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Department of Molecular Biosciences & Bioengineering
University of Hawaii-Manoa
1955 East-West Road, Ag. Science 218
Honolulu, Hawaii 96822
Telephone: (808) 956-8384
FAX: (808) 956-3542
Email:mbbe@ctahr.hawaii.edu |
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BE 350 - Dynamic Systems Modeling
Instructor: Daniel M. Jenkins
Office: Agricultural Science 415L
Office Hours: TBA & by appointment
Telephone: 956-6069
Email: danielje@hawaii.edu
Grading:
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Assignments and Lab:
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30%
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Midterms (2):
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20% each
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Final:
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30%
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| Textbook: |
Course notes and additional readings will be posted on WebCT: |
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(Log on with your UH username and password, then click "MAN: Dynamic Syst Model"). Note that course notes will not be posted if attendance is not ≥ 75%. |
| Prerequisites: |
BIOL 171, CHEM 162 or 181A, EE 160, MATH 243 or 252A, and PHYS 170; or consent. Co-requisite BE 350L. |
| Catalog Description: |
3 units. Introduction to analytical and numerical solutions for systems of differential equations. Modeling and computer simulation of representative dynamic systems encountered in biological engineering. |
Course Content
| Week |
Topics |
| 1 |
Introduction of basic principles: conservation of mass, energy, momentum, charge, etc. Review of systems of linear equations and linear algebra. |
| 2 |
Determinate and indeterminate systems, singularity. Simple biomass balances using linear algebra. Solution of linear ordinary differential equations. |
| 3 |
Solution of systems of linear ordinary differential equations. Representative biological systems modeled by systems of linear ordinary differential equations. |
| 4 |
Solutions of systems of differential equations with repeated and/or complex eigenvalues: system oscillation. Introduction to MATLAB programming environment. |
| 5 |
Direct solution of higher order differential equations and as a system of linear equations. Introduction to Laplace transforms for solving differential equations. |
| 6 |
Laplace transforms and Exam 1. |
| 7 |
Software tools for solving systems of linear equations. Introduction to numerical methods for solving differential equations. |
| 8 |
Continuation of numerical methods for solving differential equations: Euler, modified Euler, and Runge-Kutte approximations. |
| 9 |
Implementation of numerical models in MATLAB software. Introduction to LabVIEW data acquisition software and commercial data loggers. |
| 10 |
Simple model validation using experimental data: linear regression, linearization of complex data sets, graphic techniques, non-linear regression tools. |
| 11 |
Simple modeling of dynamic systems in biological engineering: 'lumped' analysis for transient mass and energy transfer. |
| 12 |
Finite difference methods (explicit and implicit numerical solutions) for solving multidimensional transport problems in biology. |
| 13 |
Finite difference methods (continued), Exam 2 |
| 14 |
Models of representative biological systems: enzyme kinetics models, counter current heat exchange, thermal destruction of microbes, growth and bioproduction kinetics, etc. |
| 15 |
Open for contingencies, quizzes, review, and student evaluations. |
* Note that some topics above will require more or less than 1 week to cover, and the syllabus should not be considered an absolute guide to the amount of time spent on each topic.
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