Demonstrating robust simulation of driven-dissipative problems on near-term quantum computers

Rost, Brian; Del Re, Lorenzo; Earnest, Nathan; Kemper, Alexander F.; Jones, Barbara; Freericks, James K.

doi:10.48550/arxiv.2108.01183

Cited by 11 publications

(15 citation statements)

References 26 publications

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“…In this regime, we may find practical simulation advantages. However, NISQ devices have yet to show a simulation advantage [90], [91], [92], [93], [94], [95]. Nevertheless, NISQ devices are predicted to provide simulation advantages in the near-term [96], [27] As an aside, we note that larger networks can be simulated using smaller quantum devices where an exponential increase in the number of circuit evaluations is accrued [97], [98].…”

Section: B Scaling Vqo For Practical Advantages On Quantum Computersmentioning

confidence: 99%

Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks

Doolittle

Bromley

Killoran

et al. 2023

IEEE Trans. Quantum Eng.

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The noise and complexity inherent to quantum communication networks leads to technical challenges in designing quantum network protocols using classical methods. We address this issue with a hybrid variational quantum optimization framework (VQO) that simulates quantum networks on quantum hardware and optimizes the simulation using differential programming. We maximize nonlocality in noisy quantum networks to showcase our VQO framework. Using a classical simulator we investigate the noise robustness of quantum nonlocality. Our VQO methods reproduce known results and uncover novel phenomena. We find that maximally entangled states maximize nonlocality in the presence of unital qubit channels, while nonmaximally entangled states can maximize nonlocality in the presence of nonunital qubit channels. Thus, we show VQO to be a practical design tool for quantum networks even when run on a classical simulator. Finally, using IBM quantum computers we demonstrate that our VQO framework can maximize nonlocality on noisy quantum hardware. In the long-term, our VQO techniques show promise of scaling beyond classical approaches and can be deployed on quantum network hardware to optimize network protocols against their inherent noise.

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Section: B Scaling Vqo For Practical Advantages On Quantum Computersmentioning

confidence: 99%

Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks

Doolittle

Bromley

Killoran

et al. 2023

IEEE Trans. Quantum Eng.

View full text Add to dashboard Cite

show abstract

“…In this regime, we may find practical simulation advantages. However, NISQ devices have yet to show a simulation advantage [89][90][91][92][93][94]. Nevertheless, NISQ devices are predicted to provide simulation advantages in the near-term [32,95] As an aside, we note that larger networks can be simulated using smaller quantum devices where an exponential increase in the number of circuit evaluations is accrued [96,97].…”

Section: B Scaling Vqo For Practical Advantages On Quantum Computersmentioning

confidence: 99%

Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks

Doolittle¹,

Bromley²,

Killoran³

et al. 2022

Preprint

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The inherent noise and complexity of quantum communication networks leads to challenges in designing quantum network protocols using classical methods. To address this issue, we develop a variational quantum optimization framework that simulates quantum networks on quantum hardware and optimizes the network using differential programming techniques. We use our hybrid framework to optimize nonlocality in noisy quantum networks. On the noisy IBM quantum computers, we demonstrate our framework's ability to maximize quantum nonlocality. On a classical simulator with a static noise model, we investigate the noise robustness of quantum nonlocality with respect to unital and nonunital channels. In both cases, we find that our optimization methods can reproduce known results, while uncovering interesting phenomena. When unital noise is present we find numerical evidence suggesting that maximally entangled state preparations yield maximal nonlocality. When nonunital noise is present we find that nonmaximally entangled states can yield maximal nonlocality. Thus, we show that variational quantum optimization is a practical design tool for quantum networks in the near-term. In the long-term, our variational quantum optimization techniques show promise of scaling beyond classical approaches and can be deployed on quantum network hardware to optimize quantum communication protocols against their inherent noise.

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“…Nevertheless, as quantum hardware and software improves, speedups relatively to classical simulation are expected to be observed (and some problems solved by quantum computing have been already shown to beat classical computing by a large factor [12,13]). In the context of quantum digital simulations of open quantum systems, several techniques have recently been proposed, such as using Kraus operators [14][15][16][17][18], solving the Lindblad equation with stochastic Schrödinger equations [19] or variationally [20], using the inherent decoherence of the quantum computer to implement the dissipative evolution [21,22], among others [23][24][25][26]. These techniques face some important issues, namely, the Kraus operators are hard to calculate in practice, Lindblad equations are restricted to Markovian environments and the natural decoherence of the quantum computer introduced by the qubits' environment is not fully controllable or its structure is not completely known, hence simulating arbitrary environments is hard.…”

Section: Introductionmentioning

confidence: 99%

Efficient method to simulate non-perturbative dynamics of an open quantum system using a quantum computer

Guimarães¹,

Vasilevskiy²,

Barbosa³

2022

Preprint

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Classical non-perturbative simulations of open quantum systems dynamics face several scalability problems, namely, exponential scaling as a function of either the time length of the simulation or the size of the open system. In this work, we propose a quantum computational method which we term as Quantum Time Evolving Density operator with Orthogonal Polynomials Algorithm (Q-TEDOPA), based on the known TEDOPA technique, avoiding any exponential scaling in simulations of non-perturbative dynamics of open quantum systems on a quantum computer. By performing an exact transformation of the Hamiltonian, we obtain only local nearest-neighbour interactions, making this algorithm suitable to be implemented in the current Noisy-Intermediate Scale Quantum (NISQ) devices. We show how to implement the Q-TEDOPA using an IBM quantum processor by simulating the exciton transport between two light-harvesting molecules in the regime of moderate coupling strength to a non-Markovian harmonic oscillator environment. Applications of the Q-TEDOPA span problems which can not be solved by perturbation techniques belonging to different areas, such as dynamics of quantum biological systems and strongly correlated condensed matter systems.

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Demonstrating robust simulation of driven-dissipative problems on near-term quantum computers

Cited by 11 publications

References 26 publications

Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks

Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks

Variational Quantum Optimization of Nonlocality in Noisy Quantum Networks

Efficient method to simulate non-perturbative dynamics of an open quantum system using a quantum computer

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