Principal eigenstate classical shadows
Abstract
Given many copies of an unknown quantum state , we consider the task of learning a classical description of its principal eigenstate. Namely, assuming that has an eigenstate |φ with (unknown) eigenvalue λ > 1/2, the goal is to learn a (classical shadows style) classical description of |φ which can later be used to estimate expectation values φ |O| φ for any O in some class of observables. We consider the sample-complexity setting in which generating a copy of is expensive, but joint measurements on many copies of the state are possible. We present a protocol for this task scaling with the principal eigenvalue λ and show that it is optimal within a space of natural approaches, e.g., applying quantum state purification followed by a single-copy classical shadows scheme. Furthermore, when λ is sufficiently close to 1, the performance of our algorithm is optimal--matching the sample complexity for pure state classical shadows.
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