Your search keyword '"Jadan, Herman Verinaz"' showing total 11 results

1. Light-Field Microscopy for optical imaging of neuronal activity: when model-based methods meet data-driven approaches

Author

Song, Pingfan, Jadan, Herman Verinaz, Howe, Carmel L., Foust, Amanda J., and Dragotti, Pier Luigi

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning, Physics - Optics

Abstract

Understanding how networks of neurons process information is one of the key challenges in modern neuroscience. A necessary step to achieve this goal is to be able to observe the dynamics of large populations of neurons over a large area of the brain. Light-field microscopy (LFM), a type of scanless microscope, is a particularly attractive candidate for high-speed three-dimensional (3D) imaging. It captures volumetric information in a single snapshot, allowing volumetric imaging at video frame-rates. Specific features of imaging neuronal activity using LFM call for the development of novel machine learning approaches that fully exploit priors embedded in physics and optics models. Signal processing theory and wave-optics theory could play a key role in filling this gap, and contribute to novel computational methods with enhanced interpretability and generalization by integrating model-driven and data-driven approaches. This paper is devoted to a comprehensive survey to state-of-the-art of computational methods for LFM, with a focus on model-based and data-driven approaches., Comment: 20 pages, 9 figures, article accepted by IEEE Signal Processing Magazine

Published

2021

2. Model-inspired Deep Learning for Light-Field Microscopy with Application to Neuron Localization

Author

Song, Pingfan, Jadan, Herman Verinaz, Howe, Carmel L., Quicke, Peter, Foust, Amanda J., and Dragotti, Pier Luigi

Subjects

Electrical Engineering and Systems Science - Image and Video Processing, Computer Science - Computer Vision and Pattern Recognition

Abstract

Light-field microscopes are able to capture spatial and angular information of incident light rays. This allows reconstructing 3D locations of neurons from a single snap-shot.In this work, we propose a model-inspired deep learning approach to perform fast and robust 3D localization of sources using light-field microscopy images. This is achieved by developing a deep network that efficiently solves a convolutional sparse coding (CSC) problem to map Epipolar Plane Images (EPI) to corresponding sparse codes. The network architecture is designed systematically by unrolling the convolutional Iterative Shrinkage and Thresholding Algorithm (ISTA) while the network parameters are learned from a training dataset. Such principled design enables the deep network to leverage both domain knowledge implied in the model, as well as new parameters learned from the data, thereby combining advantages of model-based and learning-based methods. Practical experiments on localization of mammalian neurons from light-fields show that the proposed approach simultaneously provides enhanced performance, interpretability and efficiency., Comment: 5 pages, 6 figures, ICASSP 2021

Published

2021

3. Model-based Explainable Deep Learning for Light-field Microscopy Imaging

Author

Song, Pingfan, primary, Jadan, Herman Verinaz, additional, Howe, Carmel L., additional, Foust, Amanda J., additional, and Dragotti, Pier Luigi, additional

Published

2024

4. Model-Inspired Deep Learning for Light-Field Microscopy with Application to Neuron Localization

Author

Song, Pingfan, primary, Jadan, Herman Verinaz, additional, Howe, Carmel L., additional, Quicke, Peter, additional, Foust, Amanda J., additional, and Luigi Dragotti, Pier, additional

Published

2021

5. Comparing synthetic refocusing to deconvolution for the extraction of neuronal calcium transients from light-fields

Author

Howe, Carmel L., primary, Quicke, Peter, additional, Song, Pingfan, additional, Jadan, Herman Verinaz, additional, Dragotti, Pier Luigi, additional, and Foust, Amanda J., additional

Published

2020

6. Subcellular resolution 3D light field imaging with genetically encoded voltage indicators

Author

Quicke, Peter, primary, Howe, Carmel L., additional, Song, Pingfan, additional, Jadan, Herman Verinaz, additional, Song, Chenchen, additional, Knöpfel, Thomas, additional, Neil, Mark, additional, Dragotti, Pier Luigi, additional, Schultz, Simon R., additional, and Foust, Amanda J., additional

Published

2020

7. Comparing wide field to 3D light field for imaging red calcium transients in mammalian brain

Author

Howe, Carmel L., primary, Quicke, Peter, additional, Song, Pingfan, additional, Jadan, Herman Verinaz, additional, Dragotti, Pier Luigi, additional, and Foust, Amanda J., additional

Published

2020

8. 3D Localization for Light-Field Microscopy via Convolutional Sparse Coding on Epipolar Images

Author

Song, Pingfan, primary, Jadan, Herman Verinaz, additional, Howe, Carmel L., additional, Quicke, Peter, additional, Foust, Amanda J., additional, and Dragotti, Pier Luigi, additional

Published

2020

9. Calculation of high numerical aperture lightfield microscope point spread functions

Author

Quicke, Peter, primary, Howe, Carmel L., additional, Song, Pingfan, additional, Jadan, Herman Verinaz, additional, Dragotti, Pier Luigi, additional, Knopfel, Thomas, additional, Foust, Amanda J., additional, Schultz, Simon R., additional, and Neil, Mark, additional

Published

2019

10. Location Estimation for Light Field Microscopy based on Convolutional Sparse Coding

Author

Song, Pingfan, primary, Jadan, Herman Verinaz, additional, Quicke, Peter, additional, Howe, Carmel L., additional, Foust, Amanda J., additional, and Dragotti, Pier Luigi, additional

Published

2019

11. Light-Field Microscopy for Optical Imaging of Neuronal Activity: When Model-Based Methods Meet Data-Driven Approaches.

Author

Song P, Jadan HV, Howe CL, Foust AJ, and Dragotti PL

Abstract

Understanding how networks of neurons process information is one of the key challenges in modern neuroscience. A necessary step to achieve this goal is to be able to observe the dynamics of large populations of neurons over a large area of the brain. Light-field microscopy (LFM), a type of scanless microscope, is a particularly attractive candidate for high-speed three-dimensional (3D) imaging. It captures volumetric information in a single snapshot, allowing volumetric imaging at video frame-rates. Specific features of imaging neuronal activity using LFM call for the development of novel machine learning approaches that fully exploit priors embedded in physics and optics models. Signal processing theory and wave-optics theory could play a key role in filling this gap, and contribute to novel computational methods with enhanced interpretability and generalization by integrating model-driven and data-driven approaches. This paper is devoted to a comprehensive survey to state-of-the-art of computational methods for LFM, with a focus on model-based and data-driven approaches.

Published

2022