On encoded quantum gate generation by iterative Lyapunov-based methods

TL;DR

This paper introduces a unified iterative Lyapunov-based method for generating encoded quantum gates in higher-dimensional quantum systems, applicable to various quantum control problems including state preparation and full gate synthesis.

Contribution

It generalizes the Reference Input Generation Algorithm (RIGA) for encoded quantum gate generation, unifying multiple quantum control problems within a single framework using Lyapunov functions.

Findings

Effective control algorithms demonstrated on coupled transmon-qubits.

Successful application to cavity mode and chain of qubits with N=10.

Potential for practical quantum gate synthesis in complex systems.

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 $\bar n$ of the quantum gate to be synthesized. Given two orthonormal subsets $\mathbb{E} = \{e_1, e_2, \ldots, e_{\bar n}\}$ and $\mathbb F = \{f_1, f_2, \ldots, f_{\bar n}\}$ of $\mathbb{C}^n$, the problem of encoded quantum gate generation consists in obtaining an open loop control law defined in an interval $[0, T_f]$ in a way that all initial states $e_i$ are steered to $\exp(\jmath \phi) f_i, i=1,2, \ldots ,\bar n$ up to some desired precision and to some global phase $\phi \in \mathbb{R}$. This problem includes the classical (full) quantum gate generation problem, when $\bar n = n$, the state preparation problem, when $\bar n = 1$, and finally the encoded gate generation when $ 1 < \bar n < n$. Hence, three problems are unified here within a unique common approach. The \emph{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 $N=10$.