TY - GEN
T1 - Coded Aperture-Based Self-wavefront Interference Using Transverse Splitting Holography
AU - Joshi, Narmada
AU - Xavier, Agnes Pristy Ignatius
AU - Arockiaraj, Francis Gracy
AU - Rajeswary, Aravind Simon John Francis
AU - Juodkazis, Saulius
AU - Rosen, Joseph
AU - Tamm, Aile
AU - Anand, Vijayakumar
N1 - Publisher Copyright: © 2023 IEEE.
PY - 2023/1/1
Y1 - 2023/1/1
N2 - Self-wavefront interference transverse splitting holography (SWITSH) is a recently developed holographic technique to solve a fundamental problem in the manufacturing of large-area diffractive lenses. In SWITSH, a low NA diffractive lens modulates the light from an object, and the modulated light is interfered with light from the same object that reaches beyond the aperture of the diffractive lens. The resulting self-interference hologram is processed with the pre-recorded point spread hologram using the Lucy-Richardson-Rosen algorithm. Since the self-interference hologram is formed by collecting light beyond the NA of the diffractive lens, it acquires the object information corresponding to the higher spatial frequencies of the object. Consequently, a higher imaging resolution is obtained in SWITSH compared to that of direct imaging with a diffractive lens. In the proof-of-concept study, a resolution improvement of an order was demonstrated. However, the optical architecture of the first version of SWITSH was not optimal, as the strength of the self-interference signal was weak. In this study, we improve SWITSH using different coded apertures, such as axicon and spiral element. An improvement in the strength of the self-interference signal was noticed with the axicon and spiral element. Simulation and experimental results using a diffractive lens, axicon and spiral element are presented.
AB - Self-wavefront interference transverse splitting holography (SWITSH) is a recently developed holographic technique to solve a fundamental problem in the manufacturing of large-area diffractive lenses. In SWITSH, a low NA diffractive lens modulates the light from an object, and the modulated light is interfered with light from the same object that reaches beyond the aperture of the diffractive lens. The resulting self-interference hologram is processed with the pre-recorded point spread hologram using the Lucy-Richardson-Rosen algorithm. Since the self-interference hologram is formed by collecting light beyond the NA of the diffractive lens, it acquires the object information corresponding to the higher spatial frequencies of the object. Consequently, a higher imaging resolution is obtained in SWITSH compared to that of direct imaging with a diffractive lens. In the proof-of-concept study, a resolution improvement of an order was demonstrated. However, the optical architecture of the first version of SWITSH was not optimal, as the strength of the self-interference signal was weak. In this study, we improve SWITSH using different coded apertures, such as axicon and spiral element. An improvement in the strength of the self-interference signal was noticed with the axicon and spiral element. Simulation and experimental results using a diffractive lens, axicon and spiral element are presented.
KW - Lucy-Richardson-Rosen algorithm
KW - coded aperture imaging
KW - diffractive lens
KW - incoherent holography
KW - super-resolution
UR - http://www.scopus.com/inward/record.url?scp=85186490395&partnerID=8YFLogxK
U2 - 10.1109/NEleX59773.2023.10421591
DO - 10.1109/NEleX59773.2023.10421591
M3 - Conference contribution
T3 - 2023 International Conference on Next Generation Electronics, NEleX 2023
BT - 2023 International Conference on Next Generation Electronics, NEleX 2023
T2 - 2023 IEEE International Conference on Next Generation Electronics, NEleX 2023
Y2 - 14 December 2023 through 16 December 2023
ER -
