Many processes in nature are intrinsically stochastic, a property that frequently needs
to be reflected when they are modeled. This course introduces students to a variety of
probabilistic techniques for mathematical modeling. The course will start with a review
of the basics of probability theory. The mathematical topics covered in the course will
include generating functions, Poisson and Markov processes (discrete and continuous),
branching processes, renewal processes and, time permitting, an introduction to
stochastic calculus and diffusion.
The use of each of these mathematical techniques will be illustrated in a variety of
examples including many from biology. The background for each problem will be described,
mathematical models will be developed and studied, and the implications of the
mathematical results will be interpreted.
Math 4331 - Section: 28010 - Intro To Real Analysis - by Field
MATH 4331 Intro To Real Analysis (Section# 28010 )
Time:
MoWeFr 9:00AM - 10:00AM - Room: F 162
Instructor:
Mike Field
Prerequisites:
MATH 3333 or consent of instructor.
Text(s):
lecture note from instructor
Description:
This is a first semester of a two semester course.
The emphasis in MATH 4331 will be on 1-variable theory and results from "classical analysis". Topics covered will include infinite series, sequences, functions (continuous, analytic, smooth), uniform convergence, Weierstrass Approximation theorem, Fourier series, the Gamma-function and the Euler-Maclaurin formula. There will also be a fairly extensive introduction about the real number system.
Math 4335 - Section: 30591 - Partial Differential Equations - by Wagner
MATH 4335 Partial Differential Equations (Section# 30591)
Time:
MoWeFr 12:00PM - 1:00PM - Room: AH 301
Instructor:
David Wagner
Prerequisites:
Math 3331 and 2433. Math 3334 recommended.
Text(s):
"Partial Differential Equations" by Walter Strauss 2nd Edition, published by Wiley.
Description:
Partial Differential Equations are used to model fundamental physical
phenomena such as heat conduction, wave propagation, quantum mechanics, and
electrostatics. In this course we will use the separation of variables method, and
Fourier Series, to construct solutions. Boundary value problems with eigenvalues will
prove to be important. We will introduce the Fourier Transform, especially as it
applies to the equation for heat conduction. In addition we will stress how different
pde's have very different properties.
This is a more theoretical and more mathematically rigorous course than 3363.
If a second semester (4336) is approved (this is not guaranteed), we will be able to
study Green's functions, the Schroedinger equation, the wave equation in several space
dimensions, and Distributions, Fourier transforms, and Laplace Transforms.
Math 4364 - Section: 25852 - Numerical Analysis - by Pan
MATH 4364 Numerical Analysis (Section# 25852 )
Time:
MoWe 4:00PM - 5:30PM - Room: AH 301
Instructor:
Tsorng-Whay Pan
Prerequisites:
Math 2431 (Linear Algebra), Math 3331 (Differential Equations). Ability to do computer assignments in FORTRAN, C, Matlab, Mathematica or Pascal.
Text(s):
Numerical Analysis (8th edition), by R. L. Burden and J. D. Faires
Description:
This is a first semester of a two semester course.
We will develop and analyze numerical methods for approximating the solutions of common
mathematical problems. The emphasis this semester will be on solving nonlinear
equations, interpolation, numerical integration, initial value problems of ordinary
differential equations, and direct methods for solving linear systems of algebraic
equations. This is an introductory course and will be a mix of mathematics and computing.
Math 4377 - Section: 28006 - Advanced Linear Algebra I - by Guidoboni
MATH 4377 Advanced Linear Algebra I (Section# 28006 )
Time:
TuTh 10:00AM - 11:30AM - Room: F 154
Instructor:
Giovanna Guidoboni
Prerequisites:
Math 2331 and a minimum of three semester hours of 3000-level mathematics.
Text(s):
Linear Algebra,2nd edition, by Hoffman and Kunze, Prentice Hall.
Description:
Topics covered include linear systems of equations, vector spaces, linear transformation, and matrices.
Math 4383 - Section: 25854 - Number Theory - by Hardy
MATH 4383 Number Theory (Section# 25854 )
Time:
MoWeFr 10:00AM - 11:00AM - Room: SR 121
Instructor:
John Hardy
Prerequisites:
MATH 3330
Text(s):
Elementary Number Theory by David M. Burton, 6th Edition, McGraw
Hill, ISBN 978-0-07-305118-8
Description:
This course covers the basic topics in introductory number theory: divisibility, congruences, primitive roots, quadratic reciprocity, diophantine equations, and other topics if time permits.
Math 4397 - Section: 30590 - Bio-statistics - by Bodmann
MATH 4397 Selected Topics in Math (Section# 30590 )
-
Bio-statistics -
Time:
TuTh 2:30PM - 4:00PM - Room: AH 301
Instructor:
Bernhard Bodmann
Prerequisites:
MATH 1432 and either of MATH 2311, MATH 3338 or MATH 3339.
Text(s):
Bernard Rosner, Fundamentals of Biostatistics, 6th edition, Thomson Brooks/Cole, 2006.
Description:
The goal of this course is to explore the subject of biostatistics in an intuitive, but
mathematically sound manner. The students will learn about a variety of uses, and
abuses, of statistical methods in biology and medicine. The material will be interspersed with simple programming projects and experiments, which allows the students to become familiar with R, the open-source software package used in these projects. The first part of the course is a rapid review of essentials in probability and statistics. The main part of the material focuses on some aspects of statistics which are important for typical estimation problems and hypothesis testing in biology and
medicine.
Math 4389 - Section: 30737 - Survey of Undergraduate Math (Online) - by Peters
MATH 4389: Survey of Undergraduate Math (section# 30737)
Time:
ARRANGE (online course)
Instructor:
Burnis Peters
Prerequisites:
Text(s):
Description:
Graduate online courses
Math 5350 - Section: 30632 - Intro To Differential Geometry (online) - by Ru
MATH 5350: Intro To Differential Geometry (section# 30632 )
Time:
ARRANGE (online course)
Instructor:
Min Ru
Prerequisites:
Math 2433(or equivalent) or consent of instructor.
Text(s):
A set of notes on curves and surfaces will be written and distributed by Dr. Ru.
Description:
The course will be an introduction to the study of Differential Geometry-one of the classical (and also one of the more appealing) subjects of modern mathematics. We will primarily concerned with curves in the plane and in 3-space, and with surfaces in 3-space. We will use multi-variable calculus, linear algebra, and ordinary differential equations to study the geometry of curves and surfaces in R3. Topics include: Curves in the plane and in 3-space, curvature, Frenet frame, surfaces in 3-space, the first and second fundamental form, curvatures of surfaces, Gauss's theorem egrigium, Gauss-Bonnet theorem, minimal surfaces.
Math 5385 - Section: 28022 - Statistics (online) - by Peters
MATH 5385: Statistics (section# 28022 )
Time:
ARRANGE (online course)
Instructor:
Charles Peters
Prerequisites:
Text(s):
Description:
Math 5397 - Section: 30634 - Discrete Mathematics II (online) - by Kaiser
MATH 5397: Selected Topics in Mathematics (section# 30634 )
-
Discrete Mathematics II -
Time:
ARRANGE (online course)
Instructor:
Kaiser
Prerequisites:
Graduate standing. This course is part of the Master Of Arts in Mathematics (MAM) program.
Text(s):
Discrete Mathematics and Its Applications by Kenneth H. Rosen, McGraw-Hill, Sixth edition. My own posted notes will supplement the text and serve as study guide.
Description:
The course will cover the last two chapters of the Rosen book on Boolean Algebras and Modeling Computation. In particular the relationship between Boolean Algebras and Logic Gates will be discussed. We will also study Boolean Functions and the representation of finite free Boolean Algebras.
Finite State Machines and Turing Machines serve as models of computations. We will study Kleene’s Theorem for a concise description of finite state machines. . We will also discuss the halting problem for Turing machines.
Course Organization and Grading: Students will receive on a regular basis homework assignments. There will be a midterm and a final. Homework counts for 30%, midterm for 30% and final for 40% of the final grade.
Math 5397 - Section: 30636 - Survey Of Mathematics (online) - by Etgen
MATH 5397: Selected Topics in Mathematics (section# 30636 )
-
Survey Of Mathematics -
Time:
ARRANGE (online course)
Instructor:
Etgen
Prerequisites:
Text(s):
Description:
Math 5397 - Section: 32566 - Complex Analysis (online) - by Ji
MATH 5397: Selected Topics in Mathematics (section# 32566 )
-
Complex Analysis -
Time:
ARRANGE (online course)
Instructor:
Shanyu Ji
Prerequisites:
Math 5333 or 3333, or consent of instructor.
Text(s):
Introduction to complex analysis , Juniro Noguchi, AMS (Translations of mathematical monographs, Volume 168).
Description:
This course is an introduction to complex analysis.
It will cover the theory of holomorphic functions, Cauchy theorem and Cauchy integral
formula,
residue theorem, harmonic and subharmonic functions, and other topics.
On-line course is taught through Blackboard Vista, visit http://www.uh.edu/webct/ for information on obtaining ID and password.
The course will be based on my notes and the textbook.
In each week, some lecture notes will be posted in Blackboard Vista, including homework assignment.
Homework will be turned in by the required date through Blackboard Vista. And the solution will be posted.
Graduate Courses
Math 6302 - Section: 25880 - Modern Algebra - by Tomforde
MATH 6302: Modern Algebra (section# 25880 )
Time:
MoWeFr 11:00AM - 12:00PM - Room: PGH 345
Instructor:
Mark Tomforde
Prerequisites:
MATH 4333 or MATH 4378 or consent of instructor.
Text(s):
"Abstract Algebra" by David Dummit and Richard Foote, 3rd Edition
Description:
The course covers topics from the theory of groups, rings, fields, and modules.
Math 6308 - Section: 28012 - Advanced Linear Algebra I - by Guidoboni
MATH 6308: Advanced Linear Algebra I (section# 28012 )
Time:
TuTh 10:00AM - 11:30AM - Room: F 154
Instructor:
Giovanna Guidoboni
Prerequisites:
Math 2331 and a minimum of three semester hours of 3000-level mathematics.
Text(s):
Linear Algebra,2nd edition, by Hoffman and Kunze, Prentice Hall.
Description:
Topics covered include linear systems of equations, vector spaces, linear transformation, and matrices.
Remark:
There is a limitation for counting graduate credits for Math 6308, 6309, 6312, or 6313. For detailed information, see Masters Degree Options.
Math 6312 - Section: 28016 - Intro To Real Analysis - by Field
MATH 6312: Intro To Real Analysis(section# 28016 )
Time:
MoWeFr 9:00AM - 10:00AM - Room: F 162
Instructor:
Mike Field
Prerequisites:
MATH 3333 or consent of instructor.
Text(s):
lecture note from instructor
Description:
This is a first semester of a two semester course.
The emphasis in MATH 6312 will be on 1-variable theory and results from "classical analysis". Topics covered will include infinite series, sequences, functions (continuous, analytic, smooth), uniform convergence, Weierstrass Approximation theorem, Fourier series, the Gamma-function and the Euler-Maclaurin formula. There will also be a fairly extensive introduction about the real number system.
There is a limitation for counting graduate credits for Math 6308, 6309, 6312, or 6313. For detailed information, see Masters Degree Options.
Math 6320 - Section: 25950 - Theory of Functions of a Real Variable - by Blecher
MATH 6320: Theory of Functions of a Real Variable (section# 25950 )
Time:
MoWe 1:00PM - 2:30PM - Room: PGH 350
Instructor:
David Blecher
Prerequisites:
An undergraduate real analysis sequence (Math 4331, 4332) or equivalent, or content of instructor. A little topology and metric spaces would be useful.
Text(s):
G.B. Folland, Real Analysis: Modern Techniques and Their Applications (Pure and Applied Mathematics: A Wiley-Interscience Series of Texts, Monographs and Tracts).
Recommended reading:
Lebesgue Integration on Euclidean Spaces, Frank Jones, Jones & Bartlett. Real Analysis, H.L. Royden, (3rd Edition), Prentice Hall. Real and Complex Analysis, W. Rudin, McGraw Hill. Measure Theory, D. L. Cohn, Birkhauser.
Description:
This is the first semester of a 2 semester sequence. This semester we will
be developing the basic principles of measure and integration. This body of knowledge is
essential to most parts of mathematics (in particular to analysis and probability) and
falls within the category of "What every graduate student has to know". The one test and
the final exam will be based on the notes given in class, and on the homework. After
each chapter we will schedule a problem solving workshop, based on the homework assigned
for that chapter. The most important part of your task as a graduate student in this
course is simply to reread the class notes making sure you understand everything. Please
ask me about anything you don't follow.
Final grade is approximately based on a total score of 400 points consisting of homework
(100 points), a semester test (100 points), and a final exam (200 points). The
instructor may change this at his discretion. The syllabus for the first semester will
cover some but not all of the following topics: Measures. Measurable functions.
Integration. Convergence of sequences of functions. The Lp spaces. Signed and complex
measures. Product measures and Fubini's theorem. Differentiation and integration.
Math 6322 - Section: 30592 - Theory of Functions of a Complex Variable - by Ji
MATH 6322: Theory of Functions of a Complex Variable (section# 30592 )
Time:
MoWeFr 9:00AM - 10:00AM - Room: AH 301
Instructor:
Shanyu Ji
Prerequisites:
Math 3333 or consent of instructor.
Text(s):
Introduction to complex analysis , Juniro Noguchi, AMS (Translations of
mathematical monographs, Volume 168).
Description:
This course is an introduction to complex analysis. This two semester course will cover the theory of holomorphic functions, residue theorem, harmonic and subharmonic functions, Schwarz's lemma, Riemann mapping theorem, Casorati-Weterstrass theorem, infinite product, Weierstrass' (factorization) theorem, little and big Picard Theorems and compact Riemann surfaces
theory.
Math 6326 - Section: 30593 - Partial Differential Equations - by Auchmuty
MATH 6326: Partial Differential Equations (section# 30593 )
Time:
TuTh 1:00PM - 2:30PM - Room: PGH 345
Instructor:
Giles Auchmuty
Prerequisites:
Real Analysis (M 4331-2) or equivalent.
Students should also know introductory Hilbert space theory and had some previous experience with the analysis, or simulation, of differential equations. It would help to have taken Applicable Analysis (M6360) and seen Lebesgue integration theory.
Text(s):
References:
Lawrence C. Evans, Partial Differential Equations, Graduate Studies in Mathematics, Volume 19, American Mathematical Society.
Robert McOwen, Partial Differential Equations, 2nd edition, Prentice-Hall Inc.
Description:
The first semester will concentrate on results about second order elliptic
and parabolic boundary value problems on bounded regions. We will concentrate
on proving well-posedness results, obtaining qualitative properties
and describing the representation of solutions.
Topics to be covered include basic analysis and calculus of weak and
classical derivatives. The relevant Hilbert-Sobolev spaces will be described
with some of properties proved. Then weak formulations of linear elliptic
equations, the Lax-Milgram theorem and Garding’s inequality. Variational
characterizations, spectral results and the spectral representation of solutions
for self-adjoint problems. Regularity results, inequalities and maximum principles for classical solutions.
Results for linear parabolic equations will include energy inequalities and
a priori bounds. Maximum principles and regularity results. Spectral and
Galerkin methods for approximating solutions with various types of boundary
conditions.
Math 6342 - Section: 25952 - Topology - by Ott
MATH 6342: Topology (section# 25952)
Time:
TuTh 11:30AM - 1:00PM - Room: SR 128
Instructor:
William Ott
Prerequisites:
MATH 4331 or consent of the instructor.
Text(s):
Topology (2nd edition) by James Munkres
Description:
We will study point-set topology comprehensively. Topics include topologies, continuity, convergence via sequences and nets, connectedness, compactness, separation axioms, the Urysohn lemma, metrizability, the Tietze extension theorem, quotient spaces, and function spaces. We will then study elements of algebraic topology (fundamental group, deck transformations, the Siefert-van Kampen theorem, covering spaces, the Jordan curve theorem).
Math 6360 - Section: 27892 - Applicable Analysis - by Auchmuty
MATH 6360: Applicable Analysis (section# 27892 )
Time:
TuTh 4:00PM - 5:30PM - Room: AH 301
Instructor:
Giles Auchmuty
Prerequisites:
Undergraduate Mathematical Analysis (M4331) or equivalent.
Students should know the basic definitions and results of metric spacetopology, matrices and finite dimensional linear algebra.
Text(s):
(not required): Naylor and Sell, Linear Operator theory in Science and engineering.Springer Verlag.
Description:
This course treats topics related to the solvability of various types ofequations, and also of optimization and variational problems. The first half of thesemester will concentrate on introductory material about norms, Banach and Hilbertspaces. This will be used to obtain conditions for the solvability of linear equations,including the Fredholm alternative. The second half of the course will cover thecontraction mapping
theorem and its use to prove various results about nonlinear equations. These includethe finite dimensional implicit and inverse function theorems and theexistence of solutions of initial value problems for ordinary differential equations and of integralequations.
Math 6366 - Section: 25954 - Optimization and Variational Methods - by He
MATH 6366: Optimization and Variational Methods (section# 25954 )
Time:
MoWeFr 10:00AM - 11:00AM - Room: PGH 345
Instructor:
Jiwen He
Prerequisites:
Graduate standing or consent of the instructor. Students are expected to have a good grounding in basic real analysis and linear algebra.
The focus is on key topics in optimization that are connected through the themes of convexity, Lagrange multipliers, and duality. The aim is to develop a analytical
treatment of finite dimensional constrained optimization, duality, and saddle point
theory, using a few of unifying principles that can be easily visualized and readily
understood. The course is divided into three parts that deal with convex analysis,
optimality conditions and duality, computational techniques. In Part I, the mathematical theory of convex sets and functions is developed, which allows an intuitive, geometrical approach to the subject of duality and saddle point theory. This theory is developed in detail in Part II and in parallel with other convex optimization topics. In Part III, a comprehensive and up-to-date description of the most effective algorithms is given along with convergence analysis.
Math 6370 - Section: 25956 - Numerical Analysis - by Hoppe
MATH 6370: Numerical Analysis (section# 25956)
Time:
MoWeFr 12:00PM - 1:00PM - Room: PGH 345
Instructor:
Ronald Hoppe
Prerequisites:
Calculus and Linear algebra
Text(s):
Introduction to Numerical Analysis, Third edition, Springer, New York, 2002 by Josef Stoer, Roland Bulirsch,
Description:
The course will cover the numerical solution of linear and nonlinear algebraic systems, linear and nonlinear least-squares problems, polynomial, spline and trigonometric interpolation, numerical integration, and the numerical solution of eigenvalue problems.
Math 6382 - Section: 25960 - Probability Models and Mathematical Statistics - by Kao
MATH 6382: Probability Models and Mathematical Statistics (section# 25960 )
Time:
TuTh 5:30PM - 7:00PM - Room: PGH 350
Instructor:
Edward Kao
Prerequisites:
Graduate standing
Text(s):
"An Intermdeiate Course in Probability" by Allan Gut, Springer-Verlag,
Paperback, 1995, ISBN 0-387-94507-5.
Description:
This course is to provide students with a solid background and understanding of the
basic results and methods in probability before entering into more advance courses in
probability and statistics. The subjects to be covered include multivariate random
variables, conditioning, transforms, order statistics, the multivariate normal
distribution, convergence, and the Poisson processes.
Math 6384 - Section: 25962 - Discrete-Time Model in Finance- by Kao
MATH 6384: Discrete -Time Model in Finance (section# 25962)
Time:
TuTh 2:30PM - 4:00PM - Room: F 154
Instructor:
Edward Kao
Prerequisites:
Math 6382, or equivalent background in probability.
Text(s):
Introduction to Mathematical Finance: Discrete-Time Models, by Stanley Pliska, Blackwell Publishing, 1997 ISBN 1-55786-945-6
Description:
This course is for students who seek a rigorous introduction to the modern financial theory of security markets. The course starts with single-periods and then moves to multiperiod models
within the framework of a discrete-time paradigm. We study the valuation of financial, interest-rate, and energy derivatives and optimal consumption and investment problems. The notions of risk neutral valuation and martingale will play a central role in our study of valuation of derivative securities. The discrete time stochastic processes relating to the subject will also be examined. The course serves as a prelude to a
subsequent course entitled Continuous-Time Models in Finance.
Math 6395 - Section: 30594 - Reproducing Kernel Hilbert Spaces - by Paulsen
MATH 6395: Select Topics in Analysis (section# 30594 )
Reproducing Kernel Hilbert Spaces
Time:
MoWeFr 11:00AM - 12:00PM - Room: SEC 203
Instructor:
Vern Paulsen
Prerequisites:
Familiarity with Hilbert Space
Text(s):
None
Course notes will be made available
Description:
Reproducing kernel Hilbert spaces play an important role in a number of
areas of mathematics, including statistics, approximation theory, harmonic analysis,
complex analysis and operator theory.
In this course we will develop their basic properties, study special spaces, including
the Hardy and Bergman spaces. We will then look at multipliers on these spaces and use
their theory to prove the classical Nevanlinna-Pick interpolation theorem. Finally, we
will develop the theory of vector-valued reproducing kernel Hilbert spaces, linear
fractional maps on matrix balls and use these results to prove the matrix-valued version
of the Nevanlinna-Pick theorem.
Math 6395 - Section: 30604 - Introduction to Wavelets - by Labate
MATH 6395:Select Topics in Analysis (section# 30604)
-
Introduction to Wavelets -
Time:
MoWe 4:00PM - 5:30PM - Room: PGH 348
Instructor:
Demetria Labate
Prerequisites:
Consent of instructor. It is strongly encouraged that students have a background in Linear Algebra and Real Analysis.
Text(s):
I will select most material from: A Mathematical Introduction toWavelets , by P. Wojtaszczyk, 1997. ISBN-10:0521578949
Additional notes and papers will be provided by the instructor.
Description:
Wavelet theory stands at the crossroad of harmonic analysis, signalprocessing and
scientific computing. Its goal is to provide a coherent setof mathematical methods that
are adapted to the study of a variety ofnonstationary signals and are also suitable for
efficient algorithmicimplementation. The past decade has witnessed an explosion of
research onwavelets, including thousands of papers and a great number of
successfulapplications. These applications include, to name a few, the new
FBIfingerprint database and JPEG2000, the new standard for image compression(replacing
the old JPEG).
This course will provide an introduction to the theory of wavelets and itsapplications in mathematics and signal processing. Some of the topics I will address are:
Orthonormal bases and frames: A basic problem in mathematics andengineering is to
represent a function or a signal as superposition ofelementary components. I will
introduce the theory of frames and show thatit provides the general framework to address
this problem. Orthonormalbases are a special example of frames.
Wavelet bases: The first wavelet basis, the Haar basis, was discovered in1909 before
wavelet theory was born. Unfortunately, the elements of thisbasis are not continuous.
The success of the wavelet theory is due to theability to construct a variety of wavelet
bases with very nicemathematical properties such as smoothness, compact support,
vanishmoments, etc. I will present several examples of wavelet bases anddescribe what
kind of features are desirable in such a basis.
Multiresolution Analysis: Multiresolution analysis is a general method forconstructing
wavelet bases. I will describe how to use this approach toconstruct the Shannon
wavelets, the Daubechies wavelets and the splinewavelets.
Wavelets and approximation theory: One striking feature of wavelets istheir ability to
represent function with discontinuities. In fact waveletshave optimal approximation
properties for several classes of functions andsignals. I will introduce linear and
nonlinear approximations, examine theapproximation properties of wavelets and compare
them to Fourier methods.
Wavelets and signal processing: Wavelets appear today in a variety ofadvanced signal
processing applications, including analysis anddiagnostics, quantization and
compression, transmission and storage, noisereduction and removal. I will describe the
connection between wavelettheory and filter banks theory in signal processing. I will
presentapplications of wavelets to data/image compression and denoising. Some ofthis
applications will be further explored by the students as individualor group projects.
Math 6397 - Section: 34173 - Intro To Riemannian Geometry - by Ru
MATH 6397: Intro To Riemannian Geometry (section# 34173
)
Math 6397 - Section: 30597 - Stochastic Models in Biology - by Josic
MATH 6397: Stochastic Models in Biology (section# 30597 )
Time:
TuTh 10:00AM - 11:30AM - Room: PGH 350
Instructor:
Kresimir Josic
Prerequisites:
two semesters of calculus, undergraduate probability, differential equations and linear algebra.
Text(s):
Description:
While deterministic models of biological systems can offer valuable insights into their function and behavior, they do not fully capture the effects of randomness and variability which are fundamental features of nearly all biological systems. In this course we will apply the theory of probability and stochastic processes to models of biological systems. Students taking the course should be comfortable with multivariate calculus, differential equations and linear algebra.
Topics to be covered include: a review of probability, including numerical techniques for generating random samples, Markov processes with discrete and continuous space vari-ables, diffusion processes, Wiener and Ornstein-Uhlenbeck processes, point processes, Gillespie's algorithm and other algorithms for simulating stochastic processes and their application in biology, statistical analysis of time series, power spectra of random processes. A portion of the course will be devoted to numerical simulations of stochastic systems using MATLAB.
Math 6397 - Section: 30599 - Stochastic Differential Equations - by Torok
MATH 6397: Stochastic Differential Equations (section# 30599)
Time:
TuTh 2:30PM - 4:00PM - Room: PGH 345
Instructor:
Andrew Torok
Prerequisites:
graduate (or advanced undergraduate) standing
Text(s):
We will mainly follow the notes of L. C. Evans (UC Berkeley), available on
his web-page.
Additional material will be handed out or placed on reserve in the library.
Description:
Stochastic differential equations arise when some randomness is allowed in
the coefficients of a differential equation. They have many applications,
including mathematical biology, theory of partial differential equations,
differential geometry and mathematical finance.
This is an introduction to the theory and applications of stochastic
differential equations. A knowledge of measure theory is strongly
recommended but not required. First we will review measure theory,
probability spaces, random variables and stochastic processes. Brownian
motion will be discussed in some detail before we introduce the Ito
integral and relevant aspects of martingale theory as a method to
formulate and solve stochastic differential equations. Numerical schemes
will be also discussed. Applications will include mathematical finance
(arbitrage and option pricing) and PDE's.
Math 6397 - Section: 33806 - Deformable Shapes in R2 and R3 : Comparison and Modeling. - by Azencott
MATH 6397: Special Topics: Deformable Shapes in R2 and R3 : Comparison and Modeling.
Section# 33806
Time:
TuTh 4:00PM - 5:30PM- Room: PGH 345
Instructor:
Robert Azencott
Prerequisites:
Undergraduate differential geometry
Text(s):
"Shapes and Diffeomorphisms" Laurent Younes , Springer, 2009
Description:
Quantitative comparison of smooth shapes in R2 or R3 involves the mathematical
definition of distances between shapes and/or between geometric characteristics of
shapes, for which a major requirement is the invariance under the action of natural
groups of deformations (linear or non linear) in euclidean spaces. We will present key
examples of shapes distances invariant by deformations and outline their applications
to shape recognition in image analysis.
Deformable mathematical models of smooth curves and surfaces in R3 have important
applications to the modeling of soft organs by analysis of 3D medical images. We will
present the widely used NURBS (non uniform rational B-spline) models and show how the
minimization of deformation energy leads to the quantitative comparison of "soft shapes".
Math 7396 - Section: 30602 - Iterative Methods for Large Scale Problems - by Kuznetzov
MATH 7396: Iterative Methods for Large Scale Problems (section# 30602)
Time:
MoWe 1:00PM - 2:30PM - Room: PGH 345
Instructor:
Yuri Kuznetzov
Prerequisites:
Graduate standing
Text(s):
Description:
Finite element,finite volume and finite difference discretizations
of partial differential equations result in large scale systems of linear
algebraic equations with ill-conditioned matrices.Preconditioned iterative
methods are the only way for efficient solving of these systems.
The course consists in three major parts.In the first part,we analyse the
basic properties of matrices arising from discretizations of elliptic and
parabolic problems.The second part is devoted to the basic preconditioned
iterative methods.We consider several advanced techniques based on domain
decomposition and multilevel ideas for the construction of efficient
preconditioners.In the final part ,we apply preconditioned iterative methods
for algebraic systems arising from the diffusion and convection-diffusion
differential problems.
Math 7394 - Section: 30603 - Computational Methods for Newtonian & Non-Newtonian Incompressible Viscous Flows - by Glowinski
MATH 7394: Computational Methods for Newtonian & Non-Newtonian Incompressible Viscous Flows (section# 30603 )