1. University of California
Integrated Optical Wavelength Converters and Routers for Robust Wavelength-Agile Analog/ Digital Optical Networks Project Overview and Status
Daniel J. Blumenthal (PI), John E. Bowers, Larry A. Coldren, Nadir Dagli and Evelyn L. Hu
University of California
Santa Barbara, CA
Tel: (805) ;

2. Program Objectives
Develop and demonstrate chip-scale integrated wavelength conversion, monitoring and routing on a common in-plane InP photonic integration platform.
Demonstrate and characterize InP wavelength converters with both digital and analog transmission requirements.
Investigate the impact of integration in a common InP platform on performance, power dissipation and footprint of future DoD chip-level functions.

3. Program Overview InP Integrated Optical
Program Manager:
Jagdeep Shah (DARPA/MTO)
Technical Contract Manager:
Justin Hodiak (SPAWAR)
InP Integrated Optical
Tunable Wavelength Converters and Routers
PI: D. J. Blumenthal
Co-PIs: J. Bowers, L. A. Coldren, N. Dagli, E. Hu
Task 1
All-Optical SOA
Interferometric
Wavelength Converter
(SOA-IWC)
Task Leader: Blumenthal
Task 2
Optical Filter/
Mux/DeMux/Router
Task Leader: Dagli
Task 3
Optoelectronic Integrated
Circuit (OEIC)
Wavelength Converter
Task Leader: Coldren
Wafer Processing
Task Leader: Rob Simes
(Agility)
Baseline: 15 Months
Option 1*: 21 Months
Option 2*: 12 Months
Start Date 6/26/02
Baseline Milestones
9/25/03
Option 1 Milestones 6/25/05
Program End Date
6/25/06
* Options renewal dependent

4. Personnel Task 1 Task 2 Task 3 Integration Platform Administrative
Task Leader: Blumenthal
Larry A. Coldren
Milan Masanovic (S)
Vikrant Lal (S)
John Barton (S)
Hubert Chou (S)
Joe Summers (S)
Zhaoyang Hu (PD)
Xuejin Yan (PD)
Task 2
Task Leader: Dagli
Evelyn Hu
Amin Xing (S)
Wenbin Zao (S)
Milan Masanovic (S)
Cem Ozturk (PD)
Task 3
Task Leader: Coldren
John E. Bowers
Matt Sysek (S)
Erik Skogen (S)
John Barton (S)
Jeff Henness (S)
Integration Platform
Task Leader: Rob Simes
(Agility)
Milan Masanovic (S)
Erik Skogen (S)
James Raring (S)
Administrative
Daniel Blumenthal (PI)
Alex Locke (ECE Budget)
Lisa Garza (Admin Assistant)

5. InP Building Blocks All-Optical Wavelength Converter
Mode Converter + Active WG + Passive WG + MMI-Splitters/Combiners + Tunable Laser + Ring Resonator Filter
Wavelength Router/Mux/Demux
Mode Converter + Passive WG + MMI-Splitters/Combiners + Ring Resonator Filter + TIR Turning Mirror
Optoelectronic Integrated Circuit WC
Active WG + Passive WG + Photodetector + electronic amplifier + EAM + Mode Converter
Mode
Converter
Power
Splitter/
Combiner
Ring/Disk
Resonator
Filter
TIR
Mirror
Active
Waveguide
Passive
Waveguide
Filter
Waveguide
Tunable
Laser
Photo-
detector
Electro-
Absorption
Modulator

6. Common Integration Platforms

7. Roadmap

8. 3-Year Goals Demonstrate common InP platform chip-scale integration
2-stage all-optical wavelength converter with integrated filters
Wavelength router/mux/demux
Demonstrate conversion of any one of 32 input wavelengths to any one of 32 output wavelengths
Demonstrate dynamic (<1ms) switching time.
Demonstrate conversion of digital signals
Digital out to 2.5 Gbps with low BER (10-9)
Analog signals with 20 GHz instantaneous bandwidth and high SFDR
Demonstrate wavelength converters with analog and digital signal performance monitoring capabilities.

9. Performance Metrics and Target Goals
l Resolution/Channel Spacing
FSR (nm)
Loss/ Gain (dB)
Pout (mW) BW
tswitch (ms)
RIN (dB/Hz)
AOWC
32 (C-Band)
100 GHz NA
TBD
0.1
2.5 GHz
1.0
< -150
WR-M/D
RRF
C-Band 30
< 10
<1nm 3dB
TIR
< 2/ mirror
OEIC

10. Key Milestones: Base Period
Baseline: 15 Months
Option 1*: 21 Months
Option 2*: 12 Months
Start Date 6/26/02
Baseline Milestones
9/25/03
Option 1 Milestones 6/25/05
Program End Date
6/25/06
Demonstrate operational chip-on-carrier single-stage SOA-IWC with integrated tunable laser capable of tuning to 32 wavelengths (1550nm C-band).
Demonstrate InP single disk resonator filter with 100GHz FSR.
Develop High-Quality InP etching techniques for filters, interferometers and multiplexers and demonstrate TIR mirror and strongly confined waveguide
Demonstrate directly modulated OEIC wavelength converter with electrical tap/monitor capabilities, capable of tuning to 32 wavelengths (1550nm C-band).
Measure analog and digital performance of both AOWC and OEIC-WC
The goal of this program is to investigate and develop the next generation of photonic integrated Chip-Scale optical wavelength converter and wavelength routing platform.

11. Baseline Hardware Deliverables
Deliver three (3) working chip-on-carrier prototypes of the all-optical converters to the MIT-LL DARPA designated FFRDC test facility.
Deliver three (3) working directly modulated OEIC-WC (with monitoring) as a chip-on-carrier to the MIT-LL DARPA designated FFRDC test facility.

12. Options 1 & 2 Hardware Deliverables
Deliverables under Option 1, if exercised:
Three (3) packaged single-stage SOA-IWC with an integrated filter and an integrated mode converter which has 32 wavelength.
Three (3) externally modulated OEIC-WC packaged as a chip-on-carrier.
Deliverables under Option 2, if exercised:
Three (3) packaged two-stage SOA-IWC with an integrated filter, an integrated mode converter and 32-wavelength capability.
Three (3) externally modulated OEIC-WC flip-chip bonded to a multi-chip module (MCM) with interface electronics.

13. Program Technical Accomplishments to Date
Task I: AOWC
World’s first tunable integrated SGDBR laser and SOA-IWC
Input
Task II: Filter/Mux/DeMux
Task III: OEIC/WC-Monitor
* Results are a transition from prior DARPA NGI program into current program

14. Progress Summary

15. System Issues Network: Transmission With Input from V. Chan/MIT
Reconfiguration time less than 1ms because …
Insert picture of aircraft from CS-WDM CD.
Multicasting has advantages
Changing wavelengths in the middle of the network solves key routing issues (as opposed to at the source).
Scalability of network management (computing paths, passing information)
High utility of wavelength resources (less constrained routing)
For wide area or greater networks, allows fast reconfiguration through local routing
Allows hitless protection with rollover in smaller networks
Local vs. global restoration for loss-less transmission of critical defense data
Transmission
Noise figure, dynamic range, SFDR, transients, BER, output power
With Input from V. Chan/MIT

16. Next Steps
Sending working device to MIT-LL 1st week of May 2003

17. Technology Demonstration/Transition Plan
Working chip-on-carrier prototypes of the all-optical and optoelectronic (with monitoring) converters will be delivered to the MIT-LL DARPA designated test facility.
Interaction with MIT-LL will require collaboration and transfer of knowledge and technology to use/test these devices.
Collaboration with other projects funded in the CS-WDM program (e.g. Vincent Chan/MIT).
Publications in peer reviewed journals and conferences will result from this project.
Graduate students trained in areas related to chip-scale WDM integration
Novel aspects of this work may lead to new inventions and innovations and possibly patents.

18. Budget and Spending

19. Resulting Publications to Date
“Monolithically Integrated Mach-Zehnder Interferometer Wavelength Converter and Widely-Tunable Laser in InP,” Milan L. Mašanović, Vikrant Lal, Jonathon S. Barton, Erik J. Skogen, Daniel J. Blumenthal, Larry A. Coldren, submitted to IEEE Photonics Technology Letters, 2003.
“Widely-Tunable Chip-Scale Transmitters and Wavelength Converters,” Larry A. Coldren , IPR 2003, Invited talk
“InP Laterally Tapered Wide-bandwidth Optical Power Splitter,” Xuejin Yan, Marcelo Davanco, Milan Masanovic, Wenbin Zhao, Daniel J. Blumenthal, to be presented at CLEO, Maryland. June, 2003.
“Demonstration of Monolithically-Integrated InP Widely-Tunable Laser and SOA-MZI Wavelength Converter,” Milan L. Mašanović, Erik J. Skogen, Jonathon S. Barton, Vikrant Lal, Daniel J. Blumenthal and Larry A. Coldren To be presented at the Fifteenth International Conference on Indium Phosphide and Related Materials, May , Santa Barbara, CA, 2003.
“Multimode Interference-Based 2-Stage 1x2 Light Splitter for Compact Photonic Integrated Circuits,” Milan L. Mašanović, Erik J. Skogen, Jonathon S. Barton, Joseph Sullivan, Daniel J. Blumenthal and Larry A. Coldren, To Appear in IEEE Photonics Technology Letters, May 2003.
“Cascaded Multimode Interference-Based 1x2 Light Splitter for Photonic Integrated Circuits,” M. Masanovic, E. Skogen, Barton, J. Sullivan, D. J. Blumenthal, and L. Coldren, Topical Meeting on Integrated Photonics Research (IPR), Vancouver, Canada, Paper IThA5, Jul 14-17, 2002.
“Integrated Devices for Wavelength-Agile All-Optical Networks,” D. J. Blumenthal, Topical Meeting on Integrated Photonics Research (IPR), Vancouver, Canada, Paper IWB1, July 14-17, 2002 (Plenary Paper)

20. Enabling Publications
J.T. Getty, E.J. Skogen, L.A. Coldren, "Multistage Segmented 1.55um Lasers with Record Differential Efficiency, Low Thresholds, and 50W Matching," LEOS 2003 Annual Meeting, Postdeadline Paper PD1.2, Glasgow, UK, November, J.T. Getty, L.A. Johansson, E.J. Skogen, L.A. Coldren, "Segmented 1.55um Laser with 400% Differential Quantum Efficiency," OFC 2003, Paper TuG1, Atlanta, GA, March, 2003.
Erik J. Skogen, James W. Raring, Jonathon S. Barton, Steven P. DenBaars, and Larry A. Coldren, ”Post-Growth Control of the Quantum-Well Band Edge for Optimized Widely-Tunable Laser-X Devices”, submitted to Journal of Selected Topics in Quantum Electronics
Jonathon S. Barton, Erik J. Skogen, Milan Mašanovic, James Raring, Matt Sysak, Leif Johansson, Steven P. DenBaars, Larry A. Coldren, “Photonic Integrated Circuits Based on Sampled-Grating Distributed Bragg Reflector Laser” (invited talk), Photonics West 2003, [ ]
Jonathon S. Barton, Erik J. Skogen, Milan Mašanovic, Steven P. DenBaars, Larry A. Coldren, “Widely-tunable high-speed transmitters using integrated SGDBRs and Mach-Zehnder modulators “, submitted to Journal of Selected Topics in Quantum Electronics