Your search keyword '"Ronagh, Pooya"' showing total 11 results

1. A Cryogenic Memristive Neural Decoder for Fault-tolerant Quantum Error Correction

Author

Marcotte, Frédéric, Mouny, Pierre-Antoine, Yon, Victor, Dagnew, Gebremedhin A., Kulchytskyy, Bohdan, Rochette, Sophie, Beilliard, Yann, Drouin, Dominique, and Ronagh, Pooya

Subjects

FOS: Computer and information sciences, Quantum Physics, Computer Science - Machine Learning, Emerging Technologies (cs.ET), FOS: Physical sciences, Computer Science - Emerging Technologies, Quantum Physics (quant-ph), Machine Learning (cs.LG)

Abstract

Neural decoders for quantum error correction (QEC) rely on neural networks to classify syndromes extracted from error correction codes and find appropriate recovery operators to protect logical information against errors. Despite the good performance of neural decoders, important practical requirements remain to be achieved, such as minimizing the decoding time to meet typical rates of syndrome generation in repeated error correction schemes, and ensuring the scalability of the decoding approach as the code distance increases. Designing a dedicated integrated circuit to perform the decoding task in co-integration with a quantum processor appears necessary to reach these decoding time and scalability requirements, as routing signals in and out of a cryogenic environment to be processed externally leads to unnecessary delays and an eventual wiring bottleneck. In this work, we report the design and performance analysis of a neural decoder inference accelerator based on an in-memory computing (IMC) architecture, where crossbar arrays of resistive memory devices are employed to both store the synaptic weights of the decoder neural network and perform analog matrix-vector multiplications during inference. In proof-of-concept numerical experiments supported by experimental measurements, we investigate the impact of TiO$_\textrm{x}$-based memristive devices' non-idealities on decoding accuracy. Hardware-aware training methods are developed to mitigate the loss in accuracy, allowing the memristive neural decoders to achieve a pseudo-threshold of $9.23\times 10^{-4}$ for the distance-three surface code, whereas the equivalent digital neural decoder achieves a pseudo-threshold of $1.01\times 10^{-3}$. This work provides a pathway to scalable, fast, and low-power cryogenic IMC hardware for integrated QEC.

Published

2023

2. On the Computational Cost of Stochastic Security

Author

Crum, Noah A., Sunny, Leanto, Ronagh, Pooya, Laflamme, Raymond, Balu, Radhakrishnan, and Siopsis, George

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Quantum Physics, Artificial Intelligence (cs.AI), Optimization and Control (math.OC), Computer Science - Artificial Intelligence, FOS: Mathematics, FOS: Physical sciences, Quantum Physics (quant-ph), Mathematics - Optimization and Control, Machine Learning (cs.LG)

Abstract

We investigate whether long-run persistent chain Monte Carlo simulation of Langevin dynamics improves the quality of the representations achieved by energy-based models (EBM). We consider a scheme wherein Monte Carlo simulation of a diffusion process using a trained EBM is used to improve the adversarial robustness and the calibration score of an independent classifier network. Our results show that increasing the computational budget of Gibbs sampling in persistent contrastive divergence improves the calibration and adversarial robustness of the model, elucidating the practical merit of realizing new quantum and classical hardware and software for efficient Gibbs sampling from continuous energy potentials.

Published

2023

3. Neural-Shadow Quantum State Tomography

Author

Wei, Victor, Coish, W. A., Ronagh, Pooya, and Muschik, Christine A.

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

Quantum state tomography (QST) is the art of reconstructing an unknown quantum state through measurements. It is a key primitive for developing quantum technologies. Neural network quantum state tomography (NNQST), which aims to reconstruct the quantum state via a neural network ansatz, is often implemented via a basis-dependent cross-entropy loss function. State-of-the-art implementations of NNQST are often restricted to characterizing a particular subclass of states, to avoid an exponential growth in the number of required measurement settings. To provide a more broadly applicable method for efficient state reconstruction, we present "neural-shadow quantum state tomography" (NSQST)-an alternative neural network-based QST protocol that uses infidelity as the loss function. The infidelity is estimated using the classical shadows of the target state. Infidelity is a natural choice for training loss, benefiting from the proven measurement sample efficiency of the classical shadow formalism. Furthermore, NSQST is robust against various types of noise without any error mitigation. We numerically demonstrate the advantage of NSQST over NNQST at learning the relative phases of three target quantum states of practical interest. NSQST greatly extends the practical reach of NNQST and provides a novel route to effective quantum state tomography.

Published

2023

4. Gibbs Sampling of Periodic Potentials on a Quantum Computer

Author

Motamedi, Arsalan and Ronagh, Pooya

Subjects

FOS: Computer and information sciences, Quantum Physics, Optimization and Control (math.OC), Computer Science - Data Structures and Algorithms, FOS: Mathematics, FOS: Physical sciences, Data Structures and Algorithms (cs.DS), Quantum Physics (quant-ph), Mathematics - Optimization and Control

Abstract

Gibbs sampling from continuous real-valued functions is a challenging problem of interest in machine learning. Here we leverage quantum Fourier transforms to build a quantum algorithm for this task when the function is periodic. We use the quantum algorithms for solving linear ordinary differential equations to solve the Fokker--Planck equation and prepare a quantum state encoding the Gibbs distribution. We show that the efficiency of interpolation and differentiation of these functions on a quantum computer depends on the rate of decay of the Fourier coefficients of the Fourier transform of the function. We view this property as a concentration of measure in the Fourier domain, and also provide functional analytic conditions for it. Our algorithm makes zeroeth order queries to a quantum oracle of the function. Despite suffering from an exponentially long mixing time, this algorithm allows for exponentially improved precision in sampling, and polynomial quantum speedups in mean estimation in the general case, and particularly under geometric conditions we identify for the critical points of the energy function., 48 pages

Published

2022

5. Benchmark Study of Quantum Algorithms for Combinatorial Optimization: Unitary versus Dissipative

Author

Sankar, Krishanu, Scherer, Artur, Kako, Satoshi, Reifenstein, Sam, Ghadermarzy, Navid, Krayenhoff, Willem B., Inui, Yoshitaka, Ng, Edwin, Onodera, Tatsuhiro, Ronagh, Pooya, and Yamamoto, Yoshihisa

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We study the performance scaling of three quantum algorithms for combinatorial optimization: measurement-feedback coherent Ising machines (MFB-CIM), discrete adiabatic quantum computation (DAQC), and the D\"urr-Hoyer algorithm for quantum minimum finding (DH-QMF) that is based on Grover's search. We use MaxCut problems as our reference for comparison, and time-to-solution (TTS) as a practical measure of performance for these optimization algorithms. We empirically observe a $\Theta(2^{\sqrt{n}})$ scaling for the median TTS for MFB-CIM, in comparison to the exponential scaling with the exponent $n$ for DAQC and the provable $\widetilde{\mathcal O}\left(\sqrt{2^n}\right)$ scaling for DH-QMF. We conclude that these scaling complexities result in a dramatic performance advantage for MFB-CIM in comparison to the other two algorithms for solving MaxCut problems., Comment: 24 pages, 20 figures

Published

2021

6. Mixed-Integer Programming Using a Bosonic Quantum Computer

Author

Khosravi, Farhad, Scherer, Artur, and Ronagh, Pooya

Subjects

FOS: Computer and information sciences, Quantum Physics, Optimization and Control (math.OC), Computer Science - Data Structures and Algorithms, FOS: Mathematics, FOS: Physical sciences, Data Structures and Algorithms (cs.DS), Quantum Physics (quant-ph), Mathematics - Optimization and Control

Abstract

We propose a scheme for solving mixed-integer programming problems in which the optimization problem is translated to a ground-state preparation problem on a set of bosonic quantum field modes (qumodes). We perform numerical demonstrations by simulating a circuit-based optical quantum computer with each individual qumode prepared in a Gaussian state. We simulate an adiabatic evolution from an initial mixing Hamiltonian, written in terms of the momentum operators of the qumodes, to a final Hamiltonian which is a polynomial of the position and boson number operators. In these demonstrations, we solve a variety of small non-convex optimization problems in integer programming, continuous non-convex optimization, and mixed-integer programming., Comment: 13 pages, 9 figures

Published

2021

7. Nuwa: A Quantum Circuit Transpiler Based on a Finite-Horizon Heuristic for Placement and Routing

Author

Ren, Shengru, Chen, KaWai, Ghadermarzy, Navid, Nguyen, Brandon, Huang, Yanhao, and Ronagh, Pooya

Subjects

Quantum Physics, Computer Science::Hardware Architecture, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We introduce a novel transpiler for the placement and routing of quantum circuits on arbitrary target hardware architectures. We use finite-horizon, and optionally discounted, reward functions to heuristically find a suitable placement and routing policy. We employ a finite lookahead to refine the reward functions when breaking a tie between multiple policies. We benchmark our transpiler against multiple alternative solutions and on various test sets of quantum algorithms to demonstrate the benefits of our approach., Comment: 11 pages, 7 figures, 3 tables

Published

2021

8. Reflection-Based Adiabatic State Preparation

Author

Lemieux, Jessica, Scherer, Artur, and Ronagh, Pooya

Subjects

Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)

Abstract

We propose a circuit-model quantum algorithm for eigenpath traversal that is based on a combination of concepts from Grover's search and adiabatic quantum computation. Our algorithm deploys a sequence of reflections determined from eigenspaces of instantaneous Hamiltonians defined along an adiabatic schedule in order to prepare a ground state of a target problem Hamiltonian. We provide numerical evidence suggesting that, for combinatorial search problems, our algorithm can find a solution faster, on average, than Grover's search. We demonstrate our findings by applying both algorithms to solving the NP-hard MAX-2SAT problem., Comment: 10 pages, 9 figures

Published

2021

9. Reinforcement learning using quantum Boltzmann machines

Author

Crawford, Daniel, Levit, Anna, Ghadermarzy, Navid, Oberoi, Jaspreet S., and Ronagh, Pooya

Subjects

FOS: Computer and information sciences, Computer Science::Machine Learning, Quantum Physics, Computer Science - Machine Learning, Nuclear and High Energy Physics, Computer Science - Artificial Intelligence, Computer Science - Neural and Evolutionary Computing, FOS: Physical sciences, General Physics and Astronomy, Statistical and Nonlinear Physics, Machine Learning (cs.LG), Theoretical Computer Science, Artificial Intelligence (cs.AI), Computational Theory and Mathematics, Optimization and Control (math.OC), FOS: Mathematics, Neural and Evolutionary Computing (cs.NE), Quantum Physics (quant-ph), Mathematics - Optimization and Control, Mathematical Physics

Abstract

We investigate whether quantum annealers with select chip layouts can outperform classical computers in reinforcement learning tasks. We associate a transverse field Ising spin Hamiltonian with a layout of qubits similar to that of a deep Boltzmann machine (DBM) and use simulated quantum annealing (SQA) to numerically simulate quantum sampling from this system. We design a reinforcement learning algorithm in which the set of visible nodes representing the states and actions of an optimal policy are the first and last layers of the deep network. In absence of a transverse field, our simulations show that DBMs are trained more effectively than restricted Boltzmann machines (RBM) with the same number of nodes. We then develop a framework for training the network as a quantum Boltzmann machine (QBM) in the presence of a significant transverse field for reinforcement learning. This method also outperforms the reinforcement learning method that uses RBMs.

Published

2018

10. The Problem of Dynamic Programming on a Quantum Computer

Author

Ronagh, Pooya

Subjects

FOS: Computer and information sciences, Quantum Physics, Optimization and Control (math.OC), Computer Science - Data Structures and Algorithms, FOS: Mathematics, FOS: Physical sciences, Data Structures and Algorithms (cs.DS), Quantum Physics (quant-ph), Mathematics - Optimization and Control

Abstract

We discuss the problem of finite-horizon dynamic programming (DP) on a quantum computer. We introduce a query model for studying quantum and classical algorithms for solving DP problems, and provide example oracle constructions for the travelling salesperson problem, the minimum set-cover problem, and the edit distance problem. We formulate open questions regarding quadratic quantum speedups for DP and discuss their implications. We then prove lower bounds for the query complexity of quantum algorithms and classical randomized algorithms for DP, and show that no greater-than-quadratic speedup can be achieved for solving DP problems., We were not able to amend the proof of Theorem III.5 of the previous version (v2) of this manuscript. Therefore, we have hereby withdrawn the query complexity upper bound claims that were stated in our earlier submission

Published

2019

11. Free energy-based reinforcement learning using a quantum processor

Author

Levit, Anna, Crawford, Daniel, Ghadermarzy, Navid, Oberoi, Jaspreet S., Zahedinejad, Ehsan, and Ronagh, Pooya

Subjects

FOS: Computer and information sciences, Computer Science - Learning, Quantum Physics, Artificial Intelligence (cs.AI), Optimization and Control (math.OC), Computer Science - Artificial Intelligence, FOS: Mathematics, FOS: Physical sciences, Computer Science - Neural and Evolutionary Computing, Neural and Evolutionary Computing (cs.NE), Quantum Physics (quant-ph), Mathematics - Optimization and Control, Machine Learning (cs.LG)

Abstract

Recent theoretical and experimental results suggest the possibility of using current and near-future quantum hardware in challenging sampling tasks. In this paper, we introduce free energy-based reinforcement learning (FERL) as an application of quantum hardware. We propose a method for processing a quantum annealer's measured qubit spin configurations in approximating the free energy of a quantum Boltzmann machine (QBM). We then apply this method to perform reinforcement learning on the grid-world problem using the D-Wave 2000Q quantum annealer. The experimental results show that our technique is a promising method for harnessing the power of quantum sampling in reinforcement learning tasks.

Published

2017