A Method for Generating All Uniform $\pi$-Pulse Sequences Used in Deterministic Dynamical Decoupling

TL;DR

This paper introduces a systematic framework called concatenated-projection dynamical decoupling (CPDD) for generating all uniform $$-pulse sequences used in dynamical decoupling, enabling high-order decoherence suppression.

Contribution

The paper develops a new CPDD framework that systematically constructs uniform $$-pulse sequences and unifies existing schemes, providing insights for designing improved sequences.

Findings

All known uniform $$-pulse sequences fit into the CPDD framework.

CPDD enables systematic construction of sequences with arbitrary high suppression order.

The framework offers new insights into designing better dynamical decoupling sequences.

Abstract

Dynamical decoupling has been actively investigated since Viola first suggested using a pulse sequence to protect a qubit from decoherence. Since then, many schemes of dynamical decoupling have been proposed to achieve high-order suppression, both analytically and numerically. However, hitherto, there has not been a systematic framework to understand all existing uniform $\pi$-pulse dynamical decoupling schemes. In this report, we use the projection pulse sequences as basic building blocks and concatenation as a way to combine them. We derived a new concatenated-projection dynamical decoupling (CPDD), a framework in which we can systematically construct pulse sequences to achieve arbitrary high suppression order. All previously known uniform dynamical decoupling sequences using $\pi$ pulse can be fit into this framework. Understanding uniform dynamical decoupling as successive projections on the Hamiltonian will also give insights on how to invent new ways to construct better pulse sequences.