Abstract :
We present a new variant of the quantum adversary method, a method for proving lower bounds on the quantum query complexity of a function. Adversary methods work as follows: one defines a progress function based on the state of the algorithm, and shows that for a successful algorithm there is a large gap between the initial and final value of the progress, and furthermore that the progress function cannot change by much with a single query. All known variants upper-bound the difference of the progress function, whereas our new variant upper-bounds the ratio and that is why we coin it the multiplicative adversary. Our new method is rooted in the quantum lower-bound method by Ambainis (2005, 2006), based on the analysis of eigenspaces of the density matrix. Ambainis´s method is technically very complicated, it lacks intuition, and it only works for symmetric functions. Our method fits well into the adversary framework, has a simple formulation in terms of common block-diagonalization of two operators, and works for all functions. Furthermore, we prove an unconditional strong direct product theorem for the multiplicative quantum adversary bound.
Keywords :
computational complexity; eigenvalues and eigenfunctions; mathematical operators; matrix algebra; quantum computing; common block-diagonalization; density matrix; direct product theorem; eigenspace analysis; multiplicative quantum adversary bound; progress function; quantum lower-bound method; quantum query complexity; Computational complexity; History; Polynomials; Quantum computing; Quantum entanglement; Quantum mechanics; Registers; Symmetric matrices; combinatorial matrices; direct product theorems; multiplicative adversary; quantum adversary method; quantum query lower bounds;
