With the advancement of technology, the demand for bandwidth increases exponentially with time. Hence, optical fiber communication becomes the optimum choice for backbone networks. As the efficiency of the optical system is limited by congenital parameters such as chromatic dispersion. So, in this work, we have evaluated the ability of electronic equalization scheme reduce the CD (chromatic dispersion for an optical communication system capable of transporting 4 channels at 10 Gbps line rate over a distance of 30km. Further, we compare the performance of decision feedback equalizer with two different configurations.

Dispersion compensation, Electronic equalization, Feed Forward Equalizer (FFE) Decision Feedback Equalizer (DFE), Chromatic Dispersion

Singer, A. C., et al., 2008, "Electronic dispersion compensation," IEEE Signal Processing Magazine, 25(6), pp. 110-130.

Winters, J. H., et al., 1990 "Electrical signal processing techniques in long-haul fiber-optic systems," IEEE Transactions on Communications, 38(9), pp. 1439-1453.

Moller, L., et al., 1999, "ISI mitigation using decision feedback loop demonstrated with PMD distorted 10 Gbit/s signals." Electronics Letters, 35(24), pp. 2092-2093.

Bülow, H., et al., 2000 "PMD mitigation at 10 Gbit/s using linear and nonlinear integrated electronic equalizer circuits." Electronics Letters 36(2), pp. 163-164.

Poirrier, Julien, et al., 2000, "Experimental nonlinear cancellation of polarization-mode dispersion." Optical Fiber Communication Conference, 3, pp. 119-121.

Taylor, Michael G., 2004, "Coherent detection method using DSP for demodulation of signal and subsequent equalization of propagation impairments." IEEE Photonics Technology Letters, 16(2), pp. 674-676.

Beukema, Troy, et al., 2005, "A 6.4-Gb/s CMOS SerDes core with feed-forward and decision-feedback equalization." IEEE Journal of Solid-State Circuits, 40(12) pp. 2633-2645.

Porto, S. et al., 2013, "Requirements for adaptive electronic dispersion compensation in burst-mode systems." Optical Fiber Communication Conference. Optical Society of America, pp. OTh3B-5.

Ossieur, P. et al., 2014 "Burst-mode electronic dispersion compensation." Optical Fiber Communications Conference and Exhibition (OFC), (2014), pp. 1-3.

Cartledge, J. C., et al., 1992, "Performance of smart lightwave receivers with linear equalization." Journal of lightwave technology, 10(8), pp. 1105-1109.

Yu, Q. et al., 2006, "Electronic data processing for error and dispersion compensation." Journal of lightwave technology, 24(12), pp. 4514-4525.

Singh, K., & Kaur, G., 2015, “Interferometric architectures based all-optical logic design methods and their implementations.” Optics & Laser Technology, 69, pp. 122-132.

Singh, K. et al., 2015, "A single As 2 Se 3 chalcogenide Highly Non-Linear Fiber (HNLF) based simultaneous all-optical half-adder and half-subtracter." Optical Fiber Technology 24, pp. 56-63.

Singh, K. et al., 2016, "Simultaneous all-optical half-adder, half-subtracter, comparator, and decoder based on nonlinear effects harnessing in highly nonlinear fibers." Optical Engineering, 55(7), pp. 077104-077104.

Singh, K., & Kaur, G., 2014, "All-optical half adder and half subtractor based on semiconductor optical amplifier." Open Journal of. Communication & Software 1.1, pp. 42-51.

Singh, K. et al., 2016, "A cascadable all-optical half-subtracter based on cross-modulation effects in a single highly nonlinear fiber (HNLF)." Optical and Quantum Electronics, 48(9), pp. 418.

Singh, K. et al., 2016, "Enhanced performance of all-optical half-subtracter based on cross-gain modulation (XGM) in semiconductor optical amplifier (SOA) by accelerating its gain recovery dynamics." Photonic Network Communications, pp. 1-20.

Singh, K. et al., 2017, "Performance analysis of an all-optical half-subtracter based on XGM in SOA at 20 Gbps." Optoelectronics and Advanced Materials-Rapid Communications, 11(3/4), pp. 189-196.