Design a transmitter and receiver for high data rate free space optical communication system

Abstract

Free space optical (FSO) communication has emerged as a viable technology for broadband wireless applications. FSO technology offers the potential of high bandwidth capacity over unlicensed optical wavelengths. On long-range FSO links, atmospheric turbulence causes intensity fluctuations, which degrades links performance. The performance of an optical link can be improved by the use of a time delayed diversity technique, which takes advantage of the fact that the atmospheric path from transmitter to receiver is statistically independent for time intervals beyond the coherence time of the intensity fluctuations. Communications performance is improved because the joint probability of error is less than the probability of error from individual channels. FSO technology has also emerged as a key technology for the development of rapidly deployable and secure communication and surveillance networks. In networking applications, broadcasting capability is frequently required to establish and maintain inter-node communications. One approach to deal with the broadcasting issue in FSO networking is the use of omnidirectional FSO links, which is based on non-directed line-of-sight (LOS) technique.