Book contents
- Frontmatter
- Contents
- Notation
- Preface
- Part I Overview of Optimization:Applications and Problem Formulations
- Part II From General Mathematical Background to General Nonlinear Programming Problems (NLP)
- Part III Formulation and Solution of Linear Programming (LP) Problems
- 10 Introduction to LP Models
- 11 Numerical Solution of LP Problems Using the Simplex Method
- 12 A Sampler of LP Problem Formulations
- 13 Regression Revisited: Using LP to Fit Linear Models
- 14 Network Flow Problems
- 15 LP and Sensitivity Analysis, in Brief
- 16 Multiobjective Optimization
- 17 Optimization under Uncertainty
- 18 Mixed-Integer Programming Problems
- 19 Global Optimization
- 20 Optimal Control Problems (Dynamic Optimization)
- 21 System Identification and Model Predictive Control
- Index
21 - System Identification and Model Predictive Control
from Part III - Formulation and Solution of Linear Programming (LP) Problems
Published online by Cambridge University Press: 17 December 2020
- Frontmatter
- Contents
- Notation
- Preface
- Part I Overview of Optimization:Applications and Problem Formulations
- Part II From General Mathematical Background to General Nonlinear Programming Problems (NLP)
- Part III Formulation and Solution of Linear Programming (LP) Problems
- 10 Introduction to LP Models
- 11 Numerical Solution of LP Problems Using the Simplex Method
- 12 A Sampler of LP Problem Formulations
- 13 Regression Revisited: Using LP to Fit Linear Models
- 14 Network Flow Problems
- 15 LP and Sensitivity Analysis, in Brief
- 16 Multiobjective Optimization
- 17 Optimization under Uncertainty
- 18 Mixed-Integer Programming Problems
- 19 Global Optimization
- 20 Optimal Control Problems (Dynamic Optimization)
- 21 System Identification and Model Predictive Control
- Index
Summary
Uncertainty is ubiquitous in engineering practice and models.Parameters that are estimated via online measurement or by experiments always carry a certain level of uncertainty with them – which can in fact be significant for difficult-to-measure systems.Other sources of uncertainty are fluctuations in process inputs, e.g. concentrations, flow rates, temperatures, etc.And finally, one may not be certain of the structure of models, e.g. the actual chemical reaction mechanism(s) may be uncertain.All these necessitate special handling of such models, and where the uncertainty can be quantified by probabilistic measures this allows special formulations and solution procedures to be employed so as to derive robust solutions with respect to the uncertainty involved.All these, along with the necessary theoretical concepts, are presented in this chapter, with subsequent emphasis for practical application to the multiple scenario approach for the handling of parametric uncertainty.
Keywords
- Type
- Chapter
- Information
- Optimization for Chemical and Biochemical EngineeringTheory, Algorithms, Modeling and Applications, pp. 312 - 335Publisher: Cambridge University PressPrint publication year: 2021