Quantum Information Science II
Quantum Information Science II (edX | MIT)
Already know something about quantum mechanics, quantum bits and quantum logic gates, but want to design new quantum algorithms, and explore multi-party quantum protocols? This is the course for you!
In this advanced graduate physics course on quantum computation and quantum information, we will cover:
The formalism of quantum errors (density matrices, operator sum representations)
Quantum error correction codes (stabilizers, graph states)
Fault-tolerant quantum computation (normalizers, Clifford group operations, the Gottesman-Knill Theorem)
Models of quantum computation (teleportation, cluster, measurement-based)
Quantum Fourier transform-based algorithms (factoring, simulation)
Quantum communication (noiseless and noisy coding)
Quantum protocols (games, communication complexity)
Research problem ideas are presented along the journey.
Formalisms for describing errors in quantum states and systems
Quantum error correction theory
Fault-tolerant quantum procedure constructions
Models of quantum computation beyond gates
Structures of exponentially-fast quantum algorithms
Multi-party quantum communication protocols
Isaac Chuang Professor of Electrical Engineering and Computer Science, and Professor of Physics MIT
Editor's note:This post was originally published on BoffoSocko.com