Bose Einstein condensate as nonlinear block of a Machine Learning pipeline

• URL: http://arxiv.org/abs/2304.14905v1
• Date: Fri, 28 Apr 2023 15:26:18 GMT
• Title: Bose Einstein condensate as nonlinear block of a Machine Learning pipeline
• Authors: Maurus Hans, Elinor Kath, Marius Sparn, Nikolas Liebster, Felix Draxler, Christoph Schn\"orr, Helmut Strobel, Markus K. Oberthaler
• Abstract summary: We show how to embed the nonlinear evolution of a quantum gas in a Machine Learning pipeline. We demonstrate successful regression and condensate of a nonlinear function using a quasi one-dimensional cloud of potassium atoms.
• Score: 0.7695660509846216
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Physical systems can be used as an information processing substrate and with that extend traditional computing architectures. For such an application the experimental platform must guarantee pristine control of the initial state, the temporal evolution and readout. All these ingredients are provided by modern experimental realizations of atomic Bose Einstein condensates. By embedding the nonlinear evolution of a quantum gas in a Machine Learning pipeline, one can represent nonlinear functions while only linear operations on classical computing of the pipeline are necessary. We demonstrate successful regression and interpolation of a nonlinear function using a quasi one-dimensional cloud of potassium atoms and characterize the performance of our system.

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