Your search keyword '"Marcello Benedetti"' showing total 7 results

1. Structure optimization for parameterized quantum circuits

Author

Marcello Benedetti, Mateusz Ostaszewski, and Edward R. Grant

Subjects

Quantum Physics, Physics and Astronomy (miscellaneous), Computer science, Heisenberg model, Structure (category theory), Parameterized complexity, FOS: Physical sciences, 01 natural sciences, lcsh:QC1-999, Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, Computational science, chemistry.chemical_compound, chemistry, Lithium hydride, 0103 physical sciences, 010306 general physics, Ground state, Quantum Physics (quant-ph), Quantum, lcsh:Physics, Electronic circuit, Quantum computer

Abstract

We propose an efficient method for simultaneously optimizing both the structure and parameter values of quantum circuits with only a small computational overhead. Shallow circuits that use structure optimization perform significantly better than circuits that use parameter updates alone, making this method particularly suitable for noisy intermediate-scale quantum computers. We demonstrate the method for optimizing a variational quantum eigensolver for finding the ground states of Lithium Hydride and the Heisenberg model in simulation, and for finding the ground state of Hydrogen gas on the IBM Melbourne quantum computer., Comment: 13 pages, 6 figures. Added section "Optimization of circuits with limited expressibility". The previous version was titled "Quantum circuit structure learning"

Published

2019

2. A generative modeling approach for benchmarking and training shallow quantum circuits

Author

Yunseong Nam, Vicente Leyton-Ortega, Oscar Perdomo, Delfina Garcia-Pintos, Marcello Benedetti, and Alejandro Perdomo-Ortiz

Subjects

Quantum Physics, Computer Networks and Communications, Computer science, FOS: Physical sciences, Statistical and Nonlinear Physics, Quantum entanglement, 01 natural sciences, lcsh:QC1-999, lcsh:QA75.5-76.95, 010305 fluids & plasmas, Quantum circuit, Computational Theory and Mathematics, Computer engineering, Encoding (memory), Qubit, 0103 physical sciences, Metric (mathematics), Computer Science (miscellaneous), Benchmark (computing), lcsh:Electronic computers. Computer science, Quantum Physics (quant-ph), 010306 general physics, Quantum, lcsh:Physics, Quantum computer

Abstract

Hybrid quantum-classical algorithms provide ways to use noisy intermediate-scale quantum computers for practical applications. Expanding the portfolio of such techniques, we propose a quantum circuit learning algorithm that can be used to assist the characterization of quantum devices and to train shallow circuits for generative tasks. The procedure leverages quantum hardware capabilities to its fullest extent by using native gates and their qubit connectivity. We demonstrate that our approach can learn an optimal preparation of the Greenberger-Horne-Zeilinger states, also known as "cat states". We further demonstrate that our approach can efficiently prepare approximate representations of coherent thermal states, wave functions that encode Boltzmann probabilities in their amplitudes. Finally, complementing proposals to characterize the power or usefulness of near-term quantum devices, such as IBM's quantum volume, we provide a new hardware-independent metric called the qBAS score. It is based on the performance yield in a specific sampling task on one of the canonical machine learning data sets known as Bars and Stripes. We show how entanglement is a key ingredient in encoding the patterns of this data set; an ideal benchmark for testing hardware starting at four qubits and up. We provide experimental results and evaluation of this metric to probe the trade off between several architectural circuit designs and circuit depths on an ion-trap quantum computer., 16 pages, 9 figures. Minor revisions. As published in npj Quantum Information

Published

2018

3. Training of Quantum Circuits on a Hybrid Quantum Computer

Author

Daiwei Zhu, Oscar Perdomo, Norbert M. Linke, C. Brecque, A. Garfoot, K. A. Landsman, Christopher Monroe, Marcello Benedetti, Alejandro Perdomo-Ortiz, Cinthia Huerta Alderete, Laird Egan, Nhung H. Nguyen, and N. Korda

Subjects

Quantum Physics, Multidisciplinary, Computer science, Physics, Bayesian optimization, SciAdv r-articles, Parameterized complexity, Particle swarm optimization, FOS: Physical sciences, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Quantum circuit, Computer engineering, 0103 physical sciences, 010306 general physics, 0210 nano-technology, Quantum Physics (quant-ph), Quantum, Research Articles, Trapped ion quantum computer, Research Article, Electronic circuit, Quantum computer

Abstract

We train generative modeling circuits on a quantum hybrid computer showing an optimization strategy and a resource trade-off., Generative modeling is a flavor of machine learning with applications ranging from computer vision to chemical design. It is expected to be one of the techniques most suited to take advantage of the additional resources provided by near-term quantum computers. Here, we implement a data-driven quantum circuit training algorithm on the canonical Bars-and-Stripes dataset using a quantum-classical hybrid machine. The training proceeds by running parameterized circuits on a trapped ion quantum computer and feeding the results to a classical optimizer. We apply two separate strategies, Particle Swarm and Bayesian optimization to this task. We show that the convergence of the quantum circuit to the target distribution depends critically on both the quantum hardware and classical optimization strategy. Our study represents the first successful training of a high-dimensional universal quantum circuit and highlights the promise and challenges associated with hybrid learning schemes.

Published

2018

4. Adversarial quantum circuit learning for pure state approximation

Author

Marcello Benedetti, Edward R. Grant, Simone Severini, and Leonard Wossnig

Subjects

Physics, FOS: Computer and information sciences, Quantum Physics, Entropy (statistical thermodynamics), Heuristic, General Physics and Astronomy, FOS: Physical sciences, Machine Learning (stat.ML), Quantum entanglement, Quantum tomography, 01 natural sciences, 010305 fluids & plasmas, Quantum circuit, Statistics - Machine Learning, 0103 physical sciences, Probability distribution, 010306 general physics, Quantum Physics (quant-ph), Algorithm, Quantum, Quantum computer

Abstract

Adversarial learning is one of the most successful approaches to modelling high-dimensional probability distributions from data. The quantum computing community has recently begun to generalize this idea and to look for potential applications. In this work, we derive an adversarial algorithm for the problem of approximating an unknown quantum pure state. Although this could be done on universal quantum computers, the adversarial formulation enables us to execute the algorithm on near-term quantum computers. Two parametrized circuits are optimized in tandem: One tries to approximate the target state, the other tries to distinguish between target and approximated state. Supported by numerical simulations, we show that resilient backpropagation algorithms perform remarkably well in optimizing the two circuits. We use the bipartite entanglement entropy to design an efficient heuristic for the stopping criterion. Our approach may find application in quantum state tomography., Comment: 14 pages, 6 figures. Minor revisions. As published in New J. Phys

Published

2018

5. Opportunities and challenges for quantum-assisted machine learning in near-term quantum computers

Author

Rupak Biswas, Alejandro Perdomo-Ortiz, John Realpe-Gómez, and Marcello Benedetti

Subjects

FOS: Computer and information sciences, 0301 basic medicine, Physics and Astronomy (miscellaneous), Computer science, Materials Science (miscellaneous), FOS: Physical sciences, Computer Science - Emerging Technologies, Machine learning, computer.software_genre, 01 natural sciences, 03 medical and health sciences, 0103 physical sciences, Electrical and Electronic Engineering, 010306 general physics, Quantum, Quantum computer, Quantum Physics, business.industry, Deep learning, Supervised learning, Atomic and Molecular Physics, and Optics, Helmholtz machine, Generative model, Emerging Technologies (cs.ET), 030104 developmental biology, Qubit, ComputerSystemsOrganization_MISCELLANEOUS, Key (cryptography), Artificial intelligence, Quantum Physics (quant-ph), business, computer

Abstract

With quantum computing technologies nearing the era of commercialization and quantum supremacy, machine learning (ML) appears as one of the promising "killer" applications. Despite significant effort, there has been a disconnect between most quantum ML proposals, the needs of ML practitioners, and the capabilities of near-term quantum devices to demonstrate quantum enhancement in the near future. In this contribution to the focus collection on "What would you do with 1000 qubits?", we provide concrete examples of intractable ML tasks that could be enhanced with near-term devices. We argue that to reach this target, the focus should be on areas where ML researchers are struggling, such as generative models in unsupervised and semi-supervised learning, instead of the popular and more tractable supervised learning techniques. We also highlight the case of classical datasets with potential quantum-like statistical correlations where quantum models could be more suitable. We focus on hybrid quantum-classical approaches and illustrate some of the key challenges we foresee for near-term implementations. Finally, we introduce the quantum-assisted Helmholtz machine (QAHM), an attempt to use near-term quantum devices to tackle high-dimensional datasets of continuous variables. Instead of using quantum computers to assist deep learning, as previous approaches do, the QAHM uses deep learning to extract a low-dimensional binary representation of data, suitable for relatively small quantum processors which can assist the training of an unsupervised generative model. Although we illustrate this concept on a quantum annealer, other quantum platforms could benefit as well from this hybrid quantum-classical framework., Contribution to the special issue of Quantum Science & Technology (QST) on "What would you do with 1000 qubits"

Published

2017

6. Estimation of effective temperatures in quantum annealers for sampling applications: A case study with possible applications in deep learning

Author

Alejandro Perdomo-Ortiz, Marcello Benedetti, John Realpe-Gómez, and Rupak Biswas

Subjects

Physics, Quantum Physics, Restricted Boltzmann machine, Speedup, business.industry, Deep learning, FOS: Physical sciences, Sampling (statistics), Sample (statistics), 01 natural sciences, 010305 fluids & plasmas, symbols.namesake, Theoretical physics, 0103 physical sciences, Boltzmann constant, symbols, Artificial intelligence, Quantum Physics (quant-ph), 010306 general physics, business, Algorithm, Quantum, Block (data storage)

Abstract

An increase in the efficiency of sampling from Boltzmann distributions would have a significant impact on deep learning and other machine-learning applications. Recently, quantum annealers have been proposed as a potential candidate to speed up this task, but several limitations still bar these state-of-the-art technologies from being used effectively. One of the main limitations is that, while the device may indeed sample from a Boltzmann-like distribution, quantum dynamical arguments suggest it will do so with an {\it instance-dependent} effective temperature, different from its physical temperature. Unless this unknown temperature can be unveiled, it might not be possible to effectively use a quantum annealer for Boltzmann sampling. In this work, we propose a strategy to overcome this challenge with a simple effective-temperature estimation algorithm. We provide a systematic study assessing the impact of the effective temperatures in the learning of a special class of a restricted Boltzmann machine embedded on quantum hardware, which can serve as a building block for deep-learning architectures. We also provide a comparison to $k$-step contrastive divergence (CD-$k$) with $k$ up to 100. Although assuming a suitable fixed effective temperature also allows us to outperform one step contrastive divergence (CD-1), only when using an instance-dependent effective temperature do we find a performance close to that of CD-100 for the case studied here., New appendix and figure comparing to other temperature estimation techniques from the statistical physics community. 15 pages, 6 figures

Published

2016

7. Quantum-Assisted Learning of Hardware-Embedded Probabilistic Graphical Models

Author

Rupak Biswas, John Realpe-Gómez, Alejandro Perdomo-Ortiz, and Marcello Benedetti

Subjects

FOS: Computer and information sciences, Quantum Physics, Speedup, Computer science, Physics, QC1-999, General Physics and Astronomy, Sampling (statistics), FOS: Physical sciences, 01 natural sciences, 010305 fluids & plasmas, Machine Learning (cs.LG), Computer Science - Learning, Computer engineering, ComputerSystemsOrganization_MISCELLANEOUS, 0103 physical sciences, Probability distribution, Graphical model, 010306 general physics, Quantum Physics (quant-ph), Quantum, Quantum computer

Abstract

Mainstream machine-learning techniques such as deep learning and probabilistic programming rely heavily on sampling from generally intractable probability distributions. There is increasing interest in the potential advantages of using quantum computing technologies as sampling engines to speed up these tasks or to make them more effective. However, some pressing challenges in state-of-the-art quantum annealers have to be overcome before we can assess their actual performance. The sparse connectivity, resulting from the local interaction between quantum bits in physical hardware implementations, is considered the most severe limitation to the quality of constructing powerful generative unsupervised machine-learning models. Here we use embedding techniques to add redundancy to data sets, allowing us to increase the modeling capacity of quantum annealers. We illustrate our findings by training hardware-embedded graphical models on a binarized data set of handwritten digits and two synthetic data sets in experiments with up to 940 quantum bits. Our model can be trained in quantum hardware without full knowledge of the effective parameters specifying the corresponding quantum Gibbs-like distribution; therefore, this approach avoids the need to infer the effective temperature at each iteration, speeding up learning; it also mitigates the effect of noise in the control parameters, making it robust to deviations from the reference Gibbs distribution. Our approach demonstrates the feasibility of using quantum annealers for implementing generative models, and it provides a suitable framework for benchmarking these quantum technologies on machine-learning-related tasks., Comment: 17 pages, 8 figures. Minor further revisions. As published in Phys. Rev. X

Published

2016