Knowledge of high school algebra is a prerequisite for all mathematics courses. In exceptional cases, the prerequisite for a course above the calculus sequence may be waived at the discretion of instructor.
105 Precalculus Mathematics (3:3:0) Prerequisites: high school algebra I, algebra II, and geometry, and specified score on Math Placement Test; or successful completion of self-paced algebra tutorial program offered by Math Literacy Center. Call Mathematical Sciences Department at 703-993-1460 for details. Reviews mathematics skills essential to studying calculus. Topics include equations, inequalities, absolute values, graphs, functions, exponential and logarithmic functions, and trigonometry. May not be used as credit toward BA or BS in mathematical sciences. This course does not satisfy the university’s quantitative reasoning requirement for the BA degree. May not be taken for credit after receiving grade of C or better in any MATH course numbered 113 or higher.
106 Quantitative Reasoning (3:3:0) Prerequisite: specified score on Math Placement Test, or successful completion of self-paced Basic Math Program offered by Math Literacy Center. Quantitative skills for real world. Topics include critical thinking, modeling by functions, graphs, growth, scaling, probability, and statistics.
108 Introductory Calculus with Business Applications (3:3:0) Prerequisite: specified score on Math Placement Test, or successful completion of self-paced algebra program offered by Math Literacy Center. Call Mathematical Sciences Department at 703-993-1460 for details. Functions, limits, derivative, and integral. Applications of differentiation and integration. Students who have received credit for MATH 113 or 114 may not receive credit for this course.
110 Introductory Probability and Statistics (3:3:0) Prerequisite: specified score on Math Placement Test, or successful completion of self-paced Basic Math Program offered by Math Literacy Center. Elementary set theory, probability, and statistics.
111 Linear Mathematical Modeling (3:3:0) Prerequisite: specified score on Math Placement Test, or successful completion of self-paced basic math program offered by Math Literacy Center. Matrix algebra, systems of linear equations, Markov chains, difference equations, and data fitting.
112 Discrete Mathematics for BSIT (3:3:0). Prerequisite: specified score on Math Placement Test, or successful completion of self-paced Algebra Tutorial Program offered through Math Learning Center. Introduces ideas of discrete mathematics including mathematical induction, sets, logic, graphs, trees, basic counting arguments, and discrete probability. Students who have received credit for MATH 125 may not receive credit for this course. Intended for BSIT students; does not count toward a major or minor in mathematics.
113 Analytic Geometry and Calculus I (4:4:1) Prerequisites: thorough understanding of high school algebra and trigonometry, and specified score on Math Placement Test; or grade of C or better in MATH 105. Functions, limits, the derivative, maximum and minimum problems, the integral, and transcendental functions.
114 Analytic Geometry and Calculus II (4:4:1) Prerequisite: grade of C or better in MATH 113. Methods of integration, conic sections, parametric equations, infinite series, and power series.
115 Analytic Geometry and Calculus I (Honors) (4:4:1) Prerequisite: placement or permission of department. More challenging version of MATH 113. Functions, limits, the derivative, maximum and minimum problems, the integral, and transcendental functions.
116 Analytic Geometry and Calculus II (Honors) (4:4:1) Prerequisite: successful completion of MATH 115, or grade of A in MATH 113 and recommendation of MATH 113 instructor. More challenging version of MATH 114. Methods of integration, conic sections, parametric equations, infinite series, and power series.
125 Discrete Mathematics I (3:3:0) Prerequisite: specified score on Math Placement Test, or successful completion of self-paced algebra program offered by Math Literacy Center. Introduces ideas of discrete mathematics and combinatorial proof techniques including mathematical induction, sets, graphs, trees, recursion, and enumeration.
203 Matrix Algebra (3:3:0) Prerequisite: MATH 114 or permission of instructor. Systems of linear equations, linear independence, linear transformations, inverse of a matrix, determinants, vector spaces, eigenvalues, eigenvectors, and orthogonalization.
213 Analytic Geometry and Calculus III (3:3:0) Prerequisite: grade of C or better in MATH 114. Partial differentiation, multiple integrals, line and surface integrals, and three-dimensional analytic geometry.
214 Elementary Differential Equations (3:3:0) Prerequisite: MATH 213 or 215. First-order ODEs, higher-order ODEs, Laplace transforms, linear systems, nonlinear systems, numerical approximations, and modeling.
215 Vector Calculus (3:3:0) Prerequisites: permission of instructor, and MATH 113 and 114. Vectors and vector-valued functions, partial differentiation, multiple integrals, line integrals, surface integrals, and transformation of coordinates.
216 Theory of Differential Equations (3:3:0) Prerequisites: MATH 203 and 213 or 215. First- and second-order equations, existence uniqueness of solutions, systems of differential equations, and phase plane analysis.
271 Mathematics for the Elementary School I (3:3:0) Concepts and theories underlying elementary school mathematics, including problem solving, whole numbers and numeration, whole numbers operations and properties, number theory, fractions, decimals, ratio and proportion, and integers. Intended for school educators; does not count toward major in mathematics.
272 Mathematics for the Elementary School II (3:3:0) MATH 271 recommended before enrolling. Continuation of MATH 271. Topics include rational and real numbers, introduction to algebra, geometry, statistics, and probability. Intended for school educators; does not count toward major in mathematics.
290 Introduction to Advanced Mathematics (3:3:0) Prerequisite: MATH 114. Set theory; graphs; functions; equivalence relations and partitions; partially ordered sets; induction; construction of the natural, rational, real, and complex number systems; well-ordering principle; and cardinality. Primarily intended for mathematics majors.
301 Number Theory (3:3:0) Prerequisite: 6 math credits. Prime numbers, factorization, congruences, and Diophantine equations.
302 Geometry (3:3:0) Prerequisite: 6 math credits. Fundamental concepts of incidence. Axioms of Euclidean geometry and the resulting theory, and axioms and development of non-Euclidean and projective geometry.
313 Introduction to Applied Mathematics (3:3:0) Prerequisite: MATH 213. Vector differential calculus, vector integral calculus, Fourier analysis, and complex analysis.
314 Introduction to Applied Mathematics (3:3:0) Prerequisite: MATH 214 or 216. Series solutions of differential equations, Bessel and Legendre equations, Sturm-Liouville problems, and partial differential equations.
315 Advanced Calculus I (3:3:0) Prerequisites: MATH 213 and 290. Number system, functions, sequences, limits, continuity, differentiation, integration, transcendental functions, and infinite series.
316 Advanced Calculus II (3:3:0) Prerequisite: MATH 315. Sequences of functions, Taylor series, vectors, functions of several variables, implicit functions, multiple integrals, and surface integrals.
321 Abstract Algebra (3:3:0) Prerequisites: MATH 290 and 215 or 213. Theory of groups, rings, fields.
322 Linear Algebra (3:3:0) Prerequisites: MATH 290 and 203. Abstract vector spaces, linear independence, bases, linear transformations, matrix algebra, inner product, and special topics.
325 Discrete Mathematics II (3:3:0) Prerequisite: MATH 125. Advanced counting, binomial identities, generating functions, advanced recurrence, inclusion-exclusion, and network flows.
351 Probability (3:3:0) Prerequisite: MATH 213 or 215. Random variables, probability functions, special distributions, and limit theorems.
352 Statistics (3:3:0) Prerequisite: MATH 351. Estimation, decision theory, testing hypothesis, correlation, linear models, and design.
382 Introduction to Stochastic Processes (3:3:0) Prerequisite: MATH 351. General notion of stochastic processes, finite and infinite Markov chains, discrete and continuous Markov processes, stationary processes, random walk problems, birth and death processes, waiting line and serving problems, and Brownian motion.
400 History of Math (3:3:0) Prerequisites: completion or concurrent enrollment in all other required general education courses, and completion of MATH 290. Explores internal controversies and dynamics of mathematics in larger intellectual and social settings. Topics vary but might include differential equations devised for mechanics and astronomy by Euler, Lagrange, and Laplace; foundation of mathematical analysis from Cauchy to Weierstrass; algebras of Galois and Boole; or creation of non-Euclidean geometry and Cantor’s transfinite sets. Credits may not be used toward “upper division” math hours required of math majors.
411 Functions of a Complex Variable (3:3:0) Prerequisite: MATH 214 or 216. Analytic functions, contour integration, residues, and applications to such topics as integral transforms, generalized functions, and boundary value problems.
413 Modern Applied Mathematics I (3:3:0) Prerequisites: MATH 203, and 214 or 216. Synthesis of pure mathematics and computational mathematics. Emphasizes interplay between discrete and continuous mathematics. Mathematical structure revealed from equilibrium models in discrete and continuous systems.
414 Modern Applied Mathematics II (3:3:0) Prerequisite: MATH 413. Continuation of MATH 413, which involves synthesis of pure mathematics and computational mathematics. Fourier analysis and its role in applied mathematics developed (differential equations and approximations). Discrete aspects emphasized in computational models.
431 Topology (3:3:0) Prerequisite: MATH 315. Metric spaces, topological spaces, compactness, and connectedness.
441 Operations Research I (3:3:0) Prerequisite: MATH 203 or 216, or permission of instructor. Survey of deterministic methods for solving real-world decision problems. Programming model and simplex method of solution, duality and sensitivity analysis, transportation and assignment problems, shortest path and maximal flow problems, project networks including PERT and CPM, introduction to integer and nonlinear programming, dynamic programming and game theory. Emphasizes modeling and problem solving.
442 Operations Research II (3:3:0) Prerequisite: MATH 351, or permission of instructor. Survey of probabilistic methods for solving real-world decision problems. Probability review, queuing theory, inventory theory, Markov decision processes, reliability, decision theory, simulation. Emphasizes modeling and problem solving.
446 Numerical Analysis I (3:3:0) Prerequisites: MATH 203 and CS 112. Significant figures, round-off errors, iterative methods of solution of nonlinear equations of a single variable, solutions of linear systems, iterative techniques in matrix algebra, interpolation and polynomial approximation.
447 Numerical Analysis II (3:3:0) Prerequisites: MATH 214 or 216, and 446. Numerical differentiation and integration, initial-value and boundary-value problems for ordinary differential equations, methods of solution of partial differential equations, iterative methods of solution of nonlinear systems, approximation theory.
491, 492 Reading and Problems (1–3:0:0), (1–3:0:0) For mathematical sciences majors only. Independent study in math. Must be arranged with instructor before registering.
493 Topics in Applicable Mathematics (3:3:0) Prerequisite: 6 credits of math at or above 310 level. Topics that have been successfully used in applications of mathematics. Subject determined by instructor.
494 Topics in Pure Mathematics (3:3:0) Prerequisite: 6 credits of math at or above 310 level. Topics of pure math not covered in other courses. Topics might include Galois theory, cardinal and ordinal arithmetic, measure theory, mathematical logic, and differential geometry. Subject determined by instructor.
Prior knowledge of linear algebra and single and multivariable calculus assumed in all math graduate courses. A double number separated by a comma (MATH 555, 556) indicates both graduate courses normally constitute a sequence, and the first semester is prerequisite to the second. The prerequisite may be waived by permission of department chair. See also STAT and OR courses.
551 Regression and Time Series (3:3:0) Prerequisites: MATH 352, STAT 652, SOA Exam P, or permission of instructor. Mathematics of regression, exponential smoothing, time series, and forecasting. Material included in this course constitutes Society of Actuaries Validation by Educational Experience (VEE) for applied statistics and corresponds to part of Casualty Actuary Society Exam 3.
554 Financial Mathematics (3:3:0) Prerequisite: MATH 113, corequisite: MATH 114. Simple and compound interest, annuities, present and future value, yield rates, capital budgeting, amortization schedules, mortgages, bonds. Material corresponds to the Society of Actuaries Exam: Financial Mathematics (FM). Not appropriate for graduate science and engineering majors not considering actuarial or financial career. Cannot be counted toward MS or PhD degree in mathematics.
555, 556 Actuarial Modeling I, II (3:3:0) Prerequisites: MATH 554 and either MATH 351 or STAT 344. Two-semester sequence covering portions of the material corresponding to the Society of Actuaries Exam M, Casualty Actuary Society Exam 3, and Joint Board Exam EA1. The remaining material for these exams is covered in MATH 551 and 653. Topics include survival distribution and life tables, life insurance, life annuities, net premiums, net premium reserves, multiple life and multiple decrement models, pensions, insurance models including expense, and nonforfeiture benefits and cash values.
600 Special Topics in Mathematics (1–6:1–6:0) Mathematical workshops, special courses, or other projects.
601, 602 Analysis I, II for Teachers (3:2:1) Open to in-service teachers of mathematics at middle or secondary level. Others may enroll with permission of instructor. Background in mathematics desirable but not necessary. Some topics from college algebra will be reviewed in class, but thorough understanding of high school algebra and trigonometry expected. Develops continuous ideas of calculus with particular emphasis on concepts as opposed to computational aspects of calculus. Specific topics include decimal representation of real numbers, sequences, series, and limits; differentiation to find speed, slopes of curves, and tangents; integration to find volumes and distances and area under curves. Optimization problems including maximization of area and volume, and modeling of these concepts. Graphing techniques supported by theory of calculus and graphing utilities such as TI-83 calculator or computer software such as Maple.
604 Geometry for Teachers (3:2:1) Open to in-service teachers of mathematics at middle or secondary level. Others may enroll with permission of instructor. Background in mathematics desirable but not necessary. Covers standard topics from Euclidean geometry, and includes discussion of non-Euclidean geometries. Emphasizes informal and explorative approach to geometry, and makes use of geometry sketchpad. Other topics include geometric constructions, and role of proof in geometry.
605 Discrete/Finite Mathematics for Teachers (3:2:1) Open to in-service teachers of mathematics at middle or secondary level. Others may enroll with permission of instructor. Background in mathematics desirable but not necessary. Thorough understanding of high school algebra assumed. Discusses finite mathematics in juxtaposition to continuous ideas of calculus. Topics may consist of elementary counting and combinatorics including recursion and difference equations and their analogy to calculus; thorough discussion of probability and central measures of statistics; and graph theory and its connection to geometry.
607 Algebraic Structure for Teachers (3:2:1) Open to in-service teachers of mathematics at middle school level. Others may enroll with permission of instructor. Background in mathematics desirable but not necessary. Thorough understanding of high school algebra assumed. Expands on customary operations on integers and rationals to discuss systems that mimic these operations. Emphasizes multiplicative and additive inverses and their corresponding identities as they occur in other systems. Topics might include permutation groups, rigid transformations, groups of symmetry of the plane and connection to geometry, and matrices treated as linear transformations and connections to solutions of systems of equations.
608 Problem Solving in Mathematics (3:2:1) Open to in-service teachers of mathematics at middle school level. Others may enroll with permission of instructor. Background in mathematics or science desirable but not necessary. Assumes exposure to most of topics covered in MATH 601, 604, 605, and 607. Introduces variety of challenging mathematical problems appropriate for middle school student to analyze, and solving problems using mathematics learned in previous courses. Also asks students to search for such problems and orally present solutions. Specific topics might be any course listed as prerequisites.
619 Topics in Mathematical Logic (3:3:0) Special topics in foundations of mathematics not included in regular mathematics curriculum. May be repeated for credit.
621 Algebra I (3:3:0) Prerequisite: familiarity with basic properties of groups and rings, or permission of instructor. Groups, linear algebra, and matrix groups.
625/CSI 740 Numerical Linear Algebra (3:3:0) Prerequisite: computer literacy, including some programming experience. Theory and development of numerical algorithms for solving variety of matrix problems: linear systems, least squares problems, eigenvalue problems, and singular value decomposition. Direct and iterative method, analysis of sensitivity to rounding errors, and applications.
629 Topics in Algebra (3:3:0) Special topics in pure or applied algebra not covered in regular algebra sequence. May be repeated for credit.
631 Topology I: Topology of Metric Spaces (3:3:0) Prerequisite: MATH 315 or equivalent. Covers definition and basic examples of metric spaces, open and closed sets, subspaces and finite products, sequences and convergence, compactness and separability, continuous functions, uniform continuity, metric space C(X) and uniform convergence, and homotopy.
641 Combinatorics and Graph Theory (3:3:0) Prerequisite: MATH 321 or equivalent. Covers enumerative combinatorics, including partially ordered sets; Moebius inversion and generating functions; and major topics in graph theory such as graph coloring, Ramsey theory, and matching.
644 Convex and Discrete Geometry (3:3:0) Prerequisites: MATH 203 and 290, or equivalent. Basic properties of Euclidean space, convex sets and convex cones, convex hulls, extremal structure of convex sets, support and separation properties, polyhedra and polytopes, special classes of convex sets, Helly-type theorems, selected problems of discrete geometry.
653 Actuarial Modeling III (3:3:0) Prerequisite: MATH 351 or STAT 644 required. MATH 555 recommended but not required. Economics of insurance, individual risk models for short term, collective risk models for single period, collective risk models over an extended period, and applications of risk theory. Material included in this course corresponds to portions of the Society of Actuaries Exam M and Casualty Actuary Society Exam 3. The remaining material for these exams is covered in MATH 551, 555, and 556.
654 Construction and Evaluation of Actuarial Models (3:3:0) Prerequisite: MATH 556 or permission of instructor. Nature and properties of survival and loss models, methods of estimates from complete and incomplete data, tabular and parametric models, and practical issues in survival model estimation. Material included in this course corresponds to most of the Society of Actuaries Exam C and Casualty Actuary Society Exam 4.
655 Pension Valuation (3:3:0) Prerequisite: MATH 556, SOA Exam EA-1, or permission of instructor. Basic mathematics used in pension actuarial work without regard to pension law. Material included in this course corresponds to all of the Joint Board Exam EA-2A and portions of the Society of Actuaries Exam 8. This course cannot be counted toward the MS or PhD degree in mathematics.
661 Complex Analysis I (3:3:0) Topology of complex numbers, holomorphic functions, series, complex integration. Meromorphic, multivalued, and elliptic functions.
671 Fourier Analysis (3:3:0) Study of fundamental ideas in Fourier analysis. Topics include orthonormal systems, Fourier series, continuous and discrete Fourier transform theory, generalized functions, and introduction to spectral analysis. Uses applications to physical sciences, linear systems theory, and signal processing to integrate topics.
673 Dynamical Systems (3:3:0) Prerequisites: elementary courses in linear algebra and differential equations. Contemporary topics in nonlinear dynamical systems illustrated in mathematical models from physics, ecology, and population dynamics. Traditional qualitative analysis of difference and differential equations provides background for understanding chaotic behavior when it occurs in these models. Topics include stability theory, fractals, Lyapunov exponents, and chaotic attractors.
674 Stochastic Differential Equations (3:3:0) Prerequisites: MATH 214 and 351. Introduces stochastic calculus and differential equations. Includes Wiener process, Ito and Stratonovich integrals, Ito formula, martingales, diffusions, and applications. Simulations and numerical approximations of solutions.
675 Linear Analysis I (3:3:0) Prerequisite: MATH 315 or equivalent. Metric spaces, normed linear spaces, completeness, compactness, continuous (bounded) linear transformations, Banach spaces, Hilbert spaces, and orthogonal series.
677 Ordinary Differential Equations (3:3:0) Prerequisite: elementary differential equations course. Qualitative and quantitative theory of ordinary differential equations. Phase portrait analysis of linear and nonlinear systems, including classification of stable and unstable equilibrium states and periodic orbits. Poincare-Bendixson theorem, Lyapunov stability and Lyapunov functions, and bifurcation theory. Optional topics include averaging and perturbation methods, numerical solution techniques, and chaos.
678 Partial Differential Equations (3:3:0) Prerequisite: elementary differential equations course. Physical examples, characteristics, boundary value problems, integral transforms, and other topics, such as variational, perturbation and asymptotic methods.
679 Topics in Analysis (3:3:0) Special topics not covered in regular analysis sequence. May be repeated for credit.
680 Industrial Mathematics (3:3:0) Takes examples from industry and goes through complete solution process: formulation of mathematical model of problem; solution, possibly by numerical approximation; and interpretation and presentation of results. Emphasizes working in groups, relating mathematics to concrete situations, and communication and presentation skills.
682/OR 641 Linear Programming (3:3:0) Prerequisite: OR 541, or permission of instructor. Takes in-depth look at simplex method. Includes computational enhancements such as revised simplex method, sparse-matrix techniques, bounded variables and generalized upper bounds, and large-scale decomposition methods. Also includes computational complexity of simplex algorithm, and Khachian and Karmarkar algorithms.
683 Modern Optimization Theory (3:3:0) Introduces basic mathematical ideas and methods for solving linear and nonlinear programming problems, with emphasis on mathematical aspects of optimization theory. Reviews classical topics of linear programming, and covers recent developments in linear programming including interior point method. Considers basic results in nonlinear programming, including very recent developments in this field.
685 Numerical Analysis (3:3:0) Prerequisite: computer literacy, including some programming experience. Computational techniques for solving problems arising in science and engineering. Includes theoretical development as well as implementation, efficiency, and accuracy issues in using algorithms and interpreting results. Specific topics include linear and nonlinear systems of equations, polynomial interpolation, numerical integration, and introduction to numerical solution of differential equations.
686 Numerical Solutions of Differential Equations (3:3:0) Prerequisites: MATH 446 or 685, and elementary differential equations course. Finite difference methods for initial value problems, two-point boundary value problems, Poisson equation, heat equation, and first-order partial differential equations.
687 Variational Methods (3:3:0) Prerequisites: MATH 446 or 685, and elementary differential equations course. Weak formulation of partial differential equations, energy principles, Galerkin approximations, and finite element methods. Includes review and development of necessary analysis.
689 Topics in Applied Mathematics (3:3:0) Special topics in applied math not covered in the regular applied math sequence. May be repeated for credit.
697 Independent Reading and Research (1–6:0:0) In areas of importance, but with insufficient demand to justify a regular course, students may undertake a course of study under the supervision of a consenting faculty member. Written statement of the content of the course and a tentative reading list is normally submitted as part of the request for approval. Literature review, project report, or other written product is normally required. May be repeated as necessary.
721 Algebra II (3:3:0) Prerequisite: MATH 621. Rings, fields, Galois theory.
722 Algebraic Topology (3:3:0) Prerequisites: MATH 621 and 631, or equivalent. Covers simplices and simplicial complexes, cycles and boundaries, simplicial homology, homological algebra, homotopy and the fundamental group, cohomology.
723 Combinatorial Structures (3:3:0) Prerequisite: MATH 321 or equivalent. Studies structural properties of objects encountered in pure and applied combinatorics. Topics include partially ordered sets, codes, designs, matroids, buildings, symmetrical structures, permutation groups, and face lattices of polytopes.
724 Commutative Algebra (3:3:0) Prerequisite: MATH 621. Study of commutative rings and their ideals, and of modules over commutative rings and their homological properties. More specific topics include Noetherian rings, primary decomposition, completions, graded rings and dimension theory with applications to algebraic geometry.
732 Topology II: Set-Theoretic Topology (3:3:0) Prerequisites: MATH 631 or equivalent. Topics include review of basic set theory (including cardinal numbers products of sets, the Axiom of Choice), definition of topological spaces, bases for topological spaces, forming new topological spaces by taking subspace, quotients, and products, separation properties (Hausdorff, regular, Tychonoff, and normal spaces) compactness, the Lindelof property, separability, connectedness, continuity and homeomorphism, manifolds.
739 Topics in Differential Geometry and Topology (3:3:0) Prerequisite: MATH 631 or equivalent. Topics include geometry of curves and surfaces, curvature, isometries, the Gauss-Bonet theorem, geodesics, differential forms, manifolds, smooth maps, vector fields, the Euler characteristic, integration on manifolds, de Rham cohomology.
762 Complex Analysis II (3:3:0) Prerequisite: MATH 661. Harmonic functions, generalizations of the maximum principle, entire and meromorphic functions, analytic continuation, and the Riemann mapping theorem.
763 Functions of Several Complex Variables (3:3:0) Prerequisites: MATH 661 and 762, or equivalent preparation in one complex variable. Covers the important results for analytic functions in several variables, including analyticity in several variables and the differences between the theory of one and the theory of several complex variables.
772/CSI 746 Wavelet Theory (3:3:0) Prerequisite: MATH 315 or equivalent. Study of the theory and computational aspects of wavelets and the wavelet transform. Emphasizes computational aspects of wavelets, defining the Fast Wavelet Transform in one and two dimensions. Developing the appropriate numerical algorithms. Includes developing the theory of wavelet bases on the real line, discussing multi-resolution analysis, splines, time-frequency localization, and wavelet packets.
776 Linear Analysis II (3:3:0) Prerequisite: MATH 675. Lebesque measure and integration. Theory of Lp spaces with p between one and infinity on the real line. Theory of linear operators on Banach spaces, including the Hahn-Banach Theorem, Open Mapping Theorem, Closed Graph Theorem and the Uniform Boundedness Principle.
795 Graduate Seminar (1:1:0) Prerequisite: admission to PhD program in mathematical sciences. Mandatory for all PhD students. Weekly seminar graded on presentations and attendance. Faculty presentations on potential thesis topics and presentations by students.
799 Thesis (1–6:0:0) Original or compilatory work evaluated by committee of three faculty members. Graded S/NC.
800 Studies for the Doctor of Philosophy in Education (variable credit) Prerequisite: admission to PhD in education program to study in mathematical sciences. Program of studies designed by student’s discipline director and approved by student’s doctoral committee, which brings the student to participate in current research of discipline director and results in paper reporting the original contributions of student. Enrollment may be repeated.
998 PhD Thesis Proposal (1:1:0) Prerequisite: passing grade on qualifying exam. Work on research proposal that forms basis for doctoral dissertation. May be repeated for credit. No more than 24 credit hours of 998 and 999 may be applied to doctoral degree requirements. Graded S/NC.
999 PhD Thesis Credits (1:1:0) Prerequisite: advancement to candidacy. Formal record of commitment to doctoral dissertation research under the direction of a faculty member. May be repeated for credit. No more than 24 credit hours of 998 and 999 may be applied to doctoral degree requirements. Graded S/NC.