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Simulation of All-optical Packet Routing employing PPM-based Header Processing in Photonic Packet Switched Core Network H. Le Minh, Z. Ghassemlooy and.

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Presentation on theme: "Simulation of All-optical Packet Routing employing PPM-based Header Processing in Photonic Packet Switched Core Network H. Le Minh, Z. Ghassemlooy and."— Presentation transcript:

1 Simulation of All-optical Packet Routing employing PPM-based Header Processing in Photonic Packet Switched Core Network H. Le Minh, Z. Ghassemlooy and Wai Pang Ng Optical Communications Research Group Northumbria University, UK First International Conference on Communications and Electronics HUT - ICCE 2006, 10th-11th Oct Hanoi, Vietnam

2 Contents Introduction PPM-Header Processing Overview
Operation principle Clock extraction PPM address conversion PPM header correlation All-optical flip-flop Wavelength conversion Simulation Results Summary

3 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

4 Introduction – All-optical network
Network transparency  All-optical core router Processing, switching and routing in optical domain  high throughput Packet format is preserved 1

5 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

6 Convert to pulse-position routing table
? OP 1 OP 2 OP 3 4-bit i 1001B = 9D Convert to pulse-position routing table Ref: [1] Z. Ghassemlooy et al., NOC 2005, UK, pp [2] Z. Ghassemlooy et al., ICTON 2005, Spain, Vol. 2, pp 2

7 (up to M input packets at M wavelengths)
Router Operation Principle Implementation OP 1 OP 2 OP 3 4-bit C1, is the recovered clock from the incoming . All Cs are multiplexed and feed into multiwavelength PPRT. The router is a non-blocking 1M router (up to M input packets at M wavelengths) 3

8 Router - PPM-HP PPM-HP module 4

9 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

10 Router - PPM-HP - Clock Extraction
Clk Clock, header and payload:- have the same intensity, polarization and wavelength Clock extraction requirements: Asynchronous and ultrafast response High on/off contrast ratio of extracted clock 5

11 Router - PPM-HP - Clock Extraction
CP1 Clk GCP 12 SOA1 12 SOA1 22 22 SMZ-1 SMZ-2 12 in 22 22 12 in 22 22 22 SW SOA2 SW 22 SOA2 CP2 Polarization Beam Splitter (PBS) Polarization Controller (PC) Optical fiber span Amplifier Attenuator Optical delay 6

12 Router - PPM-HP - Clock Extraction
GCP 12 SOA1 12 SOA1 22 22 SMZ-1 SMZ-2 12 in 22 22 12 in 22 22 22 SW SOA2 SW 22 SOA2 Polarization Beam Splitter (PBS) Polarization Controller (PC) Optical fiber span Amplifier Attenuator Optical delay 6

13 Router - PPM-HP - Clock Extraction
Clk GCP 12 SOA1 12 SOA1 22 22 SMZ-1 SMZ-2 12 in 22 22 12 in 22 22 22 SW SOA2 SW 22 SOA2 Polarization Beam Splitter (PBS) Polarization Controller (PC) Optical fiber span Amplifier Attenuator Optical delay 6

14 Router - PPM-HP - Clock Extraction
Input packets Extracted clock pulse by single SMZ. The residual signal intensities are high, but eventually fading due to SOA gain is saturated with the stream of high-powered control pulses Extracted clock pulse by two-inline SMZs. The residual signals are suppressed  improving the on/off contrast ratio (b) (c) Ref: Z. Ghassemlooy et al., ICTON 2006, UK, Vol. 4, pp 7

15 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

16 Router - PPM-HP - Address Conversion
(b) (b) (a) 8

17 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

18 Router - PPM-HP - Header Correlation
Matched xPPM(t) E2(t) SMZ-based AND gate: only one bit-wise operation! SOA gain recovery is no longer an issue, since it is saturated only once for header recognition Ref: R. P. Schreieck et al., IEEE Quantum Elec., Vol. 38, pp , 2002 9

19 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

20 Router - PPM-HP - All-optical Flip-Flop
Operate at < nanoseconds responses Multiple SET/RESET pulses for compensating the actual loop delay (~ hundreds of picoseconds) and for speeding up the transient ON/OFF states of Q output 10

21 Router - PPM-HP - All-optical Flip-Flop
SET (blue) / RESET (red) Q output SOA1 gain (blue) / SOA2 gain (red) ON/OFF Contrast Ratio 11

22 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

23 Router - PPM-HP - Wavelength Conversion
SOA1 SOA2 2 Data packet @ 1 22 @ 2 Ref: Y. Ueno et al., ECOC 2002 12

24 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

25 Simulation – 13 Router OP 1 OP 2 OP 3 4-bit 13

26 Simulation – Parameters
14

27 Simulation – Input / Clock Extraction
Input packets (3 wavelengths) Input spectrum / Extracted clock pulses 14

28 Simulation – Router Outputs
Spectrum at router output 1 15

29 Simulation – Router Outputs
16

30 Simulation – Multiple-hop OSNR
1- Multiple-hop OSNR due to accumulated ASE 2- Predicted & simulated OSNRs Ref: Z. Ghassemlooy et al., IEEE 49th GLOBECOM 2006, USA, (accepted) 17

31 Contents Introduction PPM-Header Processing Overview
Operation Principle Clock Extraction PPM Address Conversion PPM Header Correlation All-optical Flip-Flop Wavelength Conversion Simulation results Summary

32 Summary PPM-HP Further investigation
Provides ultrafast header processing Reduces the number of routing table entries Avoids the SOA recovery time during header correlation Operates in a large BW as employing SOA Supports multiple transmitting modes (uni/multi/broadcasting) Offers add/drop edge node scalability Further investigation ASE noise sources Timing jitter and pulse dispersion effects on PPM-HP Effective wavelength conversion IP-based optical transparent network 18

33 Thank you

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