Conventional cellular networks require that a link be setup through the aids of base stations and the associated core network. It is very inefficient either in terms of required multi-hop link setup, routing and other network overheads or from the viewpoint of delay and power performance if the associated physical device-to-device (D2D) link is in relatively good condition. Autonomous D2D communication as an underlay to an existing cellular network reduces the base stations (eNBs) and core network's loadings while enhancing the spectral efficiency and network throughput by taking the advantage of good direct link qualities. For efficient D2D communications, a device must be able to track its local environment and discover suitable connecting devices within a short time span. In this thesis, we propose a D2D link setup protocol that enables a device to establish a reliable D2D link using proper radio resources while causing only tolerable interference to the underlaid cellular network. We analyze the success D2D link setup (SDLS) probability based on the proposed protocol and related signal quality requirements, assuming devices are distributed according to some two dimensional Poisson point processes (PPPs). As the exact expression for the sum interference is very complicated, we use an approximation model and an upper bound to describe the active devices' location distribution in evaluating the signal-to-noise-plus-interference ratio of a macrocellular terminal. Using either one in computing the SDLS probability, we show that it is a quasiconcave function of the device' transmit power. We apply a bisection search with the help of the derived upper and lower search bounds to accelerate the search and prove that the existence of the optimal solution.