Performance analysis of Least Mean Square Time-Domain Equalizer for 20.48 Gb/s direct-detection optical OFDM transmission over 2560 km of SMF

Optical Orthogonal Frequency Division Multiplexing (O-OFDM) provides major advantages in mitigating Group-Velocity Dispersion (GVD) in Single Mode Fiber (SMF). Unfortunately, when the uncompensated long-haul transmission ranges become very large, substantial dispersion is accumulated. Due to the large accumulated dispersion, the Cyclic Prefix (CP) duration will occupy a substantial fraction of the OFDM frame. This effect sets some limitations on the overall throughput and the spectral efficiency. Moreover, the transmission is inefficient because of the energy wastage contained within the CP. In the case where the Channel Impulse Response (CIR) is larger than the CP, the system performance is limited by the Inter Symbol Interference (ISI) and Inter Carrier Interference (ICI). In this paper, we propose a Least Mean Square Time Domain Equalizer (LMS-TEQ) immediately after the channel. It can cancel the residual ISI and ICI caused by both the GVD and the CP length being shorter than the CIR. Our simulation results show that, using BER of 10^-3 as a reference, the system performance improves by 2.71 dB while considering an 8-tap LMS-TEQ, GVD, Gaussian Noise and in the case where the CP length is shorter than the CIR. This method reduces size of the CP, and consequently the performance of the system will be improved.