Quantum algorithm for Clifford multiplication
Abstract
Given two dense multivectors of the Clifford algebra C(V, Q) with N=2p+q coefficients, the fastest known classical algorithms compute their geometric product in O(Nω/2) arithmetic operations, where ω denotes the matrix multiplication exponent. I show that, under amplitude encoding, a quantum computer executes the geometric product in O(polylog N) time, using logarithmic space with sublogarithmic circuit depth. This exponential speedup establishes Clifford multiplication as a quantum primitive, providing an efficient computational foundation for quantum geometric algorithms and relativistic simulations.
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