Lecture
Quantum Circuits: Model and Computation
Related lectures (64)
Quantum Computation Delegation
Explores fully classical qubits, blind quantum computing, and verifiability in quantum delegation protocols.
Quantum Circuits: Models and Approximations
Explores quantum circuit modeling, approximations, unitary matrices, and measurement operations.
Quantum Computing: Introduction
Covers quantum computing basics, quantum algorithms, error correction, and quantum bit manipulation.
Quantum Principles
Covers the fundamental principles of quantum computing and unitary evolution in quantum systems.
Quantum Computation Delegation
Covers the concept of quantum computation delegation and the relationship between MIP and RE, addressing common FAQs and discussing helpful materials and interactions with quantum devices.
Quantum circuit model of computation
Covers the Cincent Model of Deutsch for Quantum Computation, focusing on input representation, Hilbert space, and unitary evolution.
Simon Problem 4: Quantum State and Complexity Analysis
Explores the Simon Problem 4, analyzing quantum states and algorithm complexity.
Quantum Entanglement
Explores quantum entanglement, Bell inequalities, and self-testing in quantum systems.
Shor Algorithm: Quantum Factorization
Explores the Shor algorithm for quantum factorization and its application in finding function periods.
Linear Quantum Calculus in Dirac Notation
Covers linear algebra in Dirac notation, emphasizing the scalar product and density product in quantum computations.