New Frontiers in Machine Learning and Quantum

10 talks

November 22, 2022 - November 23, 2022

C22034

Collection TypeConference/School

Source RepositoryPIRSA

Description

This workshop will bring together a group of young trendsetters working at the frontier of machine learning and quantum information. The workshop will feature two days of talks, and ample time for participants to interact and form new collaborations in the inspiring environment of the Perimeter Institute. Topics will include machine learning, quantum field theory, quantum information, and unifying theoretical concepts.

https://pirsa.org/C22034

Territorial Land Acknowledgement

Perimeter Institute acknowledges that it is situated on the traditional territory of the Anishinaabe, Haudenosaunee, and Neutral peoples.

Perimeter Institute is located on the Haldimand Tract. After the American Revolution, the tract was granted by the British to the Six Nations of the Grand River and the Mississaugas of the Credit First Nation as compensation for their role in the war and for the loss of their traditional lands in upstate New York. Of the 950,000 acres granted to the Haudenosaunee, less than 5 percent remains Six Nations land. Only 6,100 acres remain Mississaugas of the Credit land.

We thank the Anishinaabe, Haudenosaunee, and Neutral peoples for hosting us on their land.

Displaying 1 - 10 of 10

Quantum adiabatic speedup on a class of combinatorial optimization problems
- Madelyn Cain Harvard University
- Madelyn Cain
November 22, 2022

PIRSA:22110083
Condensed Matter
Towards an artificial Muse for new ideas in Quantum Physics

Mario Krenn Max Planck Institute for the Science of Light
November 22, 2022

PIRSA:22110085
Condensed Matter
Matchgate Shadows for Fermionic Quantum Simulation
- Kianna Wan Alphabet (United States)
- Kianna Wan
November 22, 2022

PIRSA:22110086
Condensed Matter
Self-Correcting Quantum Many-Body Control using Reinforcement Learning with Tensor Networks

Friederike Metz L'Ecole Polytechnique Federale de Lausanne (EPFL)
November 22, 2022

PIRSA:22110087
Condensed Matter
A Study of Neural Network Field Theories

Anindita Maiti Perimeter Institute for Theoretical Physics
November 22, 2022

PIRSA:22110088
Condensed Matter
Quantum hypernetworks

Juan Carrasquilla ETH Zurich
November 22, 2022

PIRSA:22110089
Condensed Matter
Representing quantum states with spiking neural networks
- Stefanie Czischek University of Ottawa
- Stefanie Czischek
November 23, 2022

PIRSA:22110090
Condensed Matter
Adaptive Quantum State Tomography with Active Learning

Hannah Lange Ludwig-Maximilians-Universität München (LMU)
November 23, 2022

PIRSA:22110092
Condensed Matter
Gibbs Sampling of Periodic Potentials on a Quantum Computer

Arsalan Motamedi University of Waterloo
November 23, 2022

PIRSA:22110094
Condensed Matter
QuEra - quantum computing with neutral atoms:

Anna Knörr Harvard University
November 23, 2022

PIRSA:22110095
Condensed Matter

Quantum adiabatic speedup on a class of combinatorial optimization problems
- Madelyn Cain Harvard University
- Madelyn Cain
November 22, 2022

PIRSA:22110083
Condensed Matter
"One of the central challenges in quantum information science is to design quantum algorithms that outperform their classical counterparts in combinatorial optimization. In this talk, I will describe a modification of the quantum adiabatic algorithm (QAA) [1] that achieves a Grover-type speedup in solving a wide class of combinatorial optimization problem instances. The speedup is obtained over classical Markov chain algorithms including simulated annealing, parallel tempering, and quantum Monte Carlo. I will then introduce a framework to predict the relative performance of the standard QAA and classical Markov chain algorithms, and show problem instances with quantum speedup and slowdown. Finally, I will apply this framework to interpret results from a recent Rydberg atom array experiment [2], which suggest a superlinear speedup in solving the Maximum Independent Set problem on unit-disk graphs. [1] Farhi et al. (2001) Science 292, 5516 [2] Ebadi et al. (2022) Science 376, 6598"
Towards an artificial Muse for new ideas in Quantum Physics

Mario Krenn Max Planck Institute for the Science of Light
November 22, 2022

PIRSA:22110085
Condensed Matter
Matchgate Shadows for Fermionic Quantum Simulation
- Kianna Wan Alphabet (United States)
- Kianna Wan
November 22, 2022

PIRSA:22110086
Condensed Matter
In this talk, I'll describe new tomographic protocols for efficiently estimating various fermionic quantities, including both local observables (i.e., expectation values of local fermionic operators) and certain global properties (e.g., inner products between an unknown quantum state and arbitrary fermionic Gaussian states). Our protocols are based on classical shadows arising from random matchgate circuits. As a concrete application, they enable us to implement the recently introduced quantum-classical hybrid quantum Monte Carlo algorithm, without the exponential post-processing cost incurred by the original approach.
Self-Correcting Quantum Many-Body Control using Reinforcement Learning with Tensor Networks

Friederike Metz L'Ecole Polytechnique Federale de Lausanne (EPFL)
November 22, 2022

PIRSA:22110087
Condensed Matter
Self-Correcting Quantum Many-Body Control using Reinforcement Learning with Tensor Networks
A Study of Neural Network Field Theories

Anindita Maiti Perimeter Institute for Theoretical Physics
November 22, 2022

PIRSA:22110088
Condensed Matter
The backbones of modern-day Deep Learning, Neural Networks (NN), define field theories on Euclidean background through their architectures, where field interaction strengths depend on the choice of NN architecture width and stochastic parameters. Infinite width limit of NN architectures, combined with independently distributed stochastic parameters, lead to generalized free field theories by the Central Limit Theorem (CLT). Small and large deviations from the CLT, due to finite architecture width and/or correlated stochastic parameters, respectively give rise to weakly coupled field theories and non-perturbative non-Lagrangian field theories in Neural Networks. I will present a systematic exploration of Neural Network field theories via a dual framework of NN parameters: non-Gaussianity, locality by cluster decomposition, and symmetries are studied without necessitating the knowledge of an action. Such a dual description to statistical or quantum field theories in Neural Networks can have potential implications for physics.
Quantum hypernetworks

Juan Carrasquilla ETH Zurich
November 22, 2022

PIRSA:22110089
Condensed Matter
Representing quantum states with spiking neural networks
- Stefanie Czischek University of Ottawa
- Stefanie Czischek
November 23, 2022

PIRSA:22110090
Condensed Matter
Adaptive Quantum State Tomography with Active Learning

Hannah Lange Ludwig-Maximilians-Universität München (LMU)
November 23, 2022

PIRSA:22110092
Condensed Matter
Gibbs Sampling of Periodic Potentials on a Quantum Computer

Arsalan Motamedi University of Waterloo
November 23, 2022

PIRSA:22110094
Condensed Matter
"Motivated by applications in machine learning, we present a quantum algorithm for Gibbs sampling from continuous real-valued functions defined on high dimensional tori. We show that these families of functions satisfy a Poincare inequality. We then use the techniques for solving linear systems and partial differential equations to design an algorithm that performs zeroeth order queries to a quantum oracle computing the energy function to return samples from its Gibbs distribution. We further analyze the query and gate complexity of our algorithm and prove that the algorithm has a polylogarithmic dependence on approximation error (in total variation distance) and a polynomial dependence on the number of variables, although it suffers from an exponentially poor dependence on temperature."
QuEra - quantum computing with neutral atoms:

Anna Knörr Harvard University
November 23, 2022

PIRSA:22110095
Condensed Matter
QuEra is a quantum computing start up located in Boston, spinning off from the groups in the physics and engineering departments of Harvard and MIT. I have spent this fall working at QuEra and will introduce you to the company and its neutral-atom quantum computing technology.

Title	Speaker(s)	Date	Talk Type	Info
Quantum adiabatic speedup on a class of combinatorial optimization problems	Madelyn CainMadelyn Cain	2022-11-22	Conference	View details
Towards an artificial Muse for new ideas in Quantum Physics	Mario Krenn	2022-11-22	Conference	View details
Matchgate Shadows for Fermionic Quantum Simulation	Kianna WanKianna Wan	2022-11-22	Conference	View details
Self-Correcting Quantum Many-Body Control using Reinforcement Learning with Tensor Networks	Friederike Metz	2022-11-22	Conference	View details
A Study of Neural Network Field Theories	Anindita Maiti	2022-11-22	Conference	View details
Quantum hypernetworks	Juan Carrasquilla	2022-11-22	Conference	View details
Representing quantum states with spiking neural networks	Stefanie CzischekStefanie Czischek	2022-11-23	Conference	View details
Adaptive Quantum State Tomography with Active Learning	Hannah Lange	2022-11-23	Conference	View details
Gibbs Sampling of Periodic Potentials on a Quantum Computer	Arsalan Motamedi	2022-11-23	Conference	View details
QuEra - quantum computing with neutral atoms:	Anna Knörr	2022-11-23	Conference	View details

Supported by

New Frontiers in Machine Learning and Quantum

Format results

Quantum adiabatic speedup on a class of combinatorial optimization problems

Towards an artificial Muse for new ideas in Quantum Physics

Matchgate Shadows for Fermionic Quantum Simulation

Self-Correcting Quantum Many-Body Control using Reinforcement Learning with Tensor Networks

A Study of Neural Network Field Theories

Quantum hypernetworks

Representing quantum states with spiking neural networks

Adaptive Quantum State Tomography with Active Learning

Gibbs Sampling of Periodic Potentials on a Quantum Computer

QuEra - quantum computing with neutral atoms: