Control in bioprocessing : modeling, estimation and the use of soft sensors /
Pablo Antonio López Pérez, Escuela Superior de Apan, Universidad Autónoma del Estado de Hidalgo, México, Ricardo Aguilar Lopez, Department of Biotechnology and Bioengineering. Centro de Investigación y de Estudios Avanzados (Cinvestav)/Center of Reaserch and Advanced Studies, Alejandro Ricardo Femat Flores, División de Matemáticas Aplciadas, IPICYT.
- First edition.
- 1 online resource
ABOUT THE AUTHOR Pablo Antonio López Pérez, PhD, is Professor at Escuela Superior de Apan, Universidad Autónoma del Estado de Hidalgo, México. His research focuses on Modeling, simulation and nonlinear control of Reactors, Bioreactors and Photobioreactors.
Ricardo Aguilar López, PhD is Professor at the Department of Biotechnology and Bioengineering, Center for Research and Advanced Studies (Cinvestav), México. His research interests include modeling of biosystems and bioprocesses, dynamic analysis in bioreactors and design of nonlinear control schemes applied to biological systems, as well as the development of online bioprocess monitoring schemes.
Ricardo Femat, PhD was the General Director of the Institute for Scientific and Technological Research of San Luis Potosi (IPICYT), and a Professor in the Department of Applied Mathematics in México. His research interests include (i) analysis, characterization and control of systems with complex dynamics, (ii) the regulation of glucose level in diabetics and (iii) the control of processes with reaction and diffusion.
Includes bibliographical references and index.
TABLE OF CONTENTS Preface xi
Part I Overview of the Control and Monitoring of Bioprocesses and Mathematical Preliminaries 1
1 Introduction 3
1.1 Overview of the Control and Monitoring of Bioprocesses 3
1.1.1 Why Nonlinear Control in Bioprocesses? 3
1.2 Improvements to Bioprocesses Productivity 13
1.2.1 Cell Lines 16
1.2.1.1 Cell Culture Process General 18
1.2.2 Microorganism Growth Under Controlled Conditions 18
1.2.3 On the Environment for the Microorganism’s Growth 19
1.2.4 Improving the Productivity for Specific Metabolic Products 21
1.3 Bioprocess Control 22
1.3.1 What is a Bioprocess? 22
1.3.2 Bioprocess Monitoring and Control 23
1.3.3 Stability of Bioprocess 25
1.3.4 Basic Concepts and Controllers 27
1.3.5 Advanced Control Schemes: Multivariable Control, Robust, Fuzzy Logic, Model Predictive Control, or Others 30
1.4.4 Process Analytical Technologies (Gas Analysis, Spectrometers, Infrared, HPLC, PCR, and Others) 34
1.4.5 Software Sensor (e.g. Cell Mass Estimation Via Complex Medium, Primary Carbon Substrate, Concentration Product of Line, Metabolites, Sensor to Computer Via Wireless) 36
1.5 Dynamic Bioprocess Models 40
1.5.1 Bioprocess Modeling for Control Purposes 40
1.5.2 Mass and Energy Balance of the Bioprocess 41
1.5.2.1 Dynamical Mass Balance 41
1.5.2.2 Batch Process 42
1.5.2.3 Fed-Batch 42
1.5.2.4 Continuous 43
1.5.2.5 Energy Balance 43
1.5.3 Black Box, White Box, and Gray Box Models 45
1.5.3.1 Black Box 45
1.5.3.2 White Box 45
1.5.3.3 Gray Box 45
1.5.4 Linear and Nonlinear Models 45
1.5.5 Segregated and Non-segregated Models 46
1.5.6 Structured and Unstructured Models 46
1.5.7 Structured Models 47
1.6 Process Optimization 51
1.6.1 Off-Line and On-Line Optimization of Bioprocesses 51
References 53
2 Mathematical Preliminaries 63
2.1 Systems of Ordinary Differential Equations 63
2.1.1 Differential Equations, Vector Fields, and State-Space Description 64
2.2 Linear Systems 70
2.2.1 The Fundamental Theorem for Linear Systems 70
2.2.2 Linear Systems in R2 71
2.2.3 Complex Eigenvalues 71
2.2.4 Multiple Eigenvalues 72
2.3 Nonlinear Dynamical Systems and its Analysis 72
2.3.1 Preliminary Concepts and Definitions 72
2.3.1.1 Continuous Dynamical Systems 73
2.3.1.2 Phase Space and Phase Portrait 73
2.3.1.3 Trajectories of Autonomous and Non-Autonomous Systems 73
2.3.1.4 The Vector Field 74
2.3.1.5 Lipschitz Condition 74
2.3.2 Existence-Uniqueness Theorem 75
2.3.2.1 Algebraic Properties of Lipschitz Continuous Functions 76
2.3.3 Dependence on Initial Conditions and Parameters 77
2.3.4 The Flow Defined by a Differential Equation 78
2.3.4.1 Differential Flow 78
2.3.5 Equilibrium Points 79
2.3.5.1 Equilibrium 79
2.3.6 The Hartman–Grobman Theorem 80
2.3.7 The Stable Manifold Theorem 81
2.3.8 Saddles, Nodes, Foci, and Centers 82
2.3.9 Center Manifold Theory 84
2.4 Stability Theory via Lyapunov Approach 84
2.4.1 Stability Notions 84
2.4.1.1 Stability 84
2.4.1.2 Asymptotic Stability 85
2.4.1.3 Exponential Stability 86
2.4.2 The Direct Method of Lyapunov (Second Method) 86
2.4.2.1 Positive Function 86
2.4.2.2 Theorem of Lyapunov 87
2.4.2.3 Globally Uniformly Asymptotically Stable of Lyapunov 88
2.4.2.4 Definition Matrices and Functions 88
2.4.3 The Indirect Method of Lyapunov (First Method) 90
2.4.3.1 Linearization 90
2.4.3.2 Stability by Linearization 90
2.4.4 Lasalles Invariance Principle 91
2.4.5 Invariant Set 91
2.4.6 Input/Output Stability 92
2.4.7 General Properties of Linear and Nonlinear Systems 93
2.4.8 Advanced Stability Theory 93
2.4.8.1 Concepts of Stability for Non-Autonomous Systems 93
2.4.8.2 Lyapunov-like Analysis Using Barbalat’s Lemma 94
2.5 Bifurcation Theory 94
2.5.1 Periodic Orbit 95
2.5.2 Limit Cycle 95
2.5.3 Bifurcation of Maps 95
2.5.4 Hyperbolic and Non-Hyperbolic Equilibrium Points 96
2.5.5 Bifurcation Point 96
2.5.6 Lyapunov Exponent 96
2.5.7 Chaos 97
2.5.8 Topological Equivalence 97
2.5.9 Example Bifurcations and Structural Stability of Dynamical Systems 98
9.4 Such Approaches, Known as Proposed Just-in-Time Modeling “Hybrid Systems” 242
9.5 Results 243
9.6 Conclusions 249
References 250
10 Virtual Sensor Design for State Estimation in a Photocatalytic Bioreactor for Hydrogen Production 255
10.1 Introduction 255
10.2 Material and Methods 257
10.2.1 Methods 257
10.2.2 Desulfovibrio Alaskensis 6SR 258
10.3 Mathematical Model Development 258
10.3.1 Basic Concepts 258
10.3.2 Proposed Model 258
10.3.3 Determination of Kinetic Parameters 261
10.4 Virtual Sensor Design 262
10.5 Results and Discussion 265
10.6 Conclusions 272
References 273
Index 277
"This chapter aims to develop in some detail the bases and concepts of bioprocesses related to the control theory introduced in basic principles of mathematical modeling in bioprocesses. From this viewpoint, the systems approach to bioengineering and bioprocessing, with its current focus on the development of mathematical models and their analysis, is a logical sequel that the control theory will play a relevant role in understanding the mechanisms of cellular and metabolic processes. It concerns specifically applications in modeling, estimation, and control of bioprocesses. Consequently, there are many exciting opportunities for control experts who want to shift their interests to bioprocesses"-- This book presents the most commonly employed approaches in the control of bioprocesses. It discusses the role that control theory plays in understanding the mechanisms of cellular and metabolic processes, and presents key results in various fields such as dynamic modeling, dynamic properties of bioprocess models, software sensors designed for the online estimation of parameters and state variables, and control and supervision of bioprocesses
Control in Bioengineering and Bioprocessing: Modeling, Estimation and the Use of Sensors is divided into three sections. Part I, Mathematical preliminaries and overview of the control and monitoring of bioprocess, provides a general overview of the control and monitoring of bioprocesses, and introduces the mathematical framework necessary for the analysis and characterization of bioprocess dynamics. Part II, Observability and control concepts, presents the observability concepts which form the basis of design online estimation algorithms (software sensor) for bioprocesses, and reviews controllability of these concepts, including automatic feedback control systems. Part III, Software sensors and observer-based control schemes for bioprocesses, features six application cases including dynamic behavior of 3-dimensional continuous bioreactors; observability analysis applied to 2D and 3D bioreactors with inhibitory and non-inhibitory models; and regulation of a continuously stirred bioreactor via modeling error compensation.
Applicable across all areas of bioprocess engineering, including food and beverages, biofuels and renewable energy, pharmaceuticals and nutraceuticals, fermentation systems, product separation technologies, wastewater and solid-waste treatment technology, and bioremediation Provides a clear explanation of the mass-balance–based mathematical modelling of bioprocesses and the main tools for its dynamic analysis Offers industry-based applications on: myco-diesel for implementing "quality" of observability; developing a virtual sensor based on the Just-In-Time Model to monitor biological control systems; and virtual sensor design for state estimation in a photocatalytic bioreactor for hydrogen production Control in Bioengineering and Bioprocessing is intended as a foundational text for graduate level students in bioengineering, as well as a reference text for researchers, engineers, and other practitioners interested in the field of estimation and control of bioprocesses.