1.6 Gbit/s Synchronous Optical QPSK Transmission with Standard DFB Lasers in Realtime

1 1.6 Gbit/s Synchronous Optical QPSK Transmission with Standard DFB Lasers in Realtime S. Hoffmann, T. Pfau, R. Peveling, S. Bhandare, O. Adamczyk, M. Porrmann, R. Noé Univ. Paderborn, EIM-E Optical Communication and High-Frequency Engineering Prof. Dr.-Ing. Reinhold Noé System and Circuit Technology Prof. Dr.-Ing. Ulrich Rückert

2 Outline Properties of synchronous optical QPSK Mathematical Description of Receiver Measurement Results Conclusions

3 Properties of synchronous optical QPSK 4 bit/symbol (with added polarization division multiplex) lower cost per bit Symbol rate: 40 Gbaud may suffer from nonlinear phase noise. 10 Gbaud (= 4 x 10 Gbit/s) is perfect for evolutionary retrofitting of 40 Gbit/s transponders into existing 10 Gbit/s WDM systems. Electrical received signals are proportional to optical fields: Optical equalization of CD and PMD in the electrical domain becomes possible. DFB lasers are a must, since external cavity lasers are too costly and spaceconsuming. Possible for synchronous QPSK with feed-forward carrier recovery

Mathematical description Demodulation of the QPSK signal 4 E E S LO ce e j j ( ω t+ ϕ ) S ( ω t+ ϕ ) LO S LO E S l 11 Re{X} Setting of 90 hybrid: ( l l ) ( l l ) 11 21 12 22 = λ 4 LO E LO l 22 l 21 l 12 X * ~ E S E LO Im{X} X = Re{ X} + j Im{ X} = ce jϕ ' ϕ' = ( ω ω ) + ( ϕ ) S LO t S ϕlo Automatic frequency control & carrier recovery needed!

Mathematical description Analog carrier recovery 5 X c e jϕ delay demodulator D frequency multipliers X 4 filter Y -1 Z ( )* C ( )* regenerative frequency dividers C* e jϕ All signals are complex! General complex multiplier requires 4 real multipliers (Gilbert cells) and 2 adders/subtractors Frequency multiplication by a factor of 4 removes QPSK modulation Lowpass filtering of frequency-quadrupled carrier Frequency division of baseband intradyne signals by a factor of 4, using two regenerative frequency dividers: e jωt = e j2ωt e jωt

Differential encoding of angle quadrant number in transmitter Mathematical description Digital carrier recovery TX fiber LO E S E LO l 11 l 22 l 21 l 12 Re X Im X A/D and 1:M DEMUX Mod. M Mod. 2 Mod. 1 Functionally identical with analog scheme demultiplexed output data bits o 1, o 2 X ~ E TX E LO * 6 Module (i mod M) All signals it needs from neighbor modules are already available. X(i) ( ) 4 (X(i))4 (X(i 1)) 4 (X(i 2)) 4 (X(i 2N)) 4 Frequency quadrupling LPF X(i N) Lowpass filtering Y(i) Signal phase ψ(i) arg( ) n r (i 1) (1/4)arg( ( )) ϕ(i) Carrier phase angle ϕ(i 1) n j (i) Quadrant phase number (0, 1, 2, 3) n r (i) n o (i) o 1 (i), o 2 (i) Differential decoding of quadrant phase number, taking carrier phase jumps into account

7 Laser linewidth tolerance of QPSK feedforward carrier recovery log(ber) -4 QPSK (single polarization) log(ber) -4 QPSK with polarization division multiplex -6 f T = 0.001-6 f T = 0.0015-8 -10-12 Ideal receiver with perfectly recovered carrier f T = 0-8 -10-12 Ideal receiver with perfectly recovered carrier f T = 0-14 8 10 12 14 16 10 log(photons/bit) -14 8 10 12 14 16 10 log(photons/bit) For single/dual polarization QPSK, f T 0.0005 or 0.001 is tolerable. Dual polarizations double carrier recovery SNR and allow to double filter bandwidth. Distribution of residual phase error ϕ is determined by simulation of 5 10 5 symbols. Resulting decision errors are found by evaluating an analytical BER( ϕ) formula. Decision errors yield double bit errors due to differential encoding. Additional cycle slips of frequency divider contribute single bit errors due to differential angle encoding/decoding.

Univ. Paderborn Signal processing component development 8 Development of advanced carrier recovery algorithms System level component simulation 10 Gsps analog digital converter 0.25µm SiGe technology 5 bit Gray coded differential outputs Carrier & data recovery realized in CMOS 1:16 Demultiplexer CMOS clock: 625 MHz Sebastian Hoffmann, Timo Pfau, Olaf Adamczyk, Ralf Peveling, Mario Porrmann, Reinhold Noé: Hardware Efficient and Phase Noise Tolerant Digital Synchronous QPSK Receiver Concept, Proc. OAA/COTA2006, CThC6, June 25-30, 2006, Whistler, Canada.

9 Realtime digital synchronous intradyne QPSK transmission setup 800 MHz clock signal Signal laser DFB PRBS QPSK modulator Data rate: 800 Mbaud (1.6 Gb/s) SMF Manual polarization control automatic power control DFB Commercial 5 bit ADCs, clocked at 800 MHz Clock recovery in the receiver LO Laser Automatic LO frequency control implemented LiNbO 3 90º optical hybrid Noisy optical front ends, much too wide optical filter (~20 GHz) I Recovered clock Q automatic frequency control electronic sampling, carrier + data recovery ADC ADC Xilinx Virtex II FPGA data 0 data 1

10 Results obtained with unmodulated DFB lasers 4 MHz 5 db due to reflections? 10 MHz Intradyne (I & Q) phasor in the complex plane, measured after 90 hybrid and photodetection IF spectrum, here stabilized at 400 MHz rather than 0 MHz. Spectrum looks the same when the IF was stabilized at 0 MHz.

11 Intradyne transmission results, using DFB lasers 800 Mbaud BER floors: 2.7 10 4 (2 7 1, 2 km), 3.4 10 4 (2 31 1, 2 km). Increased BER over 63 km may be due to lack of clock recovery combined with a noisy clock source. All BER floors within capability of FEC (7%) 1.5 Gb/s net data rate

12 Bit error ratio floor vs. linewidth times symbol duration product Unproblematic operation is expected at 10 Gbaud. Additional phase noise tolerance (factor 2) applies for polarization division multiplex.

13 Conclusions First realtime synchronous QPSK transmission with DFB lasers FEC-compatible performance at 800 Mbaud (1.6 Gb/s) Phase noise should be unproblematic at 10 Gbaud. 4 10 Gb/s synchronous QPSK transmission systems with polarization division multiplex can be developed, using DFB lasers. Acknowledgement European Commission FP6 contract 004631 http://ont.upb.de/synqpsk synqpsk Univ. Paderborn, Germany CeLight Israel Photline, France IPAG, Germany Univ. Duisburg-Essen, Germany