Mathematical Foundations for Quantum Computing

Detailed study of complex numbers including arithmetic operations, geometric interpretations, Euler's formula, complex exponentials, and their applications in quantum wave functions and quantum state evolution.

Comprehensive coverage of probability theory with emphasis on discrete and continuous distributions, conditional probability, expectation values, variance, and statistical inference as applied to quantum measurement statistics.

Detailed study of tensor products, tensor algebra, composite quantum systems, separable and entangled states, and mathematical representation of multi-qubit quantum gates and circuits.

Introduction to group theory covering symmetry groups, group operations, representations, character tables, and applications to quantum mechanical systems and quantum algorithm design.

Statistical methods for quantum data analysis including hypothesis testing, confidence intervals, error propagation, maximum likelihood estimation, and statistical inference from quantum measurement outcomes.

Comprehensive coverage of discrete mathematics topics relevant to quantum computing including Boolean algebra, propositional logic, combinatorial optimization, graph algorithms, and number theoretic functions used in quantum algorithms.

Comprehensive coverage of linear algebra concepts including vector spaces, matrix multiplication, determinants, eigenvalue decomposition, singular value decomposition, and unitary matrices with specific applications to quantum computing.