### Courses

### Winter 2020 Courses

### Spring 2019 Courses

### Fall 2019 Courses

### Fall 2018 Courses

Usual Meeting Time: Every Wednesday from 10:30am to 12:00pm

### Winter 2018 Courses

### Fall 2017 Courses

Usual Meeting Time: 4-5:15

### Spring 2017 Courses

### Winter 2017 Courses

### Fall 2016 Courses

Usual Meeting Time: Wednesdays, 2-3:30

Usual Meeting Time: tbd; meeting at Perimeter

The Blue Waters project at the University of Illinois is pleased to announce the offering of a graduate course Algorithmic Techniques for Scalable Many-core Computing that will be offered as a collaborative, online course for multiple participating institutions. We are seeking other university partners that are interested in offering the course for credit to their students. The course includes online video lectures, quizzes, and homework assignments with access to free accounts on the Blue Waters system.

** Course Goals**: To master commonly used algorithm techniques and computational thinking skills for scalable, many-core/many-thread programming

- Many-core hardware limitations and constraints
- Desirable and undesirable computation patterns
- Practical algorithm techniques to convert undesirable computation patterns into desirable ones

### Spring 2016 Courses

### Winter 2016 Courses

Usual Meeting Time: Every Monday and Friday from 1:30 - 3:00 pm

### Fall 2015 Courses

Usual Meeting Time: Thursdays at 4pm

Usual Meeting Time: Mondays and Fridays 1:30pm - 3:00pm

### Spring 2015 Courses

In relativistic quantum information (RQI) we study quantum information in relativistic systems to obtain more insights to both quantum and gravitational physics on the one hand, and to find new ideas for quantum information processing on the other. One of the popular models in RQI is the Unruh-DeWitt (UD) detector theory, in which localized objects, called detectors, are coupled to and moving in relativistc quantum fields. In this mini-course I will discuss the UD detector theory in detail, mainly on the nonperturbative methods and their applications to RQI.

In these lectures, we will study the bosonic theory of higher-spin gravity in four dimensions. After discussing the reasons for interest in the theory, we will focus on the equations of motion and their content. We will aim to construct the equations from the ground up in a motivated way. The logical order will differ somewhat from standard introductions. As preliminaries, we will discuss the geometry of spinors and twistors in (anti) de Sitter space, along with various viewpoints on free massless fields with arbitrary spin. An ulterior goal of the lectures is to introduce a new version of the theory (arXiv:1502.06685), formulated on a fixed (A)dS background.