| Holographic Shack–Hartmann wavefront sensor based on the correlation peak displacement detection method for wavefront sensing with large dynamic range Y Saita, H Shinto, T Nomura Optica 2 (5), 411-415, 2015 | 57 | 2015 |
| Motionless optical scanning holography N Yoneda, Y Saita, T Nomura Optics Letters 45 (12), 3184-3187, 2020 | 40 | 2020 |
| Shack–Hartmann wavefront sensor with large dynamic range by adaptive spot search method H Shinto, Y Saita, T Nomura Applied Optics 55 (20), 5413-5418, 2016 | 38 | 2016 |
| Single-shot higher-order transport-of-intensity quantitative phase imaging based on computer-generated holography N Yoneda, A Onishi, Y Saita, K Komuro, T Nomura Optics Express 29 (4), 4783-4801, 2021 | 30 | 2021 |
| Binary computer-generated-hologram-based holographic data storage N Yoneda, Y Saita, T Nomura Applied optics 58 (12), 3083-3090, 2019 | 26 | 2019 |
| Transport-of-intensity holographic data storage based on a computer-generated hologram N Yoneda, Y Saita, K Komuro, T Nobukawa, T Nomura Applied Optics 57 (30), 8836-8840, 2018 | 26 | 2018 |
| Improvement of image quality of 3D display by using optimized binary phase modulation and intensity accumulation K Masuda, Y Saita, R Toritani, P Xia, K Nitta, O Matoba Journal of Display Technology 12 (5), 472-477, 2016 | 25 | 2016 |
| Computer-generated-hologram-based holographic data storage using common-path off-axis digital holography N Yoneda, Y Saita, T Nomura Optics Letters 45 (10), 2796-2799, 2020 | 24 | 2020 |
| Three-dimensional fluorescence imaging through dynamic scattering media by motionless optical scanning holography N Yoneda, Y Saita, T Nomura Applied Physics Letters 119 (16), 2021 | 22 | 2021 |
| Spatially divided phase-shifting motionless optical scanning holography N Yoneda, Y Saita, T Nomura OSA Continuum 3 (12), 3523-3535, 2020 | 18 | 2020 |
| Common-path off-axis single-pixel holographic imaging N Yoneda, Y Saita, T Nomura Optics Express 30 (11), 18134-18144, 2022 | 12 | 2022 |
| Common-path angular-multiplexing holographic data storage based on computer-generated holography N Yoneda, T Nobukawa, T Morimoto, Y Saita, T Nomura Optics Letters 46 (12), 2920-2923, 2021 | 10 | 2021 |
| Design method of input phase mask to improve light use efficiency and reconstructed image quality for holographic memory Y Saita, T Nomura Applied Optics 53 (19), 4136-4140, 2014 | 10 | 2014 |
| Design of reference pattern and input phase mask for coaxial holographic memory Y Saita, T Nomura, E Nitanai, T Numata Japanese Journal of Applied Physics 50 (9S1), 09ME03, 2011 | 9 | 2011 |
| Single-shot compressive hyperspectral imaging with dispersed and undispersed light using a generally available grating Y Saita, D Shimoyama, R Takahashi, T Nomura Applied Optics 61 (5), 1106-1111, 2022 | 8 | 2022 |
| Multiplexed recording based on the reference wave correlation for computer-generated holographic data storage Y Saita, A Matsumoto, N Yoneda, T Nomura Optical Review 27, 391-398, 2020 | 7 | 2020 |
| Polarization imaging by use of optical scanning holography N Yoneda, Y Saita, T Nomura Optical Review 30 (1), 26-32, 2023 | 5 | 2023 |
| Large dynamic range wavefront sensing using Shack-Hartmann wavefront sensor based on pattern correlations Y Saita, T Nomura Optical Design and Testing VIII 10815, 57-62, 2018 | 3 | 2018 |
| Wavefront measurement with large dynamic range using holographic Shack-Hartmann wavefront sensor Y Saita, H Shinto, T Nomura 2015 14th Workshop on Information Optics (WIO), 1-3, 2015 | 3 | 2015 |
| Quantitative phase imaging based on motionless optical scanning holography N Yoneda, O Matoba, Y Saita, T Nomura Optics Letters 48 (20), 5273-5276, 2023 | 2 | 2023 |