Considering nearest neighbor constraints of quantum circuits at the reversible circuit level

Quantum Computing represents the next big step towards speed boost in computation, which promises major breakthroughs in several disciplines including Artificial Intelligence. This paper investigates the performance of a genetic algorithm to optimize the realization (compilation) of nearest-neighbor compliant quantum circuits. Currrent technological limitations (e.g., decoherence effect) impose that the overall duration (makespan) of the quantum circuit realization be minimized, and therefore the makespanminimization problem of compiling quantum algorithms on present or future quantum machines is dragging increasing attention in the AI community. In our genetic algorithm, a solution is built utilizing a novel chromosome encoding where each gene controls the iterative selection of a quantum gate to be inserted in the solution, over a lexicographic double-key ranking returned by a heuristic function recently published in the literature.Our algorithm has been tested on a set of quantum circuit benchmark instances of increasing sizes available from the recent literature. We demonstrate that our genetic approach obtains very encouraging results that outperform the solutions obtained in previous research against the same benchmark, succeeding in significantly improving the makespan values for a great number of instances.

Download Full-text

An Efficient Nearest Neighbor Design for 2D Quantum Circuits

Lecture Notes in Electrical Engineering - Design and Testing of Reversible Logic ◽

10.1007/978-981-13-8821-7_12 ◽

2019 ◽

pp. 215-231 ◽

Cited By ~ 1

Author(s):

A. Bhattacharjee ◽

C. Bandyopadhyay ◽

B. Mondal ◽

Robert Wille ◽

Rolf Drechsler ◽

...

Keyword(s):

Nearest Neighbor ◽

Quantum Circuits

Download Full-text

An Efficient Method to Convert Arbitrary Quantum Circuits to Ones on a Linear Nearest Neighbor Architecture

2009 Third International Conference on Quantum, Nano and Micro Technologies ◽

10.1109/icqnm.2009.25 ◽

2009 ◽

Cited By ~ 37

Author(s):

Yuichi Hirata ◽

Masaki Nakanishi ◽

Shigeru Yamashita ◽

Yasuhiko Nakashima

Keyword(s):

Efficient Method ◽

Nearest Neighbor ◽

Quantum Circuits ◽

Arbitrary Quantum

Download Full-text

Synthesis of quantum circuits in Linear Nearest neighbor Model using Positive Davio Lattices

Facta universitatis - series Electronics and Energetics ◽

10.2298/fuee1101071p ◽

2011 ◽

Vol 24 (1) ◽

pp. 71-87 ◽

Cited By ~ 10

Author(s):

Marek Perkowski ◽

Martin Lukac ◽

Dipal Shah ◽

Michitaka Kameyama

Keyword(s):

Nearest Neighbor ◽

Dimensional Space ◽

Synthesis Method ◽

Logic Synthesis ◽

Quantum Circuits ◽

Quantum Gates ◽

Synthesis Methods ◽

Cost Models ◽

Quantum Cost ◽

One Dimensional

We present a logic synthesis method based on lattices that realize quantum arrays in One-Dimensional Ion Trap technology. This means that all gates are built from 2x2 quantum primitives that are located only on neighbor qubits in a one-dimensional space (called also vector of qubits or Linear Nearest Neighbor (LNN) architecture). The Logic circuits designed by the proposed method are realized only with 3*3 Toffoli, Feynman and NOT quantum gates and the usage of the commonly used multi-input Toffoli gates is avoided. This realization method of quantum circuits is different from most of reversible circuits synthesis methods from the literature that use only high level quantum cost based on the number of quantum gates. Our synthesis approach applies to both standard and LNN quantum cost models. It leads to entirely new CAD algorithms for circuit synthesis and substantially decreases the quantum cost for LNN quantum circuits. The drawback of synthesizing circuits in the presented LNN architecture is the addition of ancilla qubits.

Download Full-text

Merlin-Arthur with efficient quantum Merlin and quantum supremacy for the second level of the Fourier hierarchy

Quantum ◽

10.22331/q-2018-11-15-106 ◽

2018 ◽

Vol 2 ◽

pp. 106 ◽

Cited By ~ 5

Author(s):

Tomoyuki Morimae ◽

Yuki Takeuchi ◽

Harumichi Nishimura

Keyword(s):

Quantum Computing ◽

Polynomial Time ◽

Probability Distributions ◽

Quantum Circuits ◽

Universal Models ◽

Reversible Circuit ◽

Universal Quantum ◽

Quantum Polynomial ◽

Output Probability ◽

Probabilistic Polynomial Time

We introduce a simple sub-universal quantum computing model, which we call the Hadamard-classical circuit with one-qubit (HC1Q) model. It consists of a classical reversible circuit sandwiched by two layers of Hadamard gates, and therefore it is in the second level of the Fourier hierarchy. We show that output probability distributions of the HC1Q model cannot be classically efficiently sampled within a multiplicative error unless the polynomial-time hierarchy collapses to the second level. The proof technique is different from those used for previous sub-universal models, such as IQP, Boson Sampling, and DQC1, and therefore the technique itself might be useful for finding other sub-universal models that are hard to classically simulate. We also study the classical verification of quantum computing in the second level of the Fourier hierarchy. To this end, we define a promise problem, which we call the probability distribution distinguishability with maximum norm (PDD-Max). It is a promise problem to decide whether output probability distributions of two quantum circuits are far apart or close. We show that PDD-Max is BQP-complete, but if the two circuits are restricted to some types in the second level of the Fourier hierarchy, such as the HC1Q model or the IQP model, PDD-Max has a Merlin-Arthur system with quantum polynomial-time Merlin and classical probabilistic polynomial-time Arthur.

Download Full-text

Improved Look-Ahead Approaches for Nearest Neighbor Synthesis of 1D Quantum Circuits

2019 32nd International Conference on VLSI Design and 2019 18th International Conference on Embedded Systems (VLSID) ◽

10.1109/vlsid.2019.00054 ◽

2019 ◽

Cited By ~ 2

Author(s):

Anirban Bhattacharjee ◽

Chandan Bandyopadhyay ◽

Robert Wille ◽

Rolf Drechsler ◽

Hafizur Rahaman

Keyword(s):

Nearest Neighbor ◽

Quantum Circuits ◽

Look Ahead

Download Full-text

Analyzing Heuristic-based Randomized Search Strategies for the Quantum Circuit Compilation Problem

Fundamenta Informaticae ◽

10.3233/fi-2020-1942 ◽

2020 ◽

Vol 174 (3-4) ◽

pp. 259-281

Author(s):

Angelo Oddi ◽

Riccardo Rasconi

Keyword(s):

Quantum Computing ◽

Nearest Neighbor ◽

Quantum Algorithm ◽

Quantum Circuit ◽

Quantum Circuits ◽

Quantum Gates ◽

Ranking Functions ◽

Solution Quality ◽

Circuit Realization ◽

Definition Of

In this work we investigate the performance of greedy randomised search (GRS) techniques to the problem of compiling quantum circuits to emerging quantum hardware. Quantum computing (QC) represents the next big step towards power consumption minimisation and CPU speed boost in the future of computing machines. Quantum computing uses quantum gates that manipulate multi-valued bits (qubits). A quantum circuit is composed of a number of qubits and a series of quantum gates that operate on those qubits, and whose execution realises a specific quantum algorithm. Current quantum computing technologies limit the qubit interaction distance allowing the execution of gates between adjacent qubits only. This has opened the way to the exploration of possible techniques aimed at guaranteeing nearest-neighbor (NN) compliance in any quantum circuit through the addition of a number of so-called swap gates between adjacent qubits. In addition, technological limitations (decoherence effect) impose that the overall duration (makespan) of the quantum circuit realization be minimized. One core contribution of the paper is the definition of two lexicographic ranking functions for quantum gate selection, using two keys: one key acts as a global closure metric to minimise the solution makespan; the second one is a local metric, which favours the mutual approach of the closest qstates pairs. We present a GRS procedure that synthesises NN-compliant quantum circuits realizations, starting from a set of benchmark instances of different size belonging to the Quantum Approximate Optimization Algorithm (QAOA) class tailored for the MaxCut problem. We propose a comparison between the presented meta-heuristics and the approaches used in the recent literature against the same benchmarks, both from the CPU efficiency and from the solution quality standpoint. In particular, we compare our approach against a reference benchmark initially proposed and subsequently expanded in [1] by considering: (i) variable qubit state initialisation and (ii) crosstalk constraints that further restrict parallel gate execution.

Download Full-text

Linear Nearest Neighbor Realization of Quantum Circuits Using Clustering and Look-ahead Policy

Journal of Circuits System and Computers ◽

10.1142/s0218126620502631 ◽

2020 ◽

Vol 29 (16) ◽

pp. 2050263

Author(s):

Anirban Bhattacharjee ◽

Chandan Bandyopadhyay ◽

Bappaditya Mondal ◽

Hafizur Rahaman

Keyword(s):

Nearest Neighbor ◽

Quantum Circuit ◽

Quantum Circuits ◽

Physical Realization ◽

Emerging Trends ◽

Look Ahead ◽

Wide Range ◽

Clustering Approach ◽

On Chip ◽

The Impact

In the last couple of years, quantum computing has come out as emerging trends of computation not only due to its immense popularity but also for its commitment towards physical realization of quantum circuit in on-chip units. At the same time, the process of physical realization has faced several design constraints and one such problem is nearest neighbor (NN) enforcement which demands all the operating qubits to be placed adjacent in the implementable circuit. Though SWAP gate embedment can transform a design into NN architecture, it still creates overhead in the design. So, designing algorithms to restrict the use of SWAPs bears high importance. Considering this fact, in this work, we are proposing a heuristic-based improved qubit placement strategy for efficient implementation of NN circuit. Two different design policies are being developed here. In the first scheme, a global reordering technique based on clustering approach is shown. In the second scheme, a local reordering technique based on look-ahead policy is developed. This look-ahead strategy considers the impact over the gates in the circuit and thereby estimates the effect using a cost metric to decide the suitable option for SWAP implementation. Furthermore, the joint use of both the ordering schemes also has been explored here. To ascertain the correctness of our design algorithms, we have tested them over a wide range of benchmarks and the obtained results are compared with some state-of-the-art design approaches. From this comparison, we have witnessed a considerable reduction on SWAP cost in our design scheme against the reported works’ results.

Download Full-text