Title :
Ultra-Dense, Single-Wavelength DFT-Spread OFDMA PON With Laserless 1.2 Gb/s ONU Ready for Silicon Photonics Integration
Author :
Schindler, P.C. ; Agmon, A. ; Wolf, S. ; Bonk, R. ; Meder, L. ; Meltsin, M. ; Ludwig, A. ; Schmogrow, R. ; Dreschmann, M. ; Meyer, J. ; Becker, J. ; Nazarathy, M. ; Ben-Ezra, S. ; Pfeiffer, T. ; Freude, W. ; Leuthold, J. ; Koos, C.
Author_Institution :
Inst. of Photonics & Quantum Electron., Karlsruhe Inst. of Technol., Karlsruhe, Germany
Abstract :
We introduce an ultra-dense network architecture designed for silicon photonics at the optical network unit (ONU). This network relies on only 3.333 GSa/s and 417 MSa/s converters at the OLT and ONU, respectively, and offers up to 12 Gbit/s of symmetric traffic in a single 12.5-GHz optical channel. Multiple access and lowest processing speeds at the ONU are enabled by choosing 10 DFT-spread OFDM subbands. We demonstrate this FDMA network architecture in a proof-of-principle experiment with up to eight 300-MBd 16QAM subbands offering a bidirectional data rate of 9.6 Gb/s. Real-time signal processing is realized for downstream transmission. Finally, we shortly address future improvements of this network architecture by employing integrated silicon photonics and analog signal processing to enable fine FDM for next-generation access networks.
Keywords :
OFDM modulation; discrete Fourier transforms; frequency division multiple access; passive optical networks; quadrature amplitude modulation; silicon; 16QAM subbands; DFT-spread OFDM subband; FDM; FDMA network architecture; OLT; analog signal processing; bidirectional data rate; bit rate 1.2 Gbit/s; bit rate 9.6 Gbit/s; downstream transmission; frequency 12.5 GHz; integrated silicon photonics; laserless ONU ready; next-generation access networks; optical channel; optical network unit; proof-of-principle experiment; real-time signal processing; silicon photonic integration; symmetric traffic; ultradense network architecture; ultradense single-wavelength DFT-spread OFDMA PON; Optical fibers; Optical mixing; Optical network units; Optical polarization; Optical receivers; Frequency division multiple-access; Optical Access Network; Optical fiber communication; Signal Processing; optical access network; optical fiber communication; signal processing;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2014.2386215
