This invention introduces a novel approach to implementing fault-tolerant quantum circuits using Trotter circuits, which are essential for quantum simulations and other key algorithms. It provides a systematic framework for translating logical Trotter circuits into physical ones using symplectic transvections—algebraic structures that ensure the integrity of the logical operations and stabilizers. Quantum computing has the potential to revolutionize industries by solving complex problems exponentially faster than classical computers. However, quantum hardware is highly susceptible to errors, requiring fault-tolerant methods to ensure reliable computations. By optimizing the structure and execution of logical Trotter circuits, this technology significantly reduces resource overhead while maintaining computational accuracy. Background: Current quantum computing systems face significant challenges due to hardware noise and the need for error correction. Traditional fault-tolerant quantum computing methods rely on gate-by-gate fault-tolerant compilation using logical measurement and magic state distillation techniques, which demand extensive resources and complex implementations. These existing approaches lead to increased costs and operational inefficiencies, limiting practical scalability. This technology streamlines the execution of fault-tolerant quantum computations by leveraging symplectic transvections and structured circuit design, enabling more efficient quantum algorithms with fewer resources. Its optimized approach not only reduces computational overhead but also enhances stability, making it a more viable solution for real-world quantum applications. Applications:
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