31 research outputs found
Strategic Availability and Cost Effective UAV-based Flying Access Networks: S-Modular Game Analysis
Telecommunication service providers deploy UAVs to provide flying network
access in remote rural areas, disaster-affected areas or massive-attended
events (sport venues, festivals, etc.) where full set-up to provide temporary
wireless coverage would be very expensive. Of course, a UAV is battery-powered
which means limited energy budget for both mobility aspect and communication
aspect. An efficient solution is to allow UAVs switching their radio modules to
sleep mode in order to extend battery lifetime. This results in temporary
unavailability of communication feature. Within such a situation, the ultimate
deal for a UAV operator is to provide a cost effective service with acceptable
availability. This would allow to meet some target Quality of Service while
having a good market share granting satisfactory benefits. We construct a
duopoly model to capture the adversarial behavior of service providers in terms
of their pricing policies and their respective availability probabilities.
Optimal periodic beaconing (small messages advertising existence of a UAV) is a
vital issue that needs to be addressed, given the UAVs limited battery capacity
and their recharging constraints. A full analysis of the game outcome, both in
terms of equilibrium pricing and equilibrium availability, is derived. We show
that the availability-pricing game exhibits some nice features as it is
sub-modular with respect to the availability policy, whereas it is
super-modular with respect to the service fee. Furthermore, we implement a
learning scheme using best-response dynamics that allows operators to learn
their joint pricing-availability strategies in a fast, accurate and distributed
fashion.Comment: 10 pages, 14 figure
Modeling Slotted Aloha as a Stochastic Game with Random Discrete Power Selection Algorithms
We consider the uplink case of a cellular system where bufferless mobiles transmit over a common channel to a base station, using the slotted aloha medium access protocol. We study the performance of this system under several power differentiation schemes. Indeed, we consider a random set of selectable transmission powers and further study the impact of priorities given either to new arrival packets or to the backlogged ones. Later, we address a general capture model where a mobile transmits successfully a packet if its instantaneous SINR (signal to interferences plus noise ratio) is lager than some fixed threshold. Under this capture model, we analyze both the cooperative team in which a common goal is jointly optimized as well as the noncooperative game problem where mobiles reach to optimize their own objectives. Furthermore, we derive the throughput and the expected delay and use them as the objectives to optimize and provide a stability analysis as alternative study. Exhaustive performance evaluations were carried out, we show that schemes with power differentiation improve significantly the individual as well as global performances, and could eliminate in some cases the bi-stable nature of slotted aloha
Conception de Protocoles de la Couche MAC et Modélisation des Réseaux Hétérogènes de Nouvelle Génération
The present dissertation deals with the problem of under-utilization of collision channels and other related problems in wireless networks. It deals with the design of random access protocols for wireless systems and provides a mathematical framework for performance evaluation of multihop based heterogeneous wireless networks. This thesis is divided into three parts. In the first part, we propose new versions of slotted aloha incorporating power control, priority and hierarchy. Our simulations were important to understand the behaviour of such a system and the real impact of involved parameters (transmit power, transmit rate, arrival rate, hierarchy order). Both team problem (common objective function is maximized) and game problem (each user maximizes its own objective) were discussed. Introducing hierarchy seems to provide many promising improvement without/or with a low amount of external information. We also proposed two distributed algorithms to learn the desired throughput. Next, we developed in the second part an analytical Framework to evaluate performances of multihop based heterogeneous Wireless networks. We built a cross-layer model and derived expression of stability, end-to-end throughput and end-to-end delay. Furthermore, we provided an accurate approximation for the distribution of end-to-end delay in multihop ad hoc networks (operating with slotted aloha protocol). As a direct application, we highlighted how streaming and conversational flows could be supported in this class of ubiquitous networks. The third part of this thesis is devoted to understanding and modelling of IEEE 802.11e DCF/EDCF-operated multihop ad hoc networks. We indeed built a complete and simple APPLICATION/NETWORK/MAC/PHY cross-layered model with finite retries per packet per flow. We analyzed the stability of forwarding queues and derived expression of end-to-end throughput. We finally proposed a Fountain code-based MAC layer to improve the throughput/fairness over the network.Ce manuscrit est centré sur la conception, l'amélioration et l'évaluation des protocoles des couches RESEAU, MAC et PHY. En particulier, nous nous focalisons sur la conception de nouveaux protocoles distribués pour une utilisation optimale/améliorée des ressources radio disponibles. Par ailleurs, nous caractérisons les performances des réseaux ad hoc à accès aléatoire au canal en utilisant des paramètres de plusieurs couches avec aptitude de transfert d'information (data forwarding). La majeure partie de nos analyses se base sur le concept d'interaction entre les couches OSI (cross-layer). En effet, cette nouvelle et attractive approche est devenue en peu de temps omniprésente dans le domaine de recherche et développement et dans le domaine industriel. Les métriques de performances qui nous intéressent sont la stabilité des files d'attentes de transfert, le débit, le délai et la consommation d'énergie. Principalement, la compréhension de l'interaction entre les couches MAC/PHY et routage du standard IEEE 802.11e DCF/EDCF, d'une part, et l'interaction entre noeuds en terme d'interférences, d'autre part, constituent le coeur central de notre travail