Beam steering optical switches using LCOS: The 'ROSES' demonstrator

The design, assembly and performance of a prototype 1/spl times/8 reconfigurable holographic free-space switch is described. Central to the switch fabric is a ferroelectric liquid crystal (FLC) on silicon spatial light modulator (SLM) deposited with a 540/spl times/1 array of planar mirror strips. T...

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Bibliographic Details
Main Authors: Crossland, W.A., Manolis, I.G., Redmond, M.M., Tan, K.L., Wilkinson, T.D., Chu, H.H., Croucher, J., Handerek, V.A., Holmes, M.J., Parker, T., Bonas, I.G., Robertson, B., Warr, S.T., Franklin, R., Stace, C., White, H.J., Woolley, R.A., Henshall, G.
Format: Conference Proceeding
Language:English
Subjects:
Beam steering
Holographic optical components
Holography
Lenses
Liquid crystal on silicon
Optical fiber polarization
Optical switches
Optical waveguides
Prototypes
Routing
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Summary:The design, assembly and performance of a prototype 1/spl times/8 reconfigurable holographic free-space switch is described. Central to the switch fabric is a ferroelectric liquid crystal (FLC) on silicon spatial light modulator (SLM) deposited with a 540/spl times/1 array of planar mirror strips. The input and output ports to the switch are fabricated as a linear array of silica planar waveguides connected to single-mode fibres. The waveguide array and the single Fourier transform lens for the holographic replay system are housed in an optomechanical mount to provide stability. The switch operates at 1.55 /spl mu/m wavelength and has a designed optical bandwidth of >60 nm. The primary aim of the ROSES project was to develop the technology required to implement a large scale N/spl times/N holographic routing switch. As a first step towards this goal, a prototype polarisation independent linear 1/spl times/8 fibre optic routing switch was developed. The switch was designed to take a signal beam from a single mode fibre, and dynamically route it to one of eight single-mode output fibres. The switch consists of four main components: a waveguide array providing spatial fan-in to and from the input and output fibres, a Fourier lens, a reflective binary-phase FLC silicon backplane SLM that acts as a beam steering element, and a custom interface board.
ISSN:1099-4742
2376-8614
DOI:10.1109/LEOSST.2000.869685