Autonomous illumination control for localization microscopy

Super-resolution fluorescence microscopy improves spatial resolution, but this comes at a loss of image throughput and presents unique challenges in identifying optimal acquisition parameters. Microscope automation routines can offset these drawbacks, but thus far have required user inputs that presume a priori knowledge about the sample. Here, we develop a flexible illumination control system for localization microscopy comprised of two interacting components that require no sample-specific inputs: a self-tuning controller and a deep learning-based molecule density estimator that is accurate over an extended range of densities. This system obviates the need to fine-tune parameters and enables robust, autonomous illumination control for localization microscopy. (C) 2018 Optical Society of America under the terms of the OSA Open Access Publishing Agreement.

Autonomous illumination control for localization microscopy

Koopman-based Data-driven Robust Control of Nonlinear Systems Using Integral Quadratic Constraints

Data-Driven Control and Optimization under Noisy and Uncertain Conditions

Localized model order reduction and domain decomposition methods for coupled heterogeneous systems

Koopman-based Data-driven Robust Control of Nonlinear Systems Using Integral Quadratic Constraints

Data-Driven Control and Optimization under Noisy and Uncertain Conditions

Localized model order reduction and domain decomposition methods for coupled heterogeneous systems