Anand, K. (2024). Feynman’s Entangled Paths to Optimized Circuit Design. arXiv preprint arXiv:2411.08928v1.
This paper explores the potential of leveraging entanglement dynamics, inspired by Feynman's path integral formalism, to optimize quantum circuit design. The author investigates whether minimizing the cumulative entanglement changes during circuit execution can lead to more efficient circuit constructions.
The author draws a parallel between Feynman's path integral formalism and quantum circuit dynamics, suggesting that the degree of entanglement in a state is influenced by the discrete-time trajectories leading to its preparation. The paper introduces the concept of "path-entanglement sum," which quantifies the total entanglement change throughout the circuit's execution.
The author proposes the "Minimum entanglement-path conjecture," stating that an optimal state-path, representing the sequence of states prepared by a circuit, likely belongs to a family of paths with the minimum possible path-entanglement sum. This conjecture suggests that minimizing entanglement fluctuations during computation could be a key principle for circuit optimization.
While acknowledging the limitations of applying Feynman's path integral formalism to general quantum circuits due to the lack of a well-defined action functional, the author argues that the proposed conjecture could significantly narrow the search space for optimal circuit designs. This approach could potentially enhance the efficiency of quantum circuit optimization algorithms by enabling faster convergence and more reliable outputs.
This research offers a novel perspective on quantum circuit optimization by connecting it to the fundamental concept of entanglement dynamics. If validated, the proposed conjecture could have significant implications for developing more efficient quantum algorithms and advancing the field of quantum complexity theory.
The author acknowledges that the conjecture might not hold true for specific cases and emphasizes the need for further investigation to establish a probability bound for its validity. Future research directions include rigorously formalizing Feynman's path view for general quantum circuits and exploring the relationship between the action functional and circuit complexity in this context.
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by Kartik Anand о arxiv.org 11-15-2024
https://arxiv.org/pdf/2411.08928.pdfГлибші Запити