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Main Author: Zhang, Xiao-Ming
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.02782
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author Zhang, Xiao-Ming
author_facet Zhang, Xiao-Ming
contents As standard data loading processes, quantum state preparation and block-encoding are critical and necessary processes for quantum computing applications, including quantum machine learning, Hamiltonian simulation, and many others. Yet, existing protocols suffer from poor robustness under device imperfection, thus limiting their practicality for real-world applications. Here, this limitation is overcome based on a fanin process designed in a tree-like bucket-brigade architecture. It suppresses the error propagation between different branches, thus exponentially improving the robustness compared to existing depth-optimal methods. Moreover, the approach here simultaneously achieves the state-of-the-art fault-tolerant circuit depth, gate count, and STA. As an example of application, we show that for quantum simulation of geometrically local Hamiltonian, the code distance of each logic qubit can potentially be reduced exponentially using our technique. We believe that our technique can significantly enhance the power of quantum computing in the near-term and fault-tolerant regimes.
format Preprint
id arxiv_https___arxiv_org_abs_2411_02782
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Robust and optimal loading of general classical data into quantum computers
Zhang, Xiao-Ming
Quantum Physics
Computational Complexity
Data Structures and Algorithms
Computational Physics
As standard data loading processes, quantum state preparation and block-encoding are critical and necessary processes for quantum computing applications, including quantum machine learning, Hamiltonian simulation, and many others. Yet, existing protocols suffer from poor robustness under device imperfection, thus limiting their practicality for real-world applications. Here, this limitation is overcome based on a fanin process designed in a tree-like bucket-brigade architecture. It suppresses the error propagation between different branches, thus exponentially improving the robustness compared to existing depth-optimal methods. Moreover, the approach here simultaneously achieves the state-of-the-art fault-tolerant circuit depth, gate count, and STA. As an example of application, we show that for quantum simulation of geometrically local Hamiltonian, the code distance of each logic qubit can potentially be reduced exponentially using our technique. We believe that our technique can significantly enhance the power of quantum computing in the near-term and fault-tolerant regimes.
title Robust and optimal loading of general classical data into quantum computers
topic Quantum Physics
Computational Complexity
Data Structures and Algorithms
Computational Physics
url https://arxiv.org/abs/2411.02782