Quantum advantage for differential equation analysis
- URL: http://arxiv.org/abs/2010.15776v2
- Date: Tue, 26 Apr 2022 13:58:42 GMT
- Title: Quantum advantage for differential equation analysis
- Authors: Bobak T. Kiani, Giacomo De Palma, Dirk Englund, William Kaminsky,
Milad Marvian, Seth Lloyd
- Abstract summary: We show how the output of quantum differential equation solving can serve as the input for quantum machine learning.
These quantum algorithms provide an exponential advantage over existing classical Monte Carlo methods.
- Score: 13.39145467249857
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Quantum algorithms for both differential equation solving and for machine
learning potentially offer an exponential speedup over all known classical
algorithms. However, there also exist obstacles to obtaining this potential
speedup in useful problem instances. The essential obstacle for quantum
differential equation solving is that outputting useful information may require
difficult post-processing, and the essential obstacle for quantum machine
learning is that inputting the training set is a difficult task just by itself.
In this paper, we demonstrate, when combined, these difficulties solve one
another. We show how the output of quantum differential equation solving can
serve as the input for quantum machine learning, allowing dynamical analysis in
terms of principal components, power spectra, and wavelet decompositions. To
illustrate this, we consider continuous time Markov processes on
epidemiological and social networks. These quantum algorithms provide an
exponential advantage over existing classical Monte Carlo methods.
Related papers
- Efficient Learning for Linear Properties of Bounded-Gate Quantum Circuits [63.733312560668274]
Given a quantum circuit containing d tunable RZ gates and G-d Clifford gates, can a learner perform purely classical inference to efficiently predict its linear properties?
We prove that the sample complexity scaling linearly in d is necessary and sufficient to achieve a small prediction error, while the corresponding computational complexity may scale exponentially in d.
We devise a kernel-based learning model capable of trading off prediction error and computational complexity, transitioning from exponential to scaling in many practical settings.
arXiv Detail & Related papers (2024-08-22T08:21:28Z) - Evaluation of phase shifts for non-relativistic elastic scattering using quantum computers [39.58317527488534]
This work reports the development of an algorithm that makes it possible to obtain phase shifts for generic non-relativistic elastic scattering processes on a quantum computer.
arXiv Detail & Related papers (2024-07-04T21:11:05Z) - Hybrid Quantum-Classical Clustering for Preparing a Prior Distribution of Eigenspectrum [10.950807972899575]
We consider preparing the prior distribution and circuits for the eigenspectrum of time-independent Hamiltonians.
The proposed algorithm unfolds in three strategic steps: Hamiltonian transformation, parameter representation, and classical clustering.
The algorithm is showcased through applications to the 1D Heisenberg system and the LiH molecular system.
arXiv Detail & Related papers (2024-06-29T14:21:55Z) - Quantum Annealing for Single Image Super-Resolution [86.69338893753886]
We propose a quantum computing-based algorithm to solve the single image super-resolution (SISR) problem.
The proposed AQC-based algorithm is demonstrated to achieve improved speed-up over a classical analog while maintaining comparable SISR accuracy.
arXiv Detail & Related papers (2023-04-18T11:57:15Z) - Quantum Machine Learning: from physics to software engineering [58.720142291102135]
We show how classical machine learning approach can help improve the facilities of quantum computers.
We discuss how quantum algorithms and quantum computers may be useful for solving classical machine learning tasks.
arXiv Detail & Related papers (2023-01-04T23:37:45Z) - Quantum circuit debugging and sensitivity analysis via local inversions [62.997667081978825]
We present a technique that pinpoints the sections of a quantum circuit that affect the circuit output the most.
We demonstrate the practicality and efficacy of the proposed technique by applying it to example algorithmic circuits implemented on IBM quantum machines.
arXiv Detail & Related papers (2022-04-12T19:39:31Z) - Quantum Phase Recognition via Quantum Kernel Methods [6.3286116342955845]
We explore the power of quantum learning algorithms in solving an important class of Quantum Phase Recognition problems.
We numerically benchmark our algorithm for a variety of problems, including recognizing symmetry-protected topological phases and symmetry-broken phases.
Our results highlight the capability of quantum machine learning in predicting such quantum phase transitions in many-particle systems.
arXiv Detail & Related papers (2021-11-15T06:17:52Z) - Quantum amplitude damping for solving homogeneous linear differential
equations: A noninterferometric algorithm [0.0]
This work proposes a novel approach by using the Quantum Amplitude Damping operation as a resource, in order to construct an efficient quantum algorithm for solving homogeneous LDEs.
We show that such an open quantum system-inspired circuitry allows for constructing the real exponential terms in the solution in a non-interferometric.
arXiv Detail & Related papers (2021-11-10T11:25:32Z) - Quantum algorithms for quantum dynamics: A performance study on the
spin-boson model [68.8204255655161]
Quantum algorithms for quantum dynamics simulations are traditionally based on implementing a Trotter-approximation of the time-evolution operator.
variational quantum algorithms have become an indispensable alternative, enabling small-scale simulations on present-day hardware.
We show that, despite providing a clear reduction of quantum gate cost, the variational method in its current implementation is unlikely to lead to a quantum advantage.
arXiv Detail & Related papers (2021-08-09T18:00:05Z) - Information Scrambling in Computationally Complex Quantum Circuits [56.22772134614514]
We experimentally investigate the dynamics of quantum scrambling on a 53-qubit quantum processor.
We show that while operator spreading is captured by an efficient classical model, operator entanglement requires exponentially scaled computational resources to simulate.
arXiv Detail & Related papers (2021-01-21T22:18:49Z) - Quantum Solver of Contracted Eigenvalue Equations for Scalable Molecular
Simulations on Quantum Computing Devices [0.0]
We introduce a quantum solver of contracted eigenvalue equations, the quantum analogue of classical methods for the energies.
We demonstrate the algorithm though computations on both a quantum simulator and two IBM quantum processing units.
arXiv Detail & Related papers (2020-04-23T18:35:26Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.