Learning fermionic linear optics with Heisenberg scaling and physical operations

Abstract

We revisit the problem of learning fermionic linear optics (FLO), also known as fermionic Gaussian unitaries. Given black-box query access to an unknown FLO, previous proposals required O(n5 / 2) queries, where n is the system size and is the error in diamond distance. These algorithms also use unphysical operations (i.e., violating fermionic superselection rules) and/or n auxiliary modes to prepare Choi states of the FLO. In this work, we establish efficient and experimentally friendly protocols that obey superselection, use minimal ancilla (at most 1 extra mode), and exhibit improved dependence on both parameters n and . For arbitrary (active) FLOs this algorithm makes at most O(n4 / ) queries, while for number-conserving (passive) FLOs we show that O(n3 / ) queries suffice. The complexity of the active case can be further reduced to O(n3 / ) at the cost of using n ancilla. This marks the first FLO learning algorithm that attains Heisenberg scaling in precision. As a side result, we also demonstrate an improved copy complexity of O(n η2 / 2) for time-efficient state tomography of η-particle Slater determinants in trace distance, which may be of independent interest.