Efficient quantum tomography

Abstract

In the quantum state tomography problem, one wishes to estimate an unknown d-dimensional mixed quantum state , given few copies. We show that O(d/ε) copies suffice to obtain an estimate that satisfies \| - \|F2 ≤ ε (with high probability). An immediate consequence is that O(rank() · d/ε2) ≤ O(d2/ε2) copies suffice to obtain an ε-accurate estimate in the standard trace distance. This improves on the best known prior result of O(d3/ε2) copies for full tomography, and even on the best known prior result of O(d2(d/ε)/ε2) copies for spectrum estimation. Our result is the first to show that nontrivial tomography can be obtained using a number of copies that is just linear in the dimension. Next, we generalize these results to show that one can perform efficient principal component analysis on . Our main result is that O(k d/ε2) copies suffice to output a rank-k approximation whose trace distance error is at most ε more than that of the best rank-k approximator to . This subsumes our above trace distance tomography result and generalizes it to the case when is not guaranteed to be of low rank. A key part of the proof is the analogous generalization of our spectrum-learning results: we show that the largest k eigenvalues of can be estimated to trace-distance error ε using O(k2/ε2) copies. In turn, this result relies on a new coupling theorem concerning the Robinson-Schensted-Knuth algorithm that should be of independent combinatorial interest.