Title :
High-Throughput Continuous Beam Steering Using Rotating Polarization Gratings
Author :
Oh, Chulwoo ; Kim, Jihwan ; Muth, John ; Serati, Steve ; Escuti, Michael J.
Author_Institution :
Dept. of Electr. & Comput. Eng., North Carolina State Univ., Raleigh, CA, USA
Abstract :
A new beam steering concept comprising independently rotating, inline polarization gratings (PGs) is experimentally demonstrated. The approach, which we term Risley gratings, achieves high steering throughput within a large field-of-regard (FOR) in a fashion similar to Risley prisms, composed of wedged prisms. However, because PGs are patterned in thin liquid crystal layers, they enable a system with far less thickness, weight, and beam walk-off. Furthermore, large apertures are feasible and wavelengths from visible to infrared can be chosen. Any direction within a solid angle defined by twice the diffraction angle of each PG can be addressed mechanically. Here we demonstrate a Risley grating system with a 62?? FOR and 89%-92% transmittance at 1550-nm wavelength, using two PGs with 6-??m grating period.
Keywords :
beam steering; diffraction gratings; infrared spectra; integrated optics; light diffraction; light polarisation; liquid crystal devices; nematic liquid crystals; optical prisms; Risley gratings; Risley prism; apertures; beam walk-off; diffraction angle; distance 6 mum; high-throughput continuous beam steering; inline polarization gratings; large field-of-regard; rotating polarization gratings; solid angle; thin liquid crystal layers; transmittance; wavelength 1550 nm; wedged prisms; Beam steering; Risley prism; diffraction; polarization grating (PG);
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2009.2037155
