Reducing T Gates with Unitary Synthesis

Abstract

Quantum error correction is essential for achieving practical quantum computing but has a significant computational overhead. Among fault-tolerant (FT) gate operations, non-Clifford gates, such as T, are particularly expensive due to their reliance on magic state distillation. These costly T gates appear frequently in FT circuits as many quantum algorithms require arbitrary single-qubit rotations, such as Rx and Rz gates, which must be decomposed into a sequence of T and Clifford gates. In many quantum circuits, Rx and Rz gates can be fused to form a single U3 unitary. However, existing synthesis methods, such as Gridsynth, rely on indirect decompositions, requiring separate Rz decompositions that result in a threefold increase in T count. This work presents TensoR-based Arbitrary unitary SYNthesis (trasyn), a novel FT synthesis algorithm that directly synthesizes arbitrary single-qubit unitaries, avoiding the overhead of separate Rz decompositions. By leveraging tensor network-based search, our approach enables native U3 synthesis, reducing the T count, Clifford gate count, and approximation error. Compared to Gridsynth-based circuit synthesis, for 187 representative benchmarks, our design reduces the T count by up to 3.5×, and Clifford gates by 7×, resulting in up to 4× improvement in overall circuit infidelity.

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