Go, Tae-Sik
- Major
- Biomedical-optics
- Position
- Assistant Professor
- Phone Number
- +82 63-270-4064
- Mobile Phone
- Ph.D.
- tsgo@jbnu.ac.kr
- Research Field
- Biomedical Optics
- Office
- Engineering College Building 1, 350
Career
Papers
▪ Accurate real-time monitoring of high particulate matter concentration based on holographic speckles and deep learning, Journal of Hazardous Materials, 409, 124637, 2021
▪ Three-dimensional volumetric monitoring of settling particulate matters on a leaf using digital in-line holographic microscopy, Journal of Hazardous Materials, 404, 124116, 2021
▪ Deep learning-based hologram generation using a white light source, Scientific Reports, 10(1), 1-12, 2020
▪ Deep learning-based accurate and rapid tracking of 3D positional information of microparticles using digital holographic microscopy, Experiments in Fluids, 60(11), 170, 2019
▪ Air spreading through the wetted cellulose membranes, Physical Review E, 100(3), 032409, 2019
▪ Deep learning-based digital holographic microscopy for high resolution with extended field of view, Optics and Laser Technology, 113, 77-86, 2019
▪ Learning-based automatic sensing and size classification of microparticles using smartphone digital holographic microscopy, Analyst, 144(5), 1751-1760, 2019
▪ Removal of fine particulate matter (PM2.5) via atmospheric humidity caused by plant transpiration, Environmental pollution, 245, 253-259, 2019
▪ Machine learning-based in-line holographic sensing of unstained malaria-infected red blood cells, Journal of Biophotonics, 11(9), e201800101, 2018
▪ Digital stereo-holographic microscopy for studying 3D particle dynamics, Optics and Lasers in Engineering, 105, 6-13, 2018
▪ Label-free sensor for automatic identification of erythrocytes using digital in-line holographic microscopy and machine learning, Biosensors and Bioelectronics, 103, 12-18, 2018
▪ Label-free sensing and classification of old stored blood, Annals of Biomedical Engineering, 45(11), 2563-2573, 2017
▪ Focusing and alignment of erythrocytes in a viscoelastic medium, Scientific Reports, 7, 41162, 2017
▪ Three-dimensional swimming motility of microorganism in the near-wall region, Experiments in Fluids, 57(2), 26, 2016
▪ Precise measurement of orientations of transparent ellipsoidal particles through digital holographic microscopy, Optics Express, 24(1), 598-610, 2016
▪ Three-dimensional volumetric monitoring of settling particulate matters on a leaf using digital in-line holographic microscopy, Journal of Hazardous Materials, 404, 124116, 2021
▪ Deep learning-based hologram generation using a white light source, Scientific Reports, 10(1), 1-12, 2020
▪ Deep learning-based accurate and rapid tracking of 3D positional information of microparticles using digital holographic microscopy, Experiments in Fluids, 60(11), 170, 2019
▪ Air spreading through the wetted cellulose membranes, Physical Review E, 100(3), 032409, 2019
▪ Deep learning-based digital holographic microscopy for high resolution with extended field of view, Optics and Laser Technology, 113, 77-86, 2019
▪ Learning-based automatic sensing and size classification of microparticles using smartphone digital holographic microscopy, Analyst, 144(5), 1751-1760, 2019
▪ Removal of fine particulate matter (PM2.5) via atmospheric humidity caused by plant transpiration, Environmental pollution, 245, 253-259, 2019
▪ Machine learning-based in-line holographic sensing of unstained malaria-infected red blood cells, Journal of Biophotonics, 11(9), e201800101, 2018
▪ Digital stereo-holographic microscopy for studying 3D particle dynamics, Optics and Lasers in Engineering, 105, 6-13, 2018
▪ Label-free sensor for automatic identification of erythrocytes using digital in-line holographic microscopy and machine learning, Biosensors and Bioelectronics, 103, 12-18, 2018
▪ Label-free sensing and classification of old stored blood, Annals of Biomedical Engineering, 45(11), 2563-2573, 2017
▪ Focusing and alignment of erythrocytes in a viscoelastic medium, Scientific Reports, 7, 41162, 2017
▪ Three-dimensional swimming motility of microorganism in the near-wall region, Experiments in Fluids, 57(2), 26, 2016
▪ Precise measurement of orientations of transparent ellipsoidal particles through digital holographic microscopy, Optics Express, 24(1), 598-610, 2016