A Novel Theoretical Probabilistic Model for Opportunistic Routing with Applications in Energy Consumption for WSNs.

Christian E Galarza,Jaime Utria,Jonathan M Palma,Cecilia F Morais,Ricardo C L F Oliveira,Daniel Bustos,Leonardo P Carvalho

doi:10.3390/s21238058

Christian E Galarza, Jaime Utria + Show 5 more

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https://doi.org/10.3390/s21238058

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This paper proposes a new theoretical stochastic model based on an abstraction of the opportunistic model for opportunistic networks. The model is capable of systematically computing the network parameters, such as the number of possible routes, the probability of successful transmission, the expected number of broadcast transmissions, and the expected number of receptions. The usual theoretical stochastic model explored in the methodologies available in the literature is based on Markov chains, and the main novelty of this paper is the employment of a percolation stochastic model, whose main benefit is to obtain the network parameters directly. Additionally, the proposed approach is capable to deal with values of probability specified by bounded intervals or by a density function. The model is validated via Monte Carlo simulations, and a computational toolbox (R-packet) is provided to make the reproduction of the results presented in the paper easier. The technique is illustrated through a numerical example where the proposed model is applied to compute the energy consumption when transmitting a packet via an opportunistic network.

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In wireless ad hoc networks, the traditional cellular architecture for multi-hop routing is characterized by the use of communication schemes where the single objective is the transmission between nodes, e.g., hop-by-hop and end-to-end [1,2]
A communication scheme where the transmitted messages can be received by several units corresponds to an Opportunistic Routing (OR) network (ExOR wireless network protocol), formulated in [3,4,5]
The total energy consumption for a generic wireless network is denoted by ET, and it can be obtained as a function of ETX, ERX, ESW, assuming that the nominal state of a node is reception