Lower Bounds for Learning Hamiltonians from Time Evolution

Abstract

Learning about a Hamiltonian H from its time evolution e-iHt is a fundamental task in quantum science. A flurry of recent work has developed powerful new algorithms with provable guarantees for this task, for a variety of natural settings. Despite this, relatively little is known about lower bounds for learning Hamiltonians. In particular, in the natural setting where we assume H is a k-local Hamiltonian on n qubits, all existing algorithms require total evolution time at least n (k) to learn the parameters of H, and it remained open whether one could obtain even faster algorithms -- or at the very least, if one could obtain better runtimes for simpler tasks, such as estimating a single designated coefficient of the Hamiltonian. In this work we show the answer is essentially no, by obtaining strong lower bounds for these problems. We find that not only do k-local Hamiltonians require n(k) time evolution or interactions to learn, but also that in several senses, learning anything about a Hamiltonian is just as hard as learning everything. In particular, we find the same n(k) lower bound holds for learning a single coefficient of a k-local Hamiltonian H, even if the rest of H is already known. We also show an n(k) lower bound for the task of effective Hamiltonian learning, where one seeks only to learn a unitary that approximately implements time evolution of H. Several related lower bounds, such as for general sparse (but not necessarily local) H are also given. On the technical side, we make a new connection between Hamiltonian learning lower bounds and the analysis of Boolean functions, where we introduce a novel extremal property that may be of independent interest.