2026-2027 Special Course Offerings
(Subject to change, check the time schedule for most current information.)
Undergraduate Special Topics
- Spring 2027
Spring 2027, Math 480A: Computational Algebraic Geometry
Polynomial equations and their solutions are fundamental objects in mathematics and appear across a wide range of applications. As in linear algebra, solutions to equations can be understood geometrically using tools from algebra. The solution sets of nonlinear equations in multiple variables have more interesting geometry and require us to develop new tools. In this class, we will learn how to understand and work with polynomial systems of equations using a mix of algebra, geometry, and algorithms and explore some real-world applications, such as to robotics and computer vision. This class is open to everyone who knows linear algebra and is familiar with mathematical proofs.
Prerequisite: a minimum grade of 2.0 in either MATH 334, or both MATH 208 and MATH 300.
Form opens 9:00am (Pacific Time) FEB 12, 2026 MATH 380 Registration Request Form
Spring 2027, Math 336/480C: Functional Analysis
TBD
Spring 2027, Math 480B: Graphs and Networks
A fundamental question in topology is the following: given two topological spaces
X and Y , how can one determine if there is an equivalence X ∼= Y ? One way to probe this
question is to study algebraic invariants of X and Y . For example, there is an invariant called
the fundamental group of a space, denoted by π1(−), and if π1(X)̸ ∼= π1(Y ), then in fact X̸ ∼= Y .
However, rather than merely assigning algebraic invariants, we can also study nice properties of the
spaces themselves. For example, if one can show that a continuous function ∗ → X is a cofibration,
then in fact ∗ ∼= X. These two perspectives, of using algebraic invariants to study spaces and
exhibiting properties of spaces which are invariant, combine together to create homotopy theory.
This course will be an introduction to the methods used in homotopy theory. We will study
algebraic invariants of spaces called homotopy groups and learn basic tools for calculation. Along
the way, we will develop ways to treat topological spaces themselves as a more algebraic gadget,
with an eye towards stable homotopy theory. Towards this goal, we will introduce a language known
as category theory that will allow us to pass between and directly compare topology and algebra.
This course will end with a final presentation on a topic of the your choice.
Prerequisites: MATH 441 or instructor permission.
Form opens 9:00am (Pacific Time) FEB 12, 2026 MATH 480B Registration Request Form
Graduate Special Topics 2026-2027
NOTE: courses are restricted to current Mathematics graduate students or those who have completed a minimum of three 500-level core math courses. If you have questions about this enrollment requirement visit our page about registering for 500-level courses.
- Autumn 2026
- Winter 2027
- 582 A: Alper - Stacks
- 582 B: Yuan - Theory of Linear and Nonlinear Second Order Elliptic Equations
- 582 C: Liu, G - Modern Matroid Theory
- 582 D: Pstragowski - Motivic Cohomology
- Spring 2027
581 C: Uhlmann - Introduction to Inverse Problems and PDE
Introduction to Inverse Problems and PDE
This is an introductory course to inverse problems for partial differential equations (PDE). In these problems one attempts to determine the coefficient or coefficients of a PDE by making some measurements of the solutions .
A typical example is when the measurements are made at the boundary of some domain.. Inverse problems have applications in many fields, like medical imaging, physics geophysics, material science, biology, etc.
No previous knowledge of PDE or inverse problems is necessary. We will develop both in the class.
Prerequisite. One can take Math 526 concurrently.
582 A: Alper- Stacks
We will introduce the foundations of stacks with applications to moduli problems. We will discuss topological and differentiable stacks, but the primary focus will be on algebraic stacks and their use to study moduli problems in algebraic geometry.
Prerequisites: Scheme theory (recommended)
582 B: Yuan - Theory of Linear and Nonlinear Second Order Elliptic Equations
Linear Theory: Solvability, a priori estimates, Schauder and Calderon-Zygmund estimates, and regularity
Nonlinear Theory: De Giorgi-Nash-Moser theory for divergence equations (eg. minimal surface equation), Krylov-Safonov theory for nondivergence equations (eg. Monge-Ampere equation [potential equation for maximal gradient graphs/optimal transport], special Lagrangian equation [potential equation for minimal gradient graphs], Bellman equation, and Isaacs equation [optimal stochastic control equations]).
Contents: Harmonic functions (properties), Schauder for △, Weighted norm, solvability for Laplace, Boundary Schauder, L^{p} for △, Energy method, capacity, Poincare, Soblev, W^{1,2} or H¹ space, trace; De Giorgi/Nash, Harnack, Quick applications of Harnack, Minimal surface equations, Viscosity solutions to Nondivergence equations, Alexandrov maximum principle, Krylov-Safonov, Uniqueness and Existence of viscosity solutions, C^{1,α} regularity, C^{2,α} regularity for convex equations, Monge-Ampere and special Lagrangian equations, Bellman equation, and Isaacs equation.
Prerequisites: Advanced calculus/Real Analysis (No previous PDE knowledge is required)
582 C: Liu, G - Modern Matroid Theory
This class will cover matroid theory focusing on developments from the last decades and connections to other areas of mathematics, such as convex geometry and algebraic geometry. Possible topics include the polyhedral perspective on matroid theory, log-concavity inequalities, and permutohedral varieties.
Prerequisites: linear algebra and abstract algebra
582 D: Pstragowski - Motivic Cohomology
This course would be an introduction to motivic cohomology as constructed by Voevodsky. This is a cohomology theory of smooth schemes obtained by looking at algebraic cycles and the ways they intersect, and it is closely related to algebraic K-theory and special values of L-functions. This course will be a gentle introduction to this circle of ideas, assuming basic familiarity with algebraic geometry and homological algebra.
583 A: Rothvoss - Lattices
A lattice is discrete subgroup of R^n. Lattices are fundamental objects in discrete math with
a rich set of applications to theoretical computer science, optimization and cryptography.
We will see the following in this course:
* Introduction to lattices
* Algorithms for the Closest Vector problem
* The Transference Theorems of Banaszczyk
* Khintchine's Flatness Theorem
* Lenstra's algorithm for Integer programming in fixed dimension
* Lattice problems in NP intersected coNP
* The Reverse Minkowski Theorem
* Subspace flatness and the conjecture of Kannan and Lovasz
Prerequisites: A good understanding of convex geometry, probability and algorithms will be very helpful.
583 B: Zhang - Algebraic Operads
We will cover some basics about algebraic operads, definitions, examples, Koszul duality, and quotient operads. Reference book: ``Algebraic Operads'' by Jean-Louis Loday and Bruno Vallette.