Widely-Tunable Electroabsorption-Modulated Sampled Grating DBR Laser Integrated with Semiconductor Optical Amplifier

Widely-Tunable Electroabsorption-Modulated Sampled Grating DBR Laser Integrated with Semiconductor Optical Amplifier Y. A. Akulova, C. Schow, A. Karim, S. Nakagawa, P. Kozodoy, G. A. Fish, J. DeFranco, A. Dahl, M. Larson, T. Wipiejewski, D. Pavinski, T. Butrie, L. A. Coldren Agility Communications, Inc., 6 Pine Ave, Santa Barbara, CA 93117 yakulova@agility.com Abstract: We report on a sampled grating DBR laser monolithically integrated with an electroabsorption modulator and semiconductor optical amplifier. A fiber coupled time-averaged power in excess of 3 dbm across a 4 nm tuning range and 2.5 Gb/s transmission over 2 km of standard fiber are achieved. 21 Optical Society of America OCIS codes: (25.53) Photonic integrated circuits; (6.233) Fiber optics communications 1. Introduction Tunable lasers are desired for optical networking applications ranging from one time wavelength provisioning and sparing to dynamic wavelength provisioning in re-configurable optical add/drop multiplexers, photonic crossconnects, and all-optical regenerators. Several tunable laser technologies with direct or integrated modulation ( 2.5 Gb/s) have been demonstrated [1-4]. Among those only the Sampled Grating Distributed Bragg Reflector (SG-DBR) laser architecture combines the advantages of wide tuning range, high output power, simplicity for integration with other components [4-6], and high reliability [7]. In this paper we report on a tunable 2.5 Gb/s transmitter based on a SG-DBR laser monolithically integrated with a semiconductor optical amplifier (SOA), and an electro-absorption modulator (EA) modulator, and demonstrate transmission over distances required in long-reach metro applications. 2. Device design and fabrication As illustrated in Fig. 1, the device consists of a four-section SG-DBR laser, an SOA, and an EA modulator, all integrated on the same InP chip. The SOA compensates on-state modulator loss and cavity losses caused by free carrier absorption in the tuning sections and allows power leveling with insignificant wavelength deviation. The integration of the laser and SOA active regions with the tuning and modulator sections of the device has been accomplished by using an offset quantum-well structure [4]. In this simple integration technology the active region of the modulator uses the same bulk quaternary waveguide as the tuning sections of the laser. The Franz-Keldysh effect in the bulk waveguide material provides for larger spectral bandwidth as compared to the quantum-confined Stark effect. The composition of the bulk waveguide can be optimized to achieve high tuning efficiency for the laser and a target extinction ratio over the required wide spectral bandwidth for the modulator. An angled waveguide and wide-band anti-reflection coating at the output of the device were used to suppress the optical feedback to the SGDBR laser. Modulator Amplifier Front Mirror Gain Phase Rear Mirror Light Out Q waveguide MQW active regions Sampled-gratings Fig. 1. Schematic of SG-DBR laser integrated with SOA and EA modulator.

3. Results and discussion The device was packaged in a cooled butterfly package with a co-planar RF input. The package was mounted into a transmitter assembly with dc current and voltage drivers. The ITU channel selection is done using a look up table for the laser and SOA currents and the dc bias voltage for the modulator. More than consecutive 5 GHz spaced ITU channels with fiber coupled output powers > mw and SMSR greater than 4 db were demonstrated for I gain = I SOA = 15 ma and V mod = V (Fig. 2a). Relative intensity noise is less than 145 db/hz and unmodulated timeaverage linewidth is below 2 MHz across the tuning range. The extinction ratio (ER) characteristics of EA-modulators are strongly dependent on the detuning between the lasing and absorption-edge wavelengths. To provide uniform RF ER over a wide spectral bandwidth, the dc bias on the modulator section has been adjusted for each channel. Power leveling was accomplished by adjusting SOA current in the range of 4- ma. Time-averaged power > 3 dbm and RF ER > db was simultaneously obtained across the tuning range with 3 V peak-to-peak modulation (Fig. 2b). Fiber Coupled Power, dbm 16 14 12 8 a) I gain = 15 ma I SOA = 15 ma V mod = V 6 5 4 3 2 SMSR, db RF ER, db 12 8 6 4 2 b) 5 4 3 2 1 Time Averaged Power, dbm 6 152 153 154 155 156 157 158 Wavelength, nm 152 153 154 155 156 157 158 Wavelength, nm Fig. 2. a) Fiber coupled power and SMSR across the tuning range. b) RF extinction ratio and fiber coupled time averaged optical power vs. wavelength for a fixed 3V pk-pk rf drive voltage. The fiber transmission experiments were performed using integrated SGDBR-SOA-EA modulator chip mounted on RF ceramic carrier. Bit error rate characteristics for three representative channels are shown in Fig. 3. Error-free transmission has been demonstrated for 2 km of standard single mode fiber. The dispersion penalty is <.3 db at 156 nm and <1.5 db at 153 nm. Further optimization of EA modulator operating parameters should result in lower dispersion penalty at short wavelength range. 4. Summary In summary, we have demonstrated a widely-tunable, 2.5 Gb/s transmitter based on a SG-DBR laser monolithically integrated with a SOA and EA modulator. Time-averaged powers in excess of 3 dbm and RF extinction ratio > db across a 4 nm tuning range have been achieved. Error-free transmission at 2.5 Gb/s has been demonstrated for 2 km of standard single mode fiber.

Bit Error Rate -3-4 -5-6 -7-8 -9 - -11 153 nm B-to-B 153 nm 2 km 154 nm B-to-B 154 nm, 2 km 156 nm, B-to B 156 nm, 2 km 2-2.5 V Bias, 3-3.3 V p-p -38-36 -34-32 -3-28 -26 Average Received Power [dbm] Fig. 3. Bit error rate curves for and 2 km of standard single-mode fiber spans for three different wavelengths (2.5 Gb/s NRZ, 2 31-1 PRBS). 5. References [1] J. E. Johnson, L. J.-P. Ketelsen, D. A. Ackerman, J. M. Geary, W. A. Ausous, F. S. Walters, J. M. Freund, M. S. Hybertsen, K. G. Glogovsky, C. W. Lentz, C. L. Reynolds, R. B. Bylsma, E. J. Dean, and T. L. Koch, Electroabsorption-Modulated Wavelength-Selectable Lasers, presented at Integrated Photonics Research, Monterey, CA, paper ItuC1, 21. [2] W. Yuen, G.S. Li, R.F. Nabiev, M. Jansen, D. Davis, C. J. Chang-Hasnain, Electrically-Pumped Directly-Modulated Tunable VCSEL for Metro DWDM Applications, IEEE/LEOS Summer Topical Meetings, Invited paper TuA1.2, Copper Mountain, CO, 21. [3] M. Jiang, C-C. Lu, P. Chen, J.-H. Zhou, J. Cai, K. McCallion, K. J. Knopp, P. D. Wang, M. Azimi, D. Vakhshoori, Error Free 2.5 Gb/s transmission over 125 km conventional fiber of a directly modulated widely tunable vertical cavity surface emitting laser, OFC 2, Baltimore, MD, 2. [4] B. Mason, G. A. Fish, S. P DenBaars, and L. A. Coldren, Widely tunable Sampled Grating DBR Laser with Integrated Electroabsorption Modulator, IEEE Photnics Technology Letters, 11(6), 638-4, 1999. [5] B. Mason, J. Barton, G. A. Fish, L. A. Coldren, S. P. DenBaars, Design of Sampled Grating DBR Lasers with integrated Semiconductor Optical Amplifiers, IEEE Photnics Technology Letters, 12(7), 762-4, 2. [6] J. Barton, L. Coldren, and G. Fish, Tunable Laser using Sampled Grating DBRs, IEEE/LEOS Summer Topical Meetings, Invited paper TuA2.1, Copper Mountain, CO, 21. [7] F. Delorme, G. Terol, H. de Bailliencourt, S. Grosmaire, P. Devoldere, Long-tern wavelength stability of 1.55 -µm tunable distributed Bragg reflector lasers, IEEE Journal of Selected Topics in Quantum Electronics, 5(3), 48-6, 1999.

2 Outline Introduction to Widely-Tunable SG-DBR Lasers System requirements Device design SG-DBR Lasers: Theory of Operation Integration with other components CW operation SGDBR-SOA-EAM High-speed performance Summary

3 Requirements for Tunable Lasers Output Power External Mod. -2 mw Integrated Mod. -5 dbm Tuning Range Replacement 8-32 nm Enabling >32 nm Tuning Speed Sparing 1 sec Restoration < ms Packet Switching < ns Wavelength Control GHz ±5 GHz 5 GHz ±3 GHz 25 GHz ±1 GHz

4 Sampled Grating Mirror Design d Λ s Front Mirror Gain Phase Rear Mirror Λ B = λc 2n eff λ m = 2 λ 2n Λ g S Λ B SG-DBR Repeat Mode Spacing λ F λ B 5-X Tuning Range of DBR Reliable, Manufacturable InP Technology Can Cover C band, L band or C + L Easily Integrates Monolithically with Other Components (e.g. EAM, SOA)

5 Device design and integration technology SG-DBR Laser EA Modulator Amplifier Front Mirror Gain Phase Rear Mirror Light Out Q waveguide MQW active regions Monolithic InP chip/ same material structure and process as for SGDBR alone Waveguide common to SGDBR, SOA, and EA modulator Optimized for RF ER and chirp over 4 nm tuning range, and FM efficiency of the tuning sections SOA Breaks Power/Tuning Range Tradeoff + VOA function

6 TEMLA Tunable Electroabsorption Modulated Laser Assembly Power Monitor Wavelength Locker Light out RF Signal and DC Bias Power Control Modu -lator Amplifier Mirror Control (channel selection) Wavelength Locking Front Mirror Gain Phase Back Mirror Compact footprint and industry standard pinout Microprocessor based control system Close loop control: Power Wavelength Mirror control Temperature Modulator driver: V pp V dc Integral wave-locker (5 GHz etalon) Tuning of the laser and modulator driver for the desired channel < ms VOA Blanked output power 3 dbm VOA dynamic range > db

7 CW Performance of SGDBR-SOA-EAM Chip power, mw 4 3 2 I SOA, ma 15 125 Fiber Coupled Power, dbm 16 14 12 8 I gain = 15 ma I SOA = 15 ma V mod = V 6 5 4 3 2 SMSR, db 5 15 I, ma gain 6 152 153 154 155 156 157 158 Wavelength, nm > 5 GHz ITU Channels Fiber coupled power > dbm SMSR > 4 db

8 CW close loop performance Fiber coupled power, dbm 15 5.3.2.1 -.1 ITU wavelength error, nm -.2 1525 1535 1545 1555 1565 Wavelength, nm Fiber coupled power = dbm +/-.5 db Wavelength deviation <+/- 3.5 pm

9 Percent 99.99 RIN and Linewidth of SOA Amplified SG-DBR 99.9 99 95 9 8 7 5 3 2 5 1.1 RIN Measurement Worst Case RIN over (.1 GHz - GHz) 64 channels sampled over 15 parts Mean Value: 146 db/hz Standard Deviation: 1.7 db/hz.1-154 -152-15 -148-146 -144-142 RIN (db/hz) Pout = mw Frequency Noise, (Hz 2 /Hz) FM Noise Density Measurement 6 1 2 3 4 5 6 7 8 SOA does not degrade RIN & Linewidth RIN ~ -146 db/hz Linewidth measured by self-homodyne technique at subsystem level < MHz Linewidth ~ 1 MHz using FM Noise Density measurement (more accurate than self-homodyne method). 8 7 5 MHz Linewidth 1 MHz Linewidth Pout = mw Frequency (GHz)

High-speed performance: RF ER & Chirp RF ER, db 14 12 8 6 1525 nm 1545 nm V pp 3 V and 3.3 V 156 nm 1 1.5 2 2.5 3 3.5 Vdc, V Chirp mapped out using Time Resolved Spectroscopy Curved waveguide and multilayer AR coating eliminate optical cross-talk Low on-chip electrical cross-talk EA modulator chirp can be adjusted by V dc and V p-p RF ER > db, chirp <.2 A over wide tuning range Chirp pk-pk, Angstrems.25.2.15.1 1525 nm V dc = 2.7 V 1543 nm V dc = 2.7 V 1561nm V dc = 3.3 V 1 1.5 2 2.5 3 3.5 Vdc, V

11 Modulated Performance: RF ER & P ave & VOA Operation RF ER, db 12 8 6 4 5 4 3 I = 15 ma gain 2 - variable I SOA 2 V = 3 V mod p-p 1 V -variable mod dc 152 153 154 155 156 157 158 Wavelength, nm Time Averaged Power, dbm.44 Wavelength Dev. (pm).22 -.2-2 -.4-4 SMSR (db) 52 48 44 4 1528 nm 153 nm 1534 nm 1538 nm 1542 nm 1546 nm 155 nm 1554 nm 1558 nm 1562 nm 36 - -5 5 Output Power (dbm) Time-averaged power 3 dbm and RF ER > db across C-band Output power dynamic range of ~2 db w/ small change in SMSR and Wavelength (open loop operation)

12 Bit Error Rate [Errors/s] Transmission characteristics -4-5 -6-7 -8-9 - -11 2.488 GB/s, 2 31-1 2 km, SMF28 153 nm km 153 nm 2 km 154 nm km 154 nm 2 km 155 nm km 155 nm 2 km 156 nm km 156 nm 2 km 1528 nm 154 nm 156 nm PRBS 2 31-1 at 2.5 Gb/s 4 th order Bessel- Thomson filter SONET mask with 25% margin -12 155 nm Unfiltered 2.7 Gb/s -13-36 -35-34 -33-32 -31-3 -29 Average Received Power [dbm] < ~ 1 db DP over 2 km NDSF Supports OC-48 with FEC

13 OC-192 Operation of EAM PRBS 2 31-1, V p-p = 3V Integration technology compatible with higher bit rates > db RF ER across C-band

14 Summary SG-DBR lasers meet the requirements of many market segments: from Metro to Ultra-Long Haul. Monolithic SGDBR-SOA-EAM chip using platform technology High yield Low cost High Volume SGDBR-SOA-EAM characteristics: Wide Tuning (>4 nm) High Power (> mw CW) 3 dbm time averaged power and > db RF ER across C-band Support OC-48 with FEC Fully functional widely-tunable Transmitter with integrated wavelength locker and close loops control (power, wavelength, mode, temperature) SGDBR-SOA-EAM integration technology is compatible with higher output power and bit rates