T. Fillion scite author profile

Introduction : Crosstalk induced by gain saturation and short carrier lifetime, intrinsic to the semiconductor medium, can severely limits the application of Semiconductor Optical Amplifiers (SOA) in Wavelength Division Multiplexing (WDM) systems with intensity modulated scheme [ 11. Suppression of signal induced gain fluctuations using gain clamping by laser oscillation at a wavelength different from signal bandwidth has already been demonstrated in the case of a semiconductor amplifier with an external wavelength selective reflector [2]. In this paper, we report a new Clamped Gain SOA (CG SOA) structure with an integrated Bragg grating as a wavelength selective reflector and demonstrate crosstalk suppression in case of WDM application at 2.5 Gbit/s. Device structure and principle : The proposed amplifier structure ( Figure 1) is similar to those reported in [3] and is based on 0.5 pm wide square active stripe made of InGaAsP bulk material for polarisation independant operation. The active stripe is lateraly tapered over 70 pm at both ends for reduction of far field divergence and improvement of coupling efficiency to the fiber. Window regions and antireflection coating are used for suppression of cleaved facet reflectivity. The total length of the device is 600 pm. A distributed Bragg grating is introduced under the active stripe and forms a wavelength selective reflector. The coupling coefficient of the grating is chosen so that it provides a high single pass gain at the oscillation threshold. Assuming homogeneous broadening of semiconductor gain lineshape, the overall gain bandwidth is expected to be clamped once the threshold oscillation is reached. At a wavelength different from the Bragg wavelength, the gain is independent of the signal intensity as long as the lasing oscillation is not switched off through carrier depletion effect. The optical power is, in fact, stored in the lasing wavelength and converted into amplified signal following intensity modulations,with a time response limited by the relaxation oscillation frequency. Device characteristics and results : Static light / current characteristic of CG SOA is shown on figure 2. Lasing oscillation threshold is clearly observed around 60 mA. The maximum output power is 15 mW per facet at 200mA and is mainly limited by thermal effects. Small signal fiber to fiber gain versus driving current is shown on figure 3 for TE and TM polarisations: thanks to the square active stripe, the TE / TM gain difference is less than 1 dB and gain reaches 15 dB at 60 mA where the oscillation occurs. Figure 3 clearly shows the gain clamping effect due to the distributed grating: at 60 mA the gain saturate strongly and is nearly independant, in the one dB range, on the driving current from 60 up to 200 mA. Taking into account 3 to 4 dB coupling losses per facet, the internal gain is in the 21-23 dB range. The spectrum of the light at the output of the amplifier is shown on figure 4 for -25 dBm signal power launched at the input of the device. We can observe the lasing wave...

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1.1-W continuous-wave 1480-nm semiconductor lasers with distributed electrodes for mode shaping

Salet¹,

Gerard²,

Fillion³

et al. 1998

IEEE Photon. Technol. Lett.

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How to launch 1 W into single-mode fiber from a single 1.48-μm flared resonator

Delepine

Gerard

Pinquier³

et al. 2001

IEEE J. Select. Topics Quantum Electron.

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Widely Vernier tunable external cavity laser including a sampled fiber Bragg grating with digital wavelength selection

Bergonzo¹,

Jacquet²,

Gaudemaris³

et al. 2003

IEEE Photon. Technol. Lett.

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T. Fillion

1.55 /spl mu/m polarisation independent semiconductor optical amplifier with 25 dB fiber to fiber gain

Clamped gain travelling wave semiconductor optical amplifier for wavelength division multiplexing applications

1.1-W continuous-wave 1480-nm semiconductor lasers with distributed electrodes for mode shaping

How to launch 1 W into single-mode fiber from a single 1.48-μm flared resonator

Widely Vernier tunable external cavity laser including a sampled fiber Bragg grating with digital wavelength selection

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