Trotter24: A precision-guaranteed adaptive stepsize Trotterization for Hamiltonian simulations

Choosing an optimal time step $\delta t$ is crucial for an efficient Hamiltonian simulation based on Trotterization but difficult due to the complex structure of the Trotter error. Here we develop a method measuring the Trotter error by combining the second- and fourth-order Trotterizations rather than consulting with mathematical error bounds. Implementing this method, we construct an algorithm, which we name Trotter24, for adaptively using almost the largest stepsize $\delta t$, which keeps quantum circuits shallowest, within an error tolerance $\epsilon$ preset for our purpose. Trotter24 applies to generic Hamiltonians, including time-dependent ones, and can be generalized to any orders of Trotterization. Benchmarking it in a quantum spin chain, we find the adaptively chosen $\delta t$ to be about ten times larger than that inferred from known upper bounds of Trotter errors. Trotter24 allows us to keep the quantum circuit thus shallower within the error tolerance in exchange for paying the cost of measurements.