On encoded quantum gate generation by iterative Lyapunov-based methods

Abstract

The problem of encoded quantum gate generation is studied in this paper. The idea is to consider a quantum system of higher dimension n than the dimension n of the quantum gate to be synthesized. Given two orthonormal subsets E = \e1, e2, …, e n\ and F = \f1, f2, …, f n\ of Cn, the problem of encoded quantum gate generation consists in obtaining an open loop control law defined in an interval [0, Tf] in a way that all initial states ei are steered to ( φ) fi, i=1,2, … , n up to some desired precision and to some global phase φ ∈ R. This problem includes the classical (full) quantum gate generation problem, when n = n, the state preparation problem, when n = 1, and finally the encoded gate generation when 1 < n < n. Hence, three problems are unified here within a unique common approach. The Reference Input Generation Algorithm (RIGA) is generalized in this work for considering the encoded gate generation problem for closed quantum systems. A suitable Lyapunov function is derived from the orthogonal projector on the support of the encoded gate. Three case-studies of physical interest indicate the potential interest of such numerical algorithm: two coupled transmon-qubits, a cavity mode coupled to a transmon-qubit, and a chain of N qubits, including a large dimensional case for which N=10.