MATH 531: Introduction to Real Analysis
Basic topology of Euclidean spaces, continuity and differentiation of functions on a single variable, Riemann-Stieltjes integration, and convergence of sequences and series.

MATH 533: Advanced Multivariate Calculus
Differential and integral calculus in Euclidean spaces, implicit and inverse function theorems, differential forms and Stokes' theorem.

MATH 551: Advanced Linear Algebra
This course includes a systematic review of the material usually considered in MATH 351 such as matrices, determinants, systems of linear equations, vector spaces, and linear operators. However, these concepts will be developed over general fields and more theoretical aspects will be emphasized. The centerpiece of the course is the theory of canonical forms, including the Jordan canonical form and the rational canonical form. Another important topic is general bilinear forms on vector spaces. Time permitting, some applications of linear algebra in differential equations, probability, etc. are considered.

MATH 552: Introduction to Abstract Algebra
Focuses on structural properties of basic algebraic systems such as groups, rings and fields. A special emphasis is made on polynomials in one and several variables, including irreducible polynomials, unique factorization and symmetric polynomials. Time permitting, such topics as group representations or algebras over a field may be included.

In the second year and beyond, students choose from more specialized courses. Ph.D. students past the third year are mainly involved in seminars and independent research. In seminars, students have the opportunity to lecture on published work or their own research, gaining experience in exposition of advanced mathematical topics. For descriptions of the remaining graduate courses, see the Graduate School's catalogue.


Our standard Ph.D. program for a typical student is roughly as follows:

First academic year: While supported by a teaching assistantship (e.g., running two hours per week of discussion sections of calculus), students take core courses in algebra, analysis, and topology, providing the foundation for all further graduate work.

Second academic year: Teaching responsibility usually involves four contact hours per week, typically running one discussion hour and meeting one's own class of a 100-level math course for three hours. Students continue to take a range of basic courses, but chosen with potential areas of specialization in mind. General Examinations preferably are passed either just before this year starts, or as soon as possible thereafter, and the Second-Year Proficiency Examination is taken at the end of the second academic year.

Third academic year: Students should be integrating themselves into the research life of the department through advanced courses and participation in seminars. Often students are doing independent reading toward acquiring the specialized background needed for doing research, guided by a potential thesis advisor.

Fourth academic year and beyond: Students should be reading the literature related to a potential thesis topic, followed by jumping into dissertation research. (We view five or six years as the normal time needed to complete graduate work.)

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