Applications of Photonic Parametric Processors in Optical Communication Systems

This dissertation, "Applications of Photonic Parametric Processors in Optical Communication Systems" by King-yin, Henry, Cheung, 張景然, was obtained from The University of Hong Kong (Pokfulam, Hong Kong) and is being sold pursuant to Creative Commons: Attribution 3.0 Hong Kong License. The content of this dissertation has not been altered in any way. We have altered the formatting in order to facilitate the ease of printing and reading of the dissertation. All rights not granted by the above license are retained by the author. Abstract: Abstract of thesis entitled Applications of Photonic Parametric Processors in Optical Communication Systems Submitted by Henry King Yin Cheung for the degree of Master of Philosophy at The University of Hong Kong in August 2007 Photonic parametric processors (PPPs) rely on the third-order nonlinear (3) susceptibility χ in fiber, which have been identified as useful devices for many applications in fiber optic communication systems. The major advantages of using PPPs are their inherent characteristics of ultra-fast response and high efficiency of the parametric effect. One of their useful embodiments is fiber optical parametric amplifier (OPA). When a strong pump (ω ) and a weak signal (ω ) are launched into p s the fiber, the signal will be amplified through the parametric process, and a new wavelength component, called idler (ω ), will be generated at ω = 2ω - ω . The idler i i p s contains the same modulation information as the input signal and may be regarded as the replica of the original data. Thus, OPAs may find applications such as optical amplifiers and wavelength converters, depending on whether the signal or the idler is used. This thesis describes the features and applications of PPPs, which rely on the optical parametric effect in HNLFs. They include a newly developed Raman- mediated optical parametric amplifier (RM-OPA), which combines the characteristics of both Raman amplifier (RAs) and OPA; nonreturn-to-zero (NRZ) to return-to-zero (RZ) data format converter and optical pulse compressor, which is based on the principles of one-pump OPA pumped by a strong optical pulse source; and parametric wavelength exchanger and packet switch, which evolved from the principles of two-pump OPA using different pumps allocations. The analytical model of RM-OPA is described. The signal gain is derived and solved by Wentzel-Kramers-Brillouin (WKB) approximation. Results show that the RM-OPA can provide a flat gain spectrum, and that the RIN transfers between the pumps and the signal are significantly suppressed when the amplifier is pumped by a counter-propagating Raman pump. Applications of one-pump OPAs are also discussed in this dissertation. A NRZ- to-RZ data format converter is demonstrated using a pulsed-pump OPA. The relationship between the parametric gain and pulsewidth was experimentally investigated and results show that the power penalties are improved by more than 3 -9 dB at BER of 10 at both signal and idler wavelengths. Besides, by deploying the exponential power dependence of parametric gain, pulse compression can be realized if the OPA is pumped by an optical pulse train. A theory describing the compression effect using a two-stage OPA is derived and compared to experimental results, showing good agreement. With a suitable wavelengths re-arrangement of two pumps and two signals in two-pump OPAs, a novel phenomenon known as parametric wavelength exchange (WE) can be realized. Parametric WE, which enables data swapping at two different wavelengths simultaneously, is also discussed in this thesis. Results show the exchange performance is degraded by the Raman and parametric effects induced by the two strong pumps during the exchange process. This problem can be solved by placing the two pumps at the anomalous dispersion region such that complete WE can be achieved. Packet switching in which two data packet is swapped simultaneo