α>(ε) = α<(ε) For The Margolus-Levitin Quantum Speed Limit Bound

Abstract

The Margolus-Levitin (ML) bound says that for any time-independent Hamiltonian, the time needed to evolve from one quantum state to another is at least π α(ε) / (2 E-E0 ), where E-E0 is the expected energy of the system relative to the ground state of the Hamiltonian and α(ε) is a function of the fidelity ε between the two state. For a long time, only a upper bound α>(ε) and lower bound α<(ε) are known although they agree up to at least seven significant figures. Lately, H\"ornedal and S\"onnerborn proved an analytical expression for α(ε), fully classified systems whose evolution times saturate the ML bound, and gave this bound a symplectic-geometric interpretation. Here I solve the same problem through an elementary proof of the ML bound. By explicitly finding all the states that saturate the ML bound, I show that α>(ε) is indeed equal to α<(ε). More importantly, I point out a numerical stability issue in computing α>(ε) and report a simple way to evaluate it efficiently and accurately.