Abstract
Interference is the main performance-limiting factor in most wireless networks. Protocol interference model is extensively used in the design of wireless networks. However, the setting of interference range, a crucial part of the protocol interference model, is rather heuristic and remains an open problem. In this paper, we use the stochastic geometry and the direct approach to obtain the associated feasibility distributions. After that, we use the binary hypothesis testing to achieve the Bayes risk under binomial point process (BPP) and Poisson point process (PPP), respectively. According to the first derivative of the Bayes risk, we provide the equation to achieve the optimal interference range for minimum Bayes risk. We extend the method proposed by Wildman et al. to a more general situation. Furthermore, we show that for infinite PPP, those two methods converge to the same results. Several numerical results for wireless networks under BPP, finite PPP, and infinite PPP are given. Simulation results show that in the finite wireless network, the BPP method performs better than the PPP method.
Highlights
Interference range is a crucial part of the protocol interference model
We demonstrate that the optimal interference range found by Wildman et al [30] is the special case of the infinite Poisson point process (PPP)
Our results reveal that the binomial point process (BPP) method and the finite PPP method achieve smaller optimal interference range than the infinite PPP method
Summary
Interference range is a crucial part of the protocol interference model. Under the protocol interference model, the transmission between the reference receiver and the reference transmitter is successfully received, when there is no interference transmitter within the interference range of the reference receiver [1]. Hasan and Andrews [25] study the optimal interference range (guard zone) to maximize transmission capacity in CDMA-based wireless ad hoc networks. Wildman and Weber [29] study the optimal interference range to minimize the Bayes risk of the protocol interference model in wireless Poisson networks. The authors use the binary hypothesis testing to achieve the interference range for minimum Bayes risk Their works are only suitable for Poisson networks. The optimal interference range is configured to minimize the Bayes risk of the protocol interference model. The first contribution of this paper is proposing a method to achieve the optimal interference range for binomial wireless networks. We derive the optimal interference range for finite and infinite Poisson wireless networks.
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