Bayesian Optimization With Improved Scalability and Derivative Information for Efficient Design of Nanophotonic Structures
Xavier Garcia‐Santiago, Sven Burger, Carsten Rockstuhl, Philipp‐Immanuel Schneider
Abstract
We propose the combination of forward shape derivatives and the use of an iterative inversion scheme for Bayesian optimization to find optimal designs of nanophotonic devices. This approach widens the range of applicability of Bayesian optmization to situations where a larger number of iterations is required and where derivative information is available. This was previously impractical because the computational efforts required to identify the next evaluation point in the parameter space became much larger than the actual evaluation of the objective function. We demonstrate an implementation of the method by optimizing a waveguide edge coupler.
Topics & Concepts
Bayesian optimizationComputer scienceScalabilityNanophotonicsBayesian probabilityIterative methodTestbedOptimal designInverse problemAlgorithmMathematical optimizationMathematicsArtificial intelligenceOpticsPhysicsMachine learningDatabaseComputer networkMathematical analysisAdvanced Multi-Objective Optimization AlgorithmsOrbital Angular Momentum in OpticsPhotonic and Optical Devices