Introduction to Quantum Information Processing Duration 43:39 Duration 25:29 Duration 37:12 Cutout for slide 11: [pdf] Duration 19:40 Duration 28:36 Duration 32:18 Duration 31:05 Slide 4: a proof of the classical lower bound is in section 6.2.1 of the course lecture notes [Part 2: Quantum algorithms] Duration 38:44 Supplementary: [pdf] Duration 17:00 Duration 26:21 Duration 37:55 Supplementary: [pdf] Duration 28:52 Duration 12:57 Duration 30:01 Duration 32:39 Duration 25:54 Duration 22:56 Duration 27:13 Duration 28:39 Duration 26:16 Duration 22:37 Duration 28:36 Slides: [pdf]
QIC 710, CS 768, CO 681, PHYS 767, AMATH 871, PMATH 871 (Fall 2023)
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Video lectures (from 2020)
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Part 1: A primer for beginners
Lecture 1: What is a qubit?
Lecture 2: Systems with multiple qubits
Lecture 3: Superdense coding and measurements involving multiple qubits
Lecture 4: Teleportation and the question of copying quantum states
Part 2: Quantum algorithms
Lecture 5: Quantum circuits and classical circuits as algorithms
Lecture 6: Simple quantum algorithms in the black box model
Lecture 7: Simon's problem
Lecture 8: The discrete log problem
Lecture 9: Quantum Fourier transform
Lecture 10: The phase estimation problem
Lecture 11: Algorithms for order-finding and factoring
Lecture 12: Grover's search algorithm
Lecture 13: Optimality of Grover's search algorithm
Part 3: Quantum information theory
Lecture 14: Quantum states as density matrices
Lecture 15: State transitions via Kraus operators
Lecture 16: Stinespring form vs. Kraus form
Lecture 17: Distance measures between states
Lecture 18: Simple quantum error-correcting codes
Lecture 19: Calderbank-Shor-Steane codes
Lecture 20: Nonlocality
Lecture 21: Bell/CHSH inequality
Part 4: Quantum cryptography
Lecture 23: The BB84 key distribution scheme