Reversible Pebble Games For Reducing Qubits In Hierarchical Quantum Circuit Synthesis

Hierarchical reversible logic synthesis can find quantum circuits for large combinational functions. The price for a better scalability compared to functional synthesis approaches is the requirement for many additional qubits to store temporary results of the hierarchical input representation. However, implementing a quantum circuit with large number of qubits is a major hurdle. In this paper, we demonstrate and establish how reversible pebble games can be used to reduce the number of stored temporary results, thereby reducing the qubit count. Our proposed algorithm can be constrained with number of qubits, which is aimed to meet. Experimental studies show that the qubit count can be significantly reduced (by up to 63.2%) compared to the slate-of-the-art algorithms, at the cost of additional gate count.

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Debjyoti Bhattacharjee, Anupam Chattopadhyay, Giovanni De Micheli, Mathias Soeken
IEEE, 2019
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https://infoscience.epfl.ch/record/270731?ln=en

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Advanced Functional Decomposition Using Majority and Its Applications

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Typical operators for the decomposition of Boolean functions in state-of-the-art algorithms are AND, exclusive-OR (XOR), and the 2-to-1 multiplexer (MUX). We propose a logic decomposition algorithm that uses the majority-of-three (MAJ) operation. Such a decomposition can extend the capabilities of current logic decompositions, but only found limited attention in the previous work. Our algorithm make use of a decomposition rule based on MAJ. Combined with disjoint-support decomposition, the algorithm can factorize XOR-majority graphs (XMGs), a recently proposed data structure which has XOR, MAJ, and inverters as only logic primitives. XMGs have been applied in various applications, including: 1) exact-synthesis-aware rewriting; 2) preoptimization for 6-input look-up table (6-LUT) mapping; and 3) synthesis of quantum circuits. An experimental evaluation shows that our algorithm leads to better XMGs compared to state-of-the-art algorithms based on XMGs, which positively affects all of these three applications. As one example, our experiments show that the proposed method achieves an average of 10% and 26% reduction on the LUTs size/depth product applied to the EPFL arithmetic and random control benchmarks after technology mapping, respectively.

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