Checking date: 25/01/2019


Course: 2018/2019

Numerical methods in biomedicine
(15543)
Bachelor in Biomedical Engineering (Plan: 419 - Estudio: 257)


Coordinating teacher: SECO FORSNACKE, DANIEL

Department assigned to the subject: Mathematics Department

Type: Basic Core
ECTS Credits: 6.0 ECTS

Course:
Semester:

Branch of knowledge: Engineering and Architecture



Requirements (Subjects that are assumed to be known)
Calculus I, Calculus II, Linear Algebra, Differential Equations, Computer Programming.
Using NUMERICAL METHODS -NM- to calculate approximate solutions of models of physiological, cellular, and molecular systems. Study the stability and accuracy of NM. Calculate numerical solution of systems of nonlinear equations. Approximate the minimum of a function of several variables. Developing, analyzing, and implementing finite difference methods. Solving ordinary differential equations and systems by numerical integration methods. Using the software environments to discuss the efficiency, pros and cons of different NM.
Description of contents: programme
PROGRAMME 1- PRINCIPLES OF NUMERICAL MATHEMATICS. Well-Posedness and Condition Number of a Problem. Stability of Numerical Methods. The Floating-Point Number System. 2- ROOTFINDING OF NONLINEAR EQUATIONS. Conditioning of a Nonlinear Equation. The Newton-Raphson Method. Newton's Methods for Simultaneous Nonlinear Equations. 3- UNCONSTRAINED OPTIMIZATION. Necessary and Sufficient conditions for Optimality. Convexity. Optimization Methods. 4- FINITE DIFFERENCE METHODS: INTERPOLATION, DIFFERENTIATION AND INTEGRATION. Backward, Forward, and Central Differences. Interpolation and Extrapolation methods. 5- NUMERICAL SOLUTIONS OF ORDINARY DIFFERENTIAL EQUATIONS (ODEs). ODEs and Lipschitz Condition. One Step Numerical Methods. Zero-Stability, Convergence Analysis and Absolute Stability. Consistency. Numerical methods for ODEs. Systems of ODEs. Stiff Problems. 6- APROXIMATION THEORY. Fourier Transform.
Learning activities and methodology
One of the purposes of this course is to provide the mathematical foundations of numerical methods, to analyze their basic theoretical properties (stability, accuracy, computational complexity), and demonstrate their performances on examples and counterexamples which outline their pros and cons. The primary aim is to develop algorithmic thinking-emphasizing on long-living computational concepts. Every chapter is supplied with examples, exercises and applications of the discussed theory. The course relies throughout on well tested numerical procedures for which we include codes and test files. Students should write their own codes by studying and eventually rewriting the codes given by the Teacher in Aula Global. The personal codes should be run, tested and given up in Aula Global in the Computer Room classes. Throughout the course we emphasize graphic 2D and 3D representations of solutions. Through this visual approach, students will have a chance to experience the meaning, i.e. to understand what a solution means and how it behaves.
Assessment System
  • % end-of-term-examination 60
  • % of continuous assessment (assigments, laboratory, practicals...) 40

Basic Bibliography
  • [A] K. Atkinson. Elementary Numerical Analysis. John Wiley & Sons. 2004
  • [BC] A. Belegundu and T. Chandrupatla. Optimization Concepts and Applications in Engineering. Cambridge University Press, Second Edition. 2011.. 2011
  • [BF] R. L. Burden, J. D. Faires . Numerical Methods. Brooks/Cole, Cengage Learning,. 2003
  • [DCM] S. Dunn, A. Constantinides and P. Moghe. Numerical Methods in Biomedical Engineering. Elsevier Academic Press. 2010
  • [DH] Peter Deuflhard and Andreas Hohmann. Numerical Analysis in Modern Scientific Computing. An Introduction. Second Edition.. Springer. 2003
  • [FJNT] P.E. Frandsen, K. Jonasson, H.B. Nielsen, O. Tingleff. Unconstrained Optimization. IMM, DTU. 1999
  • [QSG] A. Quarteroni, F. Saleri and P. Gervasio. Scientific computing with MATLAB and Octave. Springer. 2010
  • [QSS] A. Quarteroni, R. Sacco and F. Saleri. Numerical Mathematics. Springer. 2007
  • [T] Lloyd N. Trefethen. Finite Difference and Spectral Methods for Ordinary and Partial Differential Equations. freely available online. 1996
Additional Bibliography
  • [HH] D. Higham and N. Higham. Matlab Guide. Second Edition. . 2005.
  • [K] C. Kelley. Iterative Methods for Optimization. SIAM. 1999.

The course syllabus may change due academic events or other reasons.