Reprint

Mathematical Modeling and Control of Bioprocesses

Edited by
April 2023
302 pages
  • ISBN978-3-0365-7140-9 (Hardback)
  • ISBN978-3-0365-7141-6 (PDF)

This book is a reprint of the Special Issue Mathematical Modeling and Control of Bioprocesses that was published in

Biology & Life Sciences
Chemistry & Materials Science
Computer Science & Mathematics
Engineering
Environmental & Earth Sciences
Summary

Mathematical modeling is at the heart of most current developments in biological system analysis and bioprocess optimization and control. At the industrial scale, this evolution is reflected in process analytical technologies (PAT), digital twins, and Industry 4.0. This reprint focuses on various aspects of mathematical modeling at the microscopic and macroscopic scales, respectively, and demonstrates the potential of these methodologies to gain insight into the cell metabolism, to support the design of software sensors to reconstruct unmeasurable variables, or to establish model-based optimization of the operating conditions and/or feedback control of the bioprocesses. The range of applications is vast, including biopharmaceuticals, bioenergy, and the environment.

Format
  • Hardback
License
© by the authors
Keywords
mathematical model; continuous bioreactor; biodegradation; phenol and p-cresol mixture; SKIP model; equilibrium points; stability analysis; global stabilizability; numerical simulation; MEC; hydrogen production; online optimization; golden section search; super-twisting controller; FPGA; bioplastic; copolymerization; polyhydroxyalkanoate; kinetic modeling; PID (PI) control; gain-scheduling; mathematical model; biotechnological cultivation process; dissolved oxygen concentration; flux variability analysis; flux balance analysis; sampling; metabolic network; elementary flux modes; set membership estimation; dynamic flux balance model; multiparametric programming; observability; variable structure system; process analytical technologies (PAT); off-gas analytic; real-time monitoring; viable cell biomass; perfusion process; continuous process; single-use bioreactor (SUB); oxygen uptake rate (OUR); soft sensor; metabolic flux analysis; metabolic network; VERO cells; biotechnology; B. thuringiensis kurstaki; biopesticides; kinetic parameters; dynamic model; composting; optimization; mathematical modeling; anaerobic digestion; biogas; chemostat; maintenance; operating diagram; optimization; productivity; stability; optimal control; modelling; microalgae; chemostat; nonlinear control; Pontryagin’s principle; singular control; Droop model; photobioreactor; biomass; biorefinery design; process integration; scheduling; simulation; n/a