We consider dense wireless random-access networks, modeled as systems of particles with hard-core interaction. The particles represent the network users that try to become active after an exponential back-off time, and stay active for an exponential transmission time. Due to wireless interference, active users prevent other nearby users from simultaneous activity, which we describe as hard-core interaction on a conflict graph. We show that dense networks with aggressive back-off schemes lead to extremely slow transitions between dominant states, and inevitably cause long mixing times and starvation effects
We use fluid limits to explore the (in)stability properties of wireless networks with queue-based ra...
Next-generation wireless networks will likely evolve from cellular and small-scale home networks to ...
Abstract—We consider a stylized stochastic model for a wireless CSMA network. Experimental results i...
We consider dense wireless random-access networks, modeled as systems of particles with hard-core in...
We consider dense wireless random-access networks, modeled as systems of particles with hardcore int...
We examine the impact of torpid mixing and meta-stability issues on the delay performance in wireles...
We consider a stylized stochastic model for a wireless CSMA network. Experimental results in prior s...
Random access schemes are simple and inherently distributed, yet capable of matching the optimal thr...
We explore the achievable delay performance in wireless random-access networks. While relatively sim...
We explore the spatio-temporal congestion dynamics of wireless networks with backlog-based random-ac...
Random-access algorithms such as the Carrier-Sense Multiple-Access (CSMA) protocol provide a popular...
We establish mean-field limits for large-scale random-access networks with buffer dynamics and arbit...
We use fluid limits to explore the (in)stability properties of wireless networks with queue-based ra...
Next-generation wireless networks will likely evolve from cellular and small-scale home networks to ...
Abstract—We consider a stylized stochastic model for a wireless CSMA network. Experimental results i...
We consider dense wireless random-access networks, modeled as systems of particles with hard-core in...
We consider dense wireless random-access networks, modeled as systems of particles with hardcore int...
We examine the impact of torpid mixing and meta-stability issues on the delay performance in wireles...
We consider a stylized stochastic model for a wireless CSMA network. Experimental results in prior s...
Random access schemes are simple and inherently distributed, yet capable of matching the optimal thr...
We explore the achievable delay performance in wireless random-access networks. While relatively sim...
We explore the spatio-temporal congestion dynamics of wireless networks with backlog-based random-ac...
Random-access algorithms such as the Carrier-Sense Multiple-Access (CSMA) protocol provide a popular...
We establish mean-field limits for large-scale random-access networks with buffer dynamics and arbit...
We use fluid limits to explore the (in)stability properties of wireless networks with queue-based ra...
Next-generation wireless networks will likely evolve from cellular and small-scale home networks to ...
Abstract—We consider a stylized stochastic model for a wireless CSMA network. Experimental results i...