Abstract
Coherent optical transponders are widely deployed in today’s long haul and metro optical networks using dense wavelength division multiplexing. To increase the data carrying capacity, the coherent transponder utilizes the high order modulation format and operates at a high baud rate. The limited bandwidth and the nonlinearity are two critical impairments for the coherent in-phase quadrature transmitter. These impairments can be mitigated by digital filters. However, to accurately determine the coefficients of these filters is difficult because the impairment from the limited bandwidth and the impairment from nonlinearity are coupled together. In this paper, we present a novel method to solve this problem. During the initial power-up, we apply a sinusoidal stimulus to the coherent IQ transmitter. We then scan the frequency and amplitude of the stimulus and monitor the output power. By curve-fitting with an accurate mathematical model, we determine the limited bandwidth, the nonlinearity, the power imbalance, and the bias point of the transponder simultaneously. Optimized coefficients of the digital filters are determined accordingly. Furthermore, we utilize a coherent IQ transponder and demonstrate that the limited bandwidth is improved by the finite impulse response filter, while nonlinearity is mitigated by the memoryless Volterra filter.
Highlights
Today’s telecommunications infrastructure relies on optical fiber communications systems where the coherent in-phase quadrature (IQ) optical transceiver is an essential component
To deliver a large amount of information over a long distance, the high-order quadrature amplitude modulation (QAM) running at a high baud-rate has been adopted in the long-haul transmission system [1,2]
The proposed technique is validated on a pluggable CFP2-analog coherent optics optics (ACO) module
Summary
Today’s telecommunications infrastructure relies on optical fiber communications systems where the coherent in-phase quadrature (IQ) optical transceiver is an essential component. To deliver a large amount of information over a long distance, the high-order quadrature amplitude modulation (QAM) running at a high baud-rate has been adopted in the long-haul transmission system [1,2]. The information is carried on two orthogonal domains. One domain is the in-phase (I) and quadrature (Q), and the other domain is the two orthogonal polarizations, which are X and Y. There are impairments due to the limited bandwidth and nonlinearity. Among these tributaries, there are degrading effects due to the time skew and power imbalance. We mainly focus on the impairments within each tributary
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