Efficient High-Dimensional Quantum Circuit Synthesis: From Multi-Controlled Gates to Isometries and Quantum Channels
Abstract
Circuit synthesis of multi-controlled gates is crucial for qudit (d-level) quantum computing. This paper presents efficient synthesis schemes that reduce the elementary gate count for multi-controlled single-qudit gates. For synthesizing general (n-1)-controlled unitaries on n qudits, we reduce the controlled-increment (CINC) and generalized controlled-X (GCX) gate counts to O(n2), improving upon existing O(n2+2 d) CINC and O(n3) GCX bounds. For (n-1)-controlled special unitaries, this complexity is further reduced to O(n). By utilizing the proposed circuit, we present qudit-based circuit constructions for isometries and quantum channels from n to m qudits. When specialized to general n-qudit unitaries, our construction requires fewer CINC gates than previous results. Moreover, for the first time, we present a circuit synthesis scheme for single-controlled gates using SUM gates and single-qudit gates when d is prime. This enables all CINC-based circuits for various quantum operations to be converted into SUM-gate circuits while preserving the same asymptotic complexity. Finally, we establish a theoretical lower bound on the number of SUM and CINC gates required to synthesize general n-qudit unitaries.
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