جزییات کتاب
Enables readers to apply process dynamics and control theory to solve bioprocess and drug delivery problemsThe control of biological and drug delivery systems is critical to the health of millions of people worldwide. As a result, researchers in systems biology and drug delivery rely on process dynamics and control theory to build our knowledge of cell behavior and to develop more effective therapeutics, controlled release devices, and drug administration protocols to manage disease.Written by a leading expert and educator in the field, this text helps readers develop a deep understanding of process dynamics and control theory in order to analyze and solve a broad range of problems in bioprocess and drug delivery systems. For example, readers will learn how stability criteria can be used to gain new insights into the regulation of biological pathways and lung mechanics. They'll also learn how the concept of a time constant is used to capture the dynamics of diffusive processes. Readers will also master such topics as external disturbances, transfer functions, and input/output models with the support of the author's clear explanations, as well as:Detailed examples from the biological sciences and novel drug delivery technologies160 end-of-chapter problems with step-by-step solutionsDemonstrations of how computational software such as MATLAB and Mathematica solve complex drug delivery problemsControl of Biological and Drug-Delivery Systems for Chemical, Biomedical, and Pharmaceutical Engineering is written primarily for undergraduate chemical and biomedical engineering students; however, it is also recommended for students and researchers in pharmaceutical engineering, process control, and systems biology. All readers will gain a new perspective on process dynamics and control theory that will enable them to develop new and better technologies and therapeutics to treat human disease.Content: Chapter 1 Introduction (pages 1–20): Chapter 2 Mathematical Models (pages 21–41): Chapter 3 Linearization and Deviation Variables (pages 43–63): Chapter 4 Stability Considerations (pages 65–91): Chapter 5 Laplace Transforms (pages 93–115): Chapter 6 Inverse Laplace Transforms (pages 117–148): Chapter 7 Transfer Functions (pages 149–161): Chapter 8 Dynamic Behaviors of Typical Plants (pages 163–197): Chapter 9 Closed?Loop Responses with P, PI, and PID Controllers (pages 199–217): Chapter 10 Frequency Response Analysis (pages 219–241): Chapter 11 Stability Analysis of Feedback Systems (pages 243–267): Chapter 12 Design of Feedback Controllers (pages 269–292): Chapter 13 Feedback Control of Dead?Time Systems (pages 293–309): Chapter 14 Cascade and Feedforward Control Strategies (pages 311–333): Chapter 15 Effective Time Constant (pages 335–345): Chapter 16 Optimum Control and Design (pages 347–360):