290 likes | 397 Views
Etude des nouveaux formats de modulation pour la montée en débit dans le réseau d'accès optique. 28/03/2008 – Journée de doctorant ENSTB. DUONG Thanh Nga Encardrant à FT: GENAY Naveena Directeur de thèse: SIMON Jean-Claude. Outline. 1. Introduction Contexte Experimentation
E N D
Etude des nouveaux formats de modulation pour la montée en débit dans le réseau d'accès optique 28/03/2008 – Journée de doctorant ENSTB DUONG Thanh Nga Encardrant à FT: GENAY Naveena Directeur de thèse: SIMON Jean-Claude
Outline 1 • Introduction • Contexte • Experimentation • Low-cost MB-OFDM for remote modulation of colorless ONU • Direct modulation of 2.5GHz DFB laser at a bit rate of 10Gbit/s • Conclusion and perspective 2 3
Outline 1 • Introduction • Contexte • Experimentation • Low-cost MB-OFDM for remote modulation of colorless ONU • Direct modulation of DFB laser at a bit rate of 10Gbit/s • Conclusion and perspective 2 3
1. Introduction (1)Interest of OFDM for the optical access network
1. Introduction (2)Interest of OFDM for the optical access network • Increase the capacity and decrease the cost of the system in optical access network • Increase the bit rate up to 10Gbit/s and more • Increase the transmission distance up to 100km without chromatic dispersion compensation • Fiber chromatic dispersion • Rayleigh Backscattering in architecture colorless ONU • Cost of system • Solution • Low-cost ONU module • Direct modulation of laser • To use advanced modulation format which is robust to fiber chromatic dispersion like DB, DPSK or OFDM modulation format
Spectre de DB, NRZ, DPSK et RZ Interest of OFDM • Duo-binary (DB) • Un spectre est plus comprimé que celui du NRZ • Plus tolérance à la dispersion chromatique • Détection simple • Complexité de l'émetteur • DPSK/DQPSK • Appliquer la technique remodulation • La complexité du récepteur → coût élevé • DPSK/DQPSK-ASK • Forte tolérance à la DC • La complexité de l'émetteur et du récepteur • Faible sensibilité au récepteur • OFDM • Technique de transmission multi-porteuses • Utiliser l'algorithme FFT/IFFT • Chaque sous-porteuse est modulé par un format de modulation numérique différent Le signal modulé DPSK
1. Introduction (3)Interest of OFDM for the optical access network • What is OFDM ? • Widely use in the radio communication • DAB (Digital Audio Broadcasting) • DVB-T (Digital Video Broadcasting-Terrestrial) • DRM (Digital Radio Mondiale) • Wireless system • Multi-carriers modulation format which uses a large number of closely-spaced orthogonal sub-carriers • Use FFT/IFFT algorithm • Each sub-carrier is modulated with a conventional modulation (QPSK, m-QAM, etc…)
1. Introduction (5)Interests of OFDM for optical access network • Why we use OFDM for optical access network? • High density of information (Bit/s/Hz) → increase the bit ratewithout increasing RF cost (using low bandwidth component) • More tolerant to fiber chromatic dispersion (multi-path resilience) and we can optimize the transmission performance by adjusting the modulation format on each sub-carrier → 10G compatible • Could be implemented with DSP technique on fast and low cost devices • Reuse existing development in radio system (ISO/IEC DIS26908 UWB standard for MB-OFDM) • Improve the transmission performance with the help of FEC (BER = 10-4 without FEC)
Outline 1 • Introduction • Contexte • Experimentation • Low-cost MB-OFDM for remote modulation of colorless ONU • Direct modulation of DFB laser at a bit rate of 10Gbit/s • Conclusion 2 3
CWDM 1xN ONU CW CW laser Remote modulation 20km Splitter OLT CW Rx 1.92Gbit/s OFDM 2. Experimentation (1)Low-cost MB-OFDM for remote modulation of colorless ONU • Bidirectional transmission on 20km single-fiber hybrid WDM/TDM-PON architecture • CW laser at 1550nm sent downstream • Upstream data was generated by MB-OFDM at 1.92Gbit/s (3 OFDM bands at a bit rate of 640Mbit/s for each band)
CW signal l1 OFDM Signal EAM CWDM SOA1 SOA2 Modulated upstream signal l1 2. Experimentation (2)Low-cost MB-OFDM for remote modulation of colorless ONU, EAM solution • Filter: CWDM having 0.6dB insertion losses and bandwidth of 20nm • EAM: 14dB insertion losses, 10dB extinction ratio and bandwidth of 12GHz • 2SOAs: 18dB optical gain • 3 OFDM bands centred at 744MHz, 1272MHz and 1800MHz. 128 sub-carriers modulated by QPSK format each band
upstream transmission for 1x16 splitting ratio BTB transmission, 2. Experimentation (3)Low-cost MB-OFDM for remote modulation of colorless ONU, EAM solution Received signal's constellation
1x16 BTB 6dB 2dB 1x8 2. Experimentation (4)Low-cost MB-OFDM for remote modulation of colorless ONU, EAM solution • Remote modulation was possible on a single fiber hybrid architecture • There are 2dB penalty for 1x8 splitting ratio and 6dB for 1x16 splitting ratio
NRZ EAM CWDM SOA1 SOA2 2. Experimentation (7)Comparison with NRZ signal
1x4 1x16 1x2 (pour 2Vp-p) 1x8 No splitter R-EAM solution EAM solution 2. Experimentation (8)Comparison with NRZ signal • Remote modulation was also possible on a single fiber hybrid architecture • Only a splitting ratio of 1x8 was achieved for EAM solution and no splitter could be added for R-EAM solution (at 1.3Vp-p input at R-EAM)-error floor for 1x2 splitting ratio at 2Vp-p
2. Experimentation (9)Comparison with NRZ signal For EAM solution
Discussion • OFDM modulation is a good candidate as a cost effective solution for colorless ONU • OFDM format is more tolerant to Rayleigh backscattering than NRZ format in a bidirectional link
Outline 1 • Introduction • Interest of OFDM modulation for the optical access network • Experimentation • Low-cost MB-OFDM for remote modulation of colorless ONU • Direct modulation of low-cost laser at a bit rate of 10Gbit/s • Conclusion 2 3
20km, 50km, 110km SMF DSP modulation S/P M-QAM mapper IFFT P/S DFB laser AWG Encoded data in AOV DSP demodulation Optical receiver A/D converter Encoded data out Negotiation between Tx and Rx 2. Experimentation (1)Direct modulation of DFB laser at a bit rate of 10Gbit/s • Direct modulation of 2.5GHz DFB laser by 10Gbit/s AMOOFDM signal • 64 sub-carriers • The m-QAM mapping varies from 4-QAM to 32-QAM • Transmission distance was taken to be 20km, 50km and 110km • No dispersion compensation
Sub No.1 Sub No.31 Sub No.10 Sub No.23 2. Experimentation (2)Direct modulation of DFB laser at a bit rate of 10Gbit/s
BERk is the bit error rate of kth sub-carrier • ND is the number of sub-carrier which contain the real data • The transmission is possible on 110km SMF • A BER of 10-3 was obtained at a received optical power of -16dBm • The penalties for 20km and 50km optical links are negligible (the sensibility is considering at BER of 10-4) • The penalty on 110km optical link was approximately 2dB because of chromatic dispersion 2. Experimentation (3)Direct modulation of low-cost laser at a bit rate of 10Gbit/s – DFB laser
2. Experimentation (4)Comparison with NRS modulation – DFB laser • Modulate directly with signal NRZ-OOK at a bit rate of 10Gb/s using the same DFB laser and receiver • There was an error-floor at a bit rate of 9x10-4 for BTB curve and at a bit rate of 3x10-2 for 20km transmission. • Transmission over 50km and 110km SMF were impossible due to the effect of chromatic dispersion AMOOFDM is more tolerant to fiber chromatic dispersion than NRZ-OOK signal
2. Experimentation (5)Comparison with NRZ modulation – 2.5GHz DFB laser
Discussion • AMOOFDM modulation is a good candidate as a cost effective solution for optical access network in order to increase the capacity (bit rate and transmission distance) • AMOOFDM format is more tolerant to fiber dispersion chromatic than NRZ format
1 2 3 Outline • Introduction • Contexte • Experimentation • Low-cost MB-OFDM for remote modulation of colorless ONU • Direct modulation of DFB laser at a bit rate of 10Gbit/s • Conclusion and perspective
3. Conclusion • A remote modulation scheme was presented for upstream transmission in hybrid WDM/TDM-PON single fiber architecture • A solutions are proposed for the colorless ONU: EAM solution. A bit rate of 1.92Gbit/s was archived for each wavelength • Comparison between NRZ and OFDM remote modulation for both solutions was performed • OFDM format is more robust to Rayleigh Backscattered light than NRZ-OOK modulation • 10Gb/s transmission is experimentally demonstrated over 110km SMF by direct modulation of 2GHz bandwidth DFB laser without dispersion compensation • A comparison between NRZ-OOK format and AMOOFDM format was performed at a bit rate of 10Gb/s • AMOOFDM modulation format is more tolerant with fiber chromatic dispersion than NRZ-OOK format
Thank you for your attention Any question ? This work was performed in the framework of E-Photon One network of excellence and the French ANTARES project
Annexe (1) • Definition of EVM
1. Introduction (4)Interest of OFDM for the optical access network