Quantum Signal Processing and Quantum Singular Value Transformation on U(N)
Abstract
Quantum signal processing and quantum singular value transformation are powerful tools to implement polynomial transformations of block-encoded matrices on quantum computers, and has achieved asymptotically optimal complexity in many prominent quantum algorithms. We propose a framework of quantum signal processing and quantum singular value transformation on U(N), which realizes multiple polynomials simultaneously from a block-encoded input, as a generalization of those on U(2) in the original frameworks. We provide a comprehensive characterization of achievable polynomial matrices and give recursive algorithms to construct the quantum circuits that realize desired polynomial transformations. As three example applications, we propose a framework to realize bi-variate polynomial functions, demonstrate N-interval decision achieving O(d) query complexity with a 2 N improvement over iterative U(2)-QSP requiring O(d2 N) queries, and present a quantum amplitude estimation algorithm achieving the Heisenberg limit without adaptive measurements.
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