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Analysis of Sum-of-Squares Relaxations for the Quantum Rotor Model


แนวคิดหลัก
The author explores the application of sum-of-squares relaxations to approximate ground state energies in the quantum rotor model, showcasing a novel technique for constructing entangled states directly from semidefinite programming solutions.
บทคัดย่อ

The content delves into the noncommutative sum-of-squares hierarchy applied to local Hamiltonians, focusing on approximating ground state energies. It introduces a new method inspired by Connes's noncommutative geometry to construct entangled states efficiently. The study highlights the significance of solving infinite-dimensional problems using the ncSoS hierarchy and provides theoretical guarantees for finding ground energy in the quantum rotor model.

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สถิติ
Recent work analyzes hierarchy for approximating ground energies. Degree-2 ncSoS relaxation outperforms product state approximations. Quantum rotor model shows potential benefits of solving infinite-dimensional problems. Results provide theoretical guarantees for finding ground energy in quantum rotor model.
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ข้อมูลเชิงลึกที่สำคัญจาก

by Sujit Rao ที่ arxiv.org 03-04-2024

https://arxiv.org/pdf/2311.09010.pdf
Analysis of sum-of-squares relaxations for the quantum rotor model

สอบถามเพิ่มเติม

How does the proposed technique compare with traditional methods in quantum optimization?

The proposed technique in the context provided is based on noncommutative sum-of-squares (ncSoS) relaxations for approximating ground energies of local Hamiltonians, specifically focusing on the quantum rotor model. This approach involves a hierarchy of semidefinite programming relaxations and utilizes techniques from Connes's noncommutative geometry to construct entangled states directly from the output of an ncSoS SDP. In comparison to traditional methods in quantum optimization, such as classical polynomial optimization using sum-of-squares hierarchies, this technique offers a more specialized and tailored approach for problems involving noncommutative polynomial optimization. By leveraging concepts from quantum information theory and condensed matter physics, it addresses specific challenges related to local Hamiltonians with infinite-dimensional Hilbert spaces.

What implications could this research have on practical applications in quantum computing?

This research has significant implications for practical applications in quantum computing. By providing theoretical guarantees for finding the ground energy of complex models like the quantum rotor model, it opens up possibilities for optimizing algorithms and simulations that involve continuous-variable systems. The ability to approximate ground state energies better than product states using degree-2 ncSoS relaxations can lead to improved efficiency and accuracy in solving real-world problems within quantum mechanics. Furthermore, advancements in noncommutative polynomial optimization techniques can enhance computational capabilities in areas such as machine learning, cryptography, and algorithm design where complex mathematical models need efficient solutions. The insights gained from studying these relaxation methods can potentially drive innovation in developing new algorithms for tackling challenging computational tasks efficiently.

How might advancements in noncommutative polynomial optimization impact other fields beyond physics?

Advancements in noncommutative polynomial optimization have far-reaching implications beyond physics into various fields such as computer science, mathematics, engineering, finance, and more: Computer Science: Improved algorithms based on these optimizations can enhance problem-solving capabilities across different domains like artificial intelligence (AI), data analysis, pattern recognition. Mathematics: Developments here could lead to new mathematical tools and methodologies applicable not only within theoretical mathematics but also practical problem-solving scenarios. Engineering: Optimization techniques derived from noncommutative polynomials may find applications in designing efficient systems or processes within engineering disciplines like control systems or signal processing. Finance: Enhanced computational methods could be utilized for financial modeling tasks requiring complex calculations or risk assessments. Cryptography: Advanced optimization approaches may contribute towards strengthening cryptographic protocols by improving security measures through optimized algorithms. Overall, progress made through advancements in noncommutative polynomial optimizations has the potential to revolutionize problem-solving strategies across diverse fields beyond just physics applications.
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