The efficient characterization of quantum systems1, 2, 3, the verification of the operations of quantum devices4, 5, 6 and the validation of underpinning physical models7, 8, 9, are central challenges for quantum technologies10, 11, 12 and fundamental physics13, 14. The computational cost of such studies could be improved by machine learning enhanced by quantum simulators15, 16. Here we interface two different quantum systems through a classical channel—a silicon-photonics quantum simulator and an electron spin in a diamond nitrogen–vacancy centre—and use the former to learn the Hamiltonian of the latter via Bayesian inference. We learn the salient Hamiltonian parameter with an uncertainty of approximately 10−5. Furthermore, an observed sat...
Quantum computing is one of the most promising techniques for simulating physical systems that canno...
Mainstream machine-learning techniques such as deep learning and probabilistic programming rely heav...
68 pages, 39 Figures. Comments welcome. Implementation at https://github.com/BrianCoyle/IsingBornMac...
The efficient characterization of quantum systems1, 2, 3, the verification of the operations of quan...
Summary form only given. The efficient characterization and validation of the underlying model of a ...
Here we show the first experimental implementation of quantum Hamiltonian Learning, where a silicon-...
We present the experimental demonstration of quantum Hamiltonian learning. Using an integrated silic...
Identifying an accurate model for the dynamics of a quantum system is a vexing problem that underlie...
The efficient validation of quantum devices is critical for emerging technological applications. In ...
In this work we combine two distinct machine learning methodologies, sequential Monte Carlo and Baye...
In this work we combine two distinct machine learning methodologies, sequential Monte Carlo and Baye...
Large-scale quantum devices provide insights beyond the reach of classical simulations. However, for...
The goal of generative machine learning is to model the probability distribution underlying a given ...
Large faulttolerant universal gate quantum computers will provide a major speedup to a variety of ...
Quantum computing is one of the most promising techniques for simulating physical systems that canno...
Mainstream machine-learning techniques such as deep learning and probabilistic programming rely heav...
68 pages, 39 Figures. Comments welcome. Implementation at https://github.com/BrianCoyle/IsingBornMac...
The efficient characterization of quantum systems1, 2, 3, the verification of the operations of quan...
Summary form only given. The efficient characterization and validation of the underlying model of a ...
Here we show the first experimental implementation of quantum Hamiltonian Learning, where a silicon-...
We present the experimental demonstration of quantum Hamiltonian learning. Using an integrated silic...
Identifying an accurate model for the dynamics of a quantum system is a vexing problem that underlie...
The efficient validation of quantum devices is critical for emerging technological applications. In ...
In this work we combine two distinct machine learning methodologies, sequential Monte Carlo and Baye...
In this work we combine two distinct machine learning methodologies, sequential Monte Carlo and Baye...
Large-scale quantum devices provide insights beyond the reach of classical simulations. However, for...
The goal of generative machine learning is to model the probability distribution underlying a given ...
Large faulttolerant universal gate quantum computers will provide a major speedup to a variety of ...
Quantum computing is one of the most promising techniques for simulating physical systems that canno...
Mainstream machine-learning techniques such as deep learning and probabilistic programming rely heav...
68 pages, 39 Figures. Comments welcome. Implementation at https://github.com/BrianCoyle/IsingBornMac...