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Efficient Implementation of Interior-Point Methods for Quantum Relative Entropy


Temel Kavramlar
The authors propose numerical and linear algebraic techniques to enhance the efficiency of interior-point methods for Quantum Relative Entropy (QRE) programming, addressing scalability challenges.
Özet

The paper discusses modern interior-point methods for optimizing over the QRE cone, introducing techniques to improve gradient and Hessian computations. It also explores symmetric quantum relative entropy and a two-phase method for enhancing performance in QRE programming. The authors present comprehensive numerical experiments comparing their techniques with existing software packages like Hypatia. Additionally, they discuss handling complex Hermitian matrices and propose a two-phase approach for calculating the rate of quantum key distribution channels.

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Kaynak

İstatistikler
DDS 2.2 implemented new techniques to solve larger instances compared to DDS 2.1 and Hypatia. The code can handle various constraints including QRE constraints combined with other types. Numerical experiments were conducted on MATLAB R2022a using default settings with tolerance set at 10^-8.
Alıntılar
"The available modern IP codes for solving convex optimization problems using self-concordant barriers are Alfonso, Hypatia, and DDS." "Our new techniques have been implemented in the latest version (DDS 2.2) of the software package DDS." "DDS accepts every combination of function/set constraints including symmetric cones, quadratic constraints, direct sums of convex sets, vector relative entropy, quantum entropy, and hyperbolic polynomials."

Önemli Bilgiler Şuradan Elde Edildi

by Mehdi Karimi... : arxiv.org 03-12-2024

https://arxiv.org/pdf/2312.07438.pdf
Efficient Implementation of Interior-Point Methods for Quantum Relative  Entropy

Daha Derin Sorular

How do the proposed two-phase methods compare to traditional optimization approaches

The proposed two-phase methods in the context of Quantum Relative Entropy (QRE) optimization offer significant advantages over traditional optimization approaches. By breaking down the problem into two phases, where Phase-I focuses on finding a well-conditioned formulation and Phase-II solves the actual QRE problem, these methods enhance efficiency and scalability. Traditional optimization approaches may struggle with large-scale QRE programming due to computational complexity and numerical challenges. In contrast, the two-phase methods provide a systematic way to handle such complexities by reducing the dimensionality of the problem in an initial phase before tackling the main optimization task.

What implications do these advancements have for real-world applications in quantum computing

The advancements in two-phase methods for QRE optimization have profound implications for real-world applications in quantum computing, particularly in areas like quantum key distribution (QKD) channels. By improving the performance and scalability of solving QRE problems, these techniques enable more accurate calculations of key rates for secure communication protocols like QKD. This can lead to enhanced security measures and improved encryption strategies based on quantum principles. Additionally, efficient solutions to complex convex optimization problems involving quantum relative entropy open up possibilities for optimizing various aspects of quantum information theory applications.

How might the integration of complex Hermitian matrices impact future developments in quantum information theory

The integration of complex Hermitian matrices into developments in quantum information theory holds significant promise for advancing research and practical implementations. Complex matrices play a crucial role in representing quantum states and operations accurately, especially when dealing with entanglement or superposition phenomena inherent to quantum systems. By incorporating complex matrix operations efficiently within algorithms like those designed for Quantum Relative Entropy (QRE), researchers can explore more intricate aspects of quantum computing such as multi-qubit interactions or advanced cryptographic protocols based on qubit manipulations. This integration paves the way for exploring new frontiers in quantum information processing with enhanced precision and versatility.
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