The authors present a fault-tolerant logical sampling architecture based on a family of [2D, D, 2] color codes. These codes support a transversal gate set that includes non-Clifford CkZ gates, allowing the efficient implementation of degree-D IQP circuits without the need for magic state distillation.
The authors design a hardware-efficient family of degree-D IQP circuits with connectivity given by a D-dimensional hypercube, which they call hypercube IQP (hIQP) circuits. They show that this family rapidly converges to uniform IQP circuits and can therefore be thought of as a fault-tolerant compilation of the uniform IQP family.
The authors analyze the conditions under which random degree-D hIQP circuits are sufficiently scrambling for quantum advantage and benchmarking applications. They develop a theory of second-moment properties of degree-D IQP circuits, mapping them to a statistical mechanics model, which allows them to study the scrambling properties and the linear cross-entropy benchmark (XEB) of the hIQP circuits.
To address the issue of efficiently verifying quantum advantage, the authors show that degree-D IQP sampling can be efficiently validated by measuring two copies of a logical degree-(D+1) circuit in the Bell basis.
Finally, the authors devise new families of [O(dD), D, d] color codes that support scalable fault-tolerant transversal IQP sampling, with an error correction threshold that allows the quantum output distribution to converge exponentially to the target distribution as the code size is increased.
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by Dominik Hang... alle arxiv.org 05-01-2024
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