Rolf Drechsler scite author profile

Synthesis of reversible logic has become an active research area in the last years. But many proposed algorithms are evaluated with a small set of benchmarks only. Furthermore, results are often documented only in terms of gate counts or quantum costs, rather than presenting the specific circuit. In this paper RevLib (www.revlib.org) is introduced, an online resource for reversible functions and reversible circuits. RevLib provides a large database of functions with respective circuit realizations. RevLib is designed to ease the evaluation of new methods and facilitate the comparison of results. In addition, tools are introduced to support researchers in evaluating their algorithms and documenting their results.

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BDD-based synthesis of reversible logic for large functions

Wille

Drechsler

2009

269

184

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Reversible logic is the basis for several emerging technologies such as quantum computing, optical computing, or DNA computing and has further applications in domains like low-power design and nanotechnologies. However, current methods for the synthesis of reversible logic are limited, i.e. they are applicable to relatively small functions only. In this paper, we propose a synthesis approach, that can cope with Boolean functions containing more than a hundred of variables. We present a technique to derive reversible circuits for a function given by a Binary Decision Diagram (BDD). The circuit is obtained using an algorithm with linear worst case behavior regarding run-time and space requirements. Furthermore, the size of the resulting circuit is bounded by the BDD size. This allows to transfer theoretical results known from BDDs to reversible circuits. Experiments show better results (with respect to the circuit cost) and a significantly better scalability in comparison to previous synthesis approaches.

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Synthesis of quantum circuits for linear nearest neighbor architectures

Saeedi

Wille

Drechsler

2010

Quantum Inf Process

181

125

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While a couple of impressive quantum technologies have been proposed, they have several intrinsic limitations which must be considered by circuit designers to produce realizable circuits. Limited interaction distance between gate qubits is one of the most common limitations. In this paper, we suggest extensions of the existing synthesis flow aimed to realize circuits for quantum architectures with linear nearest neighbor (LNN) interaction. To this end, a template matching optimization, an exact synthesis approach, and two reordering strategies are introduced. The proposed methods are combined as an integrated synthesis flow. Experiments show that by using the suggested flow, quantum cost can be improved by more than 50% on average.

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Exact Multiple-Control Toffoli Network Synthesis With SAT Techniques

Große

Wille

Dueck

et al. 2009

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

153

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RTL-datapath verification using integer linear programming

Brinkmann¹,

Drechsler²

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Rolf Drechsler

RevLib: An Online Resource for Reversible Functions and Reversible Circuits

BDD-based synthesis of reversible logic for large functions

Synthesis of quantum circuits for linear nearest neighbor architectures

Exact Multiple-Control Toffoli Network Synthesis With SAT Techniques

RTL-datapath verification using integer linear programming

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