We apply an online optimization process based on machine learning to the production of Bose-Einstein condensates (BEC). BEC is typically created with an exponential evaporation ramp that is optimal for ergodic dynamics with two-body s-wave interactions and no other loss rates, but likely sub-optimal for real experiments. Through repeated machine-controlled scientific experimentation and observations our 'learner' discovers an optimal evaporation ramp for BEC production. In contrast to previous work, our learner uses a Gaussian process to develop a statistical model of the relationship between the parameters it controls and the quality of the BEC produced. We demonstrate that the Gaussian process machine learner is able to discover a ramp th...
Machine learning models can learn complex relationships from data and have led to breakthrough resul...
Since Feynman's realization of using quantum systems to investigate quantum dynamics, interest in cr...
My PhD thesis presents three applications of machine learning to condensed matter theory. Firstly, I...
We apply an online optimization process based on machine learning to the production of Bose-Einstein...
We apply three machine learning strategies to optimize the atomic cooling processes utilized in the ...
Machine learning is emerging as a technology that can enhance physics experiment execution and data ...
We introduce a novel remote interface to control and optimize the experimental production of Bose-Ei...
The control and manipulation of quantum systems without excitation are challenging, due to the compl...
We introduce a remote interface to control and optimize the experimental production of Bose-Einstein...
This thesis illustrates the use of machine learning algorithms and exact numerical methods to study ...
High-dimensional optimization is a critical challenge for operating large-scale scientific facilitie...
In ultracold-atom experiments, data often comes in the form of images which suffer information loss ...
We apply on-the-fly machine learning potentials (MLPs) using the sparse Gaussian process regression ...
Single-shot images are the standard readout of experiments with ultracold atoms, the imperfect refle...
Atom chips are an excellent tool for studying ultracold degenerate quantum gases, due to the high de...
Machine learning models can learn complex relationships from data and have led to breakthrough resul...
Since Feynman's realization of using quantum systems to investigate quantum dynamics, interest in cr...
My PhD thesis presents three applications of machine learning to condensed matter theory. Firstly, I...
We apply an online optimization process based on machine learning to the production of Bose-Einstein...
We apply three machine learning strategies to optimize the atomic cooling processes utilized in the ...
Machine learning is emerging as a technology that can enhance physics experiment execution and data ...
We introduce a novel remote interface to control and optimize the experimental production of Bose-Ei...
The control and manipulation of quantum systems without excitation are challenging, due to the compl...
We introduce a remote interface to control and optimize the experimental production of Bose-Einstein...
This thesis illustrates the use of machine learning algorithms and exact numerical methods to study ...
High-dimensional optimization is a critical challenge for operating large-scale scientific facilitie...
In ultracold-atom experiments, data often comes in the form of images which suffer information loss ...
We apply on-the-fly machine learning potentials (MLPs) using the sparse Gaussian process regression ...
Single-shot images are the standard readout of experiments with ultracold atoms, the imperfect refle...
Atom chips are an excellent tool for studying ultracold degenerate quantum gases, due to the high de...
Machine learning models can learn complex relationships from data and have led to breakthrough resul...
Since Feynman's realization of using quantum systems to investigate quantum dynamics, interest in cr...
My PhD thesis presents three applications of machine learning to condensed matter theory. Firstly, I...