We propose Hamiltonian Quantum Generative Adversarial Networks (HQuGANs), to learn to generate unknown input quantum states using two competing quantum optimal controls. The game-theoretic framework of the algorithm is inspired by the success of classical generative adversarial networks in learning high-dimensional distributions. The quantum optimal control approach not only makes the algorithm naturally adaptable to the experimental constraints of near-term hardware, but also has the potential to provide a better convergence due to overparameterization compared to the circuit model implementations. We numerically demonstrate the capabilities of the proposed framework to learn various highly entangled many-body quantum states, using simple ...
We study classical and quantum learning algorithms with access to data produced by a quantum process...
Quantum control is valuable for various quantum technologies such as high-fidelity gates for univers...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2016.Cataloged from PD...
Quantum algorithms have the potential to outperform their classical counterparts in a variety of tas...
We introduce a new approach towards generative quantum machine learning significantly reducing the n...
Adversarial learning is one of the most successful approaches to modeling high-dimensional probabili...
The exploration of quantum algorithms that possess quantum advantages is a central topic in quantum ...
The goal of generative machine learning is to model the probability distribution underlying a given ...
Quantum computing is widely thought to provide exponential speedups over classical algorithms for a ...
The intrinsic probabilistic nature of quantum mechanics invokes endeavors of designing quantum gener...
The increasing success of classical generative adversarial networks (GANs) has inspired several quan...
The quantum alternating operator ansatz (QAOA) is a prominent example of variational quantum algorit...
Quantum Optimal Control (QOC) enables the realization of accurate operations, such as quantum gates,...
Quantum Computing leverages the quantum properties of subatomic matter to enable computations faster...
We show a divide and conquer approach for simulating quantum mechanical systems on quantum computers...
We study classical and quantum learning algorithms with access to data produced by a quantum process...
Quantum control is valuable for various quantum technologies such as high-fidelity gates for univers...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2016.Cataloged from PD...
Quantum algorithms have the potential to outperform their classical counterparts in a variety of tas...
We introduce a new approach towards generative quantum machine learning significantly reducing the n...
Adversarial learning is one of the most successful approaches to modeling high-dimensional probabili...
The exploration of quantum algorithms that possess quantum advantages is a central topic in quantum ...
The goal of generative machine learning is to model the probability distribution underlying a given ...
Quantum computing is widely thought to provide exponential speedups over classical algorithms for a ...
The intrinsic probabilistic nature of quantum mechanics invokes endeavors of designing quantum gener...
The increasing success of classical generative adversarial networks (GANs) has inspired several quan...
The quantum alternating operator ansatz (QAOA) is a prominent example of variational quantum algorit...
Quantum Optimal Control (QOC) enables the realization of accurate operations, such as quantum gates,...
Quantum Computing leverages the quantum properties of subatomic matter to enable computations faster...
We show a divide and conquer approach for simulating quantum mechanical systems on quantum computers...
We study classical and quantum learning algorithms with access to data produced by a quantum process...
Quantum control is valuable for various quantum technologies such as high-fidelity gates for univers...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Physics, 2016.Cataloged from PD...