Using Deep Learning Artificial Neural Networks for Optimizations of Optical Alignment and Magneto-Optical Trap
Centre for Quantum Technologies via YouTube
Overview
Save Big on Coursera Plus. 7,000+ courses at $160 off. Limited Time Only!
Explore a physics colloquium presentation that demonstrates how deep learning artificial neural networks can revolutionize experimental optimizations in quantum physics. Discover the application of machine learning techniques for automating optical resonator alignment and improving magneto-optical trap performance. Learn how artificial neural networks can achieve high mode-matching efficiencies in laser-resonator coupling and interferometric visibility, eliminating time-consuming manual alignment processes. Examine how these networks tackle complex many-body interactions in high optical density atomic ensembles, revealing novel solutions that surpass traditional adiabatic approaches. Gain insights into how machine learning opens new pathways for understanding cooling and trapping dynamics in cold atomic ensembles, offering solutions that challenge conventional methodologies in quantum physics experimentation.
Syllabus
Using Deep Learning Artificial Neural Networks for Optimisations of Optical Alignment and...
Taught by
Centre for Quantum Technologies