Projects 2022-23
Image source: Qiskit
QBasics
Summary: A ground level introduction to Qiskit and the principles of quantum computing. The group will start with math foundations such as Hilbert spaces and information theory, then progress to using Qiskit to represent quantum circuits. The endpoint for this project is preparation for the Qiskit developer exam.
Structure: Biweekly Lecture / Discussion format with suggested readings and Qiskit exercises in between meetings.
Project Leaders: Ben McDonough and Mason Abrell
Graduate Mentor: Katie Chang
Image source: Wikimedia
Superconducting
Circuits
Summary: Introduction to quantum hardware platforms and experimental methods. Transmons, dispersive readout, pulse engineering, cavity QED. Particular focus on the coupling between real world implementations and theory.
Structure: Biweekly meetings. Papers, etc will be provided as suggested readings in between meetings.
Project Leader: Alex Deters
Graduate Mentor: Harsh Babla
Image source: Quantum Error Correction by Joschka Roffe
Error Correcting Codes
Summary: Get a broad overview of quantum error correction, learn some basic classical and quantum error correcting algorithms, and eventually work up to understanding the error correcting research happening at Yale!
Structure: Biweekly (once every two weeks) meetings that are in the structure of a lecture/discussion. Between these meetings, there will be suggested readings of papers and textbooks that we might find interesting! Towards the end of the semester, we hope to get some guest speakers to come in and talk to us about their research.
Project Leader: Pranav Parakh
Graduate Mentor: Kaavya Sahay
Image source: Wikimedia
Efficient Gradient Estimation
Summary: Research a novel noise-aware gradient estimation model for optimization problems on near-term quantum computers.
Project Leader: Dikshant Dulal
Background Level: Intermediate
Source: Ben Foxman
Hidden Subgroup Problems
Summary: Learn about Hidden Subgroup Problems (HSP) which are a framework describing most of the common quantum algorithms giving exponential speedups (think Shor’s). This project will investigate quantum algorithms for the most general form of the HSP - a problem which quantum computers are conjectured to be able to solve, but many important subclasses of HSP remain unsolved in quantum polynomial time.
Project Leader: Ben Foxman
Background Level: Advanced. Requires background in group theory + more advanced quantum algorithm concepts (weak/strong fourier sampling, oracles).
Source: Jeb Cui
C2QA Testing and Tutorials
Summary: A novel package for extending Qiskit to coupled bosonic-qubit systems was recently (in the past week or so!) published, with several authors at Yale. We would have a unique chance to be the first students to learn how to use this package. We could provide feedback and bug testing to the developers. The culmination of the project will be a series of tutorial notebooks on the C2QA package.
Project Leader: Ben McDonough
Background Level: Intermediate, but can be beginner if you are willing to do a bit more reading! Some background in Python will probably be necessary.
Format: In-person meetings weekly for half an hour.
Graduate Mentor: Kevin Smith (one of the authors)