Query Learning Nearly Pauli Sparse Unitaries in Diamond Distance
Abstract
We study the problem of learning nearly (s,ε)-sparse unitaries, meaning that the Pauli spectrum is concentrated on at most s components with at most ε residual mass in Pauli 1-norm. This class generalizes well-studied families, including sparse unitaries, quantum k-juntas, 2k-Pauli dimensional channels, and compositions of depth O( n) circuits with near-Clifford circuits. Given query access to an unknown nearly sparse unitary U, our goal is to efficiently (both in time and query complexity) construct a quantum channel that is close in diamond distance to U. We design a learning algorithm achieving this guarantee using O(s6/ε4) forward queries to U, and running time polynomial in relevant parameters. A key contribution is an efficient quantum algorithm that, given query access to an arbitrary unknown unitary U, estimates all Pauli coefficients (up to a shared global phase) whose magnitude exceeds a given threshold θ, extending existing sparse recovery techniques to general unitaries. We also study the broader class of unitaries with bounded Pauli 1-norm. For that class, we prove an exponential query lower bound (2n/2). We introduce a more relaxed accuracy metric which is the diamond distance restricted to a set of input states. Then, we show that, under this metric, unitaries with Pauli 1-norm uniformly bounded by L1 are learnable with O(L18/ε16).
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