A Lifting Theorem for Hybrid Classical-Quantum Communication Complexity

Abstract

We investigates a model of hybrid classical-quantum communication complexity, in which two parties first exchange classical messages and subsequently communicate using quantum messages. We study the trade-off between the classical and quantum communication for composed functions of the form f Gn, where f:\0,1\n\1\ and G is an inner product function of ( n) bits. To prove the trade-off, we establish a novel lifting theorem for hybrid communication complexity. This theorem unifies two previously separate lifting paradigms: the query-to-communication lifting framework for classical communication complexity and the approximate-degree-to-generalized-discrepancy lifting methods for quantum communication complexity. Our hybrid lifting theorem therefore offers a new framework for proving lower bounds in hybrid classical-quantum communication models. As a corollary, we show that any hybrid protocol communicating c classical bits followed by q qubits to compute f Gn must satisfy c+q2=(\deg(f),bs(f)\· n), where deg(f) is the degree of f and bs(f) is the block sensitivity of f. For read-once formula f, this yields an almost tight trade-off: either they have to exchange (n· n) classical bits or ( n· n) qubits, showing that classical pre-processing cannot significantly reduce the quantum communication required. To the best of our knowledge, this is the first non-trivial trade-off between classical and quantum communication in hybrid two-way communication complexity.

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