Author_Institution :
Eng. Dept., Univ. of Roma Tre, Rome, Italy
Abstract :
Two new arrayed waveguide grating (AWG) architectures are presented, for flat-top multiplexing and for the generation of Nyquist sinc-shaped optical pulses. We demonstrate that an AWG, with a number of grating arms double with respect to a conventional configuration, and an input y-branch, is equivalent to a synchronized router, composed of a Mach-Zehnder interferometer and an AWG in tandem. The proposed device is more compact, with reduced losses and dispersion sensitivity, and a more flat-top frequency behavior. To generate and process a sinc-shaped optical pulse train, a new AWG is used, that implements the fractional Fourier transform (FrFT), followed by a dispersion compensating fiber. We use the time-lens effect and the chirped modulation introduced by a fully passive FrFT-AWG to optically transform a sinc -shaped transfer function into a sinc-shaped impulse response, and vice versa. Detailed AWG design guidelines for wavelength division multiplexing and orthogonal frequency division multiplexing are also provided, evidencing the different roles played by the two slab couplers, in a signal processing framework.
Keywords :
Fourier transforms; Nyquist criterion; OFDM modulation; arrayed waveguide gratings; chirp modulation; optical fibre couplers; optical fibre dispersion; optical information processing; optical modulation; transient response; wavelength division multiplexing; Mach-Zehnder interferometer; Nyquist sinc-shaped optical pulse generation; arrayed waveguide grating architecture; chirped modulation; fiber dispersion sensitivity; flat-top multiplexing; fractional Fourier transform; grating arms; loss reduction; orthogonal frequency division multiplexing; passive FrFT-AWG enhanced functionalities; signal processing framework; sinc-shaped impulse response; slab couplers; synchronized router; tandem; wavelength division multiplexing; Arrayed waveguide gratings; Couplers; OFDM; Optical pulses; Slabs; Transfer functions; Demultiplexing; Optical signal processing; demultiplexing; multiplexing; optical planar waveguides; optical signal processing; time division multiplexing; wavelength division multiplexing;
