On the Nash Equilibria of graphical games for channel access in multihop wireless networks

“…A maximal scheduling vector corresponds to a feasible schedule such that no more devices can be activated without violating the interference constraints. As we have shown in [2], a NE strategy vector in the setup that we study is a maximal scheduling vector but a maximal scheduling vector is not necessarily a NE strategy vector. A maximal scheduling vector that is not a NE will never be chosen by autonomous devices, since at least one of them will be able to improve its payoff by simply switching to another strategy.…”

“…Following up on our previous work [2], we model this scenario as a non-cooperative game, focusing on the Nash Equilibrium (NE) concept, i.e., a state where no device has motivation to unilaterally change its strategy. The goal of this work is two-fold.…”

“…Firstly, we are interested in studying theoretically the properties of Nash Equilibria and, secondly, exploit these properties to design a practical, efficient and distributed scheme that converges fast to a NE. The main extensions from [2] are the following: (i) We analyze the structural properties of a strategy vector that is a NE. (ii) We propose a sophisticated scheme that is guaranteed to monotonically converge to a NE using these properties.…”

“…(ii) We propose a sophisticated scheme that is guaranteed to monotonically converge to a NE using these properties. (iii) We study this scheme under both the unicast and the multicast communication model (in [2], we studied only unicast). (iv) For each particular network, there are different NE where nodes either transmit their data or wait and receive data.…”

“…On the other hand, in this work, we consider a linear multihop device-to-device network, whereas in [2] we have studied tree topologies, which are more general. This is due to the fact that the analysis of our scheme assuming a tree topology is quite complex and also because the onedimensional model is more suitable for emphasizing the key features of our scheme.…”

Channel access competition in linear multihop device-to-device networks

“…A maximal scheduling vector corresponds to a feasible schedule such that no more devices can be activated without violating the interference constraints. As we have shown in [2], a NE strategy vector in the setup that we study is a maximal scheduling vector but a maximal scheduling vector is not necessarily a NE strategy vector. A maximal scheduling vector that is not a NE will never be chosen by autonomous devices, since at least one of them will be able to improve its payoff by simply switching to another strategy.…”

“…Following up on our previous work [2], we model this scenario as a non-cooperative game, focusing on the Nash Equilibrium (NE) concept, i.e., a state where no device has motivation to unilaterally change its strategy. The goal of this work is two-fold.…”

“…Firstly, we are interested in studying theoretically the properties of Nash Equilibria and, secondly, exploit these properties to design a practical, efficient and distributed scheme that converges fast to a NE. The main extensions from [2] are the following: (i) We analyze the structural properties of a strategy vector that is a NE. (ii) We propose a sophisticated scheme that is guaranteed to monotonically converge to a NE using these properties.…”

“…(ii) We propose a sophisticated scheme that is guaranteed to monotonically converge to a NE using these properties. (iii) We study this scheme under both the unicast and the multicast communication model (in [2], we studied only unicast). (iv) For each particular network, there are different NE where nodes either transmit their data or wait and receive data.…”

“…On the other hand, in this work, we consider a linear multihop device-to-device network, whereas in [2] we have studied tree topologies, which are more general. This is due to the fact that the analysis of our scheme assuming a tree topology is quite complex and also because the onedimensional model is more suitable for emphasizing the key features of our scheme.…”

Channel access competition in linear multihop device-to-device networks

Incentives - based power control in wireless networks of autonomous entities with various degrees of cooperation