>André H. Campher and Carl Sandrock<br/>
 
<center>André H. Campher and Carl Sandrock<br/>
 
''Department of Chemical Engineering, University of Pretoria''</center>
 
''Department of Chemical Engineering, University of Pretoria''</center>
  
The models used by model predictive controllers (MPCs) to predict future outcomes are usually unconstrained forms like impulse response-, response- or discrete state space models. Certain MPC algorithms allow constraints to be imposed on the inputs or outputs of a system; but, as they are not coupled with the process model and checked for consistency, infeasible constraints can be specified. Methods for handling constraints in a consistent manner, taking into account their interdependence and disambiguating the language used to specify constraints, would therefore be an attractive addition to any MPC package.  
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The models used by model predictive controllers (MPCs) to predict future outcomes are usually unconstrained forms like impulse or step responses and discrete state space models. Certain MPC algorithms allow constraints to be imposed on the inputs or outputs of a system; but they may be infeasible as they are not checked for consistency via the process model. Consistent constraint handling methods -- which account for their interdependence and disambiguate the language used to specify constraints -- would therefore be an attractive addition to any MPC package.  
  
A rigorous and systematic approach to constraint management has been developed, building on the work of Georgakis and others (for instance, Vinson & Georgakis, 2000) in interpreting constraint interactions. The method supports linear and non-linear (polynomial) steady-state systems, and provides an interface where the following actions can be taken and information obtained;
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A rigorous and systematic approach to constraint management has been developed, building on the work of Georgakis and others in interpreting constraint interactions. The method supports linear and non-linear (polynomial) steady-state system models, and provides an interface where the following information can be obtained;
 
* effects of constraint changes on the corresponding input/output constraints,
 
* effects of constraint changes on the corresponding input/output constraints,
 
* feasibility checks for constraints,
 
* feasibility checks for constraints,
 
* constraint-type information,
 
* constraint-type information,
 
* specification of constraint-set size and
 
* specification of constraint-set size and
* optimal fitting of constraints within the desirable input/output space.  
+
* optimal fitting of constraints within the desirable input/output space.
 
Mathematical rigour and unambiguous language for identifying constraint types were key design criteria.  Ample feedback to the user was added to provide a supportive rather than prescriptive environment.
 
Mathematical rigour and unambiguous language for identifying constraint types were key design criteria.  Ample feedback to the user was added to provide a supportive rather than prescriptive environment.
  
It was ensured that the outputs of the program were compatible with commercial MPC packages, such as Honeywell’s RMPCT® and AspenTech’s DMCPlus®. The aforementioned packages were used in conjunction with the developed software to test functionality and performance of the method. The method was applied to case studies from Anglo Platinum, the Tennessee Eastman sample problem and laboratory scale test rigs.
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The outputs of the program are compatible with commercial MPC packages, such as Honeywell’s RMPCT® and AspenTech’s DMCPlus®. These packages were used in conjunction with the developed software to test functionality and performance of the method. The method was applied to case studies from Anglo Platinum, the Tennessee Eastman sample problem and laboratory scale test rigs.

Latest revision as of 11:27, 27 July 2010

SAIChE Postgraduate Student Symposium Abstract

Abstract for Masters project up for discussion/comments.
Current word count: 249 [250 max]


Systematic Model Predictive Controller Constraint Handling: Rigorous Geometric Methods

André H. Campher and Carl Sandrock
Department of Chemical Engineering, University of Pretoria

The models used by model predictive controllers (MPCs) to predict future outcomes are usually unconstrained forms like impulse or step responses and discrete state space models. Certain MPC algorithms allow constraints to be imposed on the inputs or outputs of a system; but they may be infeasible as they are not checked for consistency via the process model. Consistent constraint handling methods -- which account for their interdependence and disambiguate the language used to specify constraints -- would therefore be an attractive addition to any MPC package.

A rigorous and systematic approach to constraint management has been developed, building on the work of Georgakis and others in interpreting constraint interactions. The method supports linear and non-linear (polynomial) steady-state system models, and provides an interface where the following information can be obtained;

  • effects of constraint changes on the corresponding input/output constraints,
  • feasibility checks for constraints,
  • constraint-type information,
  • specification of constraint-set size and
  • optimal fitting of constraints within the desirable input/output space.

Mathematical rigour and unambiguous language for identifying constraint types were key design criteria. Ample feedback to the user was added to provide a supportive rather than prescriptive environment.

The outputs of the program are compatible with commercial MPC packages, such as Honeywell’s RMPCT® and AspenTech’s DMCPlus®. These packages were used in conjunction with the developed software to test functionality and performance of the method. The method was applied to case studies from Anglo Platinum, the Tennessee Eastman sample problem and laboratory scale test rigs.