Stochastic analysis of spatial and opportunistic aloha

Spatial Aloha is probably the simplest medium access protocol to be used in a large mobile ad hoc network: each station tosses a coin independently of everything else and accesses the channel if it gets heads. In a network where stations are randomly and homogeneously located in the Euclidean plane, there is a way to tune the bias of the coin so as to obtain the best possible compromise between spatial reuse and per transmitter throughput. This paper shows how to address this questions using stochastic geometry and more precisely Poisson shot noise field theory. The theory that is developed is fully computational and leads to new closed form expressions for various kinds of spatial averages (like e.g. outage, throughput or transport). It also allows one to derive general scaling laws that hold for general fading assumptions. We exemplify its flexibility by analyzing a natural variant of Spatial Aloha that we call Opportunistic Aloha and that consists in replacing the coin tossing by an evaluation of the quality of the channel of each station to its receiver and a selection of the stations with good channels (e.g. fading) conditions. We show how to adapt the general machinery to this variant and how to optimize and implement it. We show that when properly tuned, Opportunistic Aloha very significantly outperforms Spatial Aloha, with e.g. a mean throughput per unit area twice higher for Rayleigh fading scenarios with typical parameters.

[1]  Frank E. Grubbs,et al.  An Introduction to Probability Theory and Its Applications , 1951 .

[2]  François Baccelli,et al.  A Stochastic Geometry Analysis of Dense IEEE 802.11 Networks , 2007, IEEE INFOCOM 2007 - 26th IEEE International Conference on Computer Communications.

[3]  R.L. Cruz,et al.  On the Optimal SINR in Random Access Networks with Spatial Reuse , 2006, 2006 40th Annual Conference on Information Sciences and Systems.

[4]  F. Baccelli,et al.  On a coverage process ranging from the Boolean model to the Poisson–Voronoi tessellation with applications to wireless communications , 2001, Advances in Applied Probability.

[5]  Philippe Jacquet Realistic wireless network model with explicit capacity evaluation , 2008 .

[6]  D. Stoyan,et al.  Stochastic Geometry and Its Applications , 1989 .

[7]  Bartlomiej Blaszczyszyn,et al.  M/D/1/1 loss system with interference and applications to transmit-only sensor networks , 2007, 2007 5th International Symposium on Modeling and Optimization in Mobile, Ad Hoc and Wireless Networks and Workshops.

[8]  François Baccelli,et al.  On the performance of time-space opportunistic routing in multihop Mobile Ad Hoc Networks , 2008, 2008 6th International Symposium on Modeling and Optimization in Mobile, Ad Hoc, and Wireless Networks and Workshops.

[9]  S. T. Buckland,et al.  An Introduction to the Bootstrap. , 1994 .

[10]  Jeffrey G. Andrews,et al.  Capacity Scaling of Ad Hoc Networks with Spatial Diversity , 2007, 2007 IEEE International Symposium on Information Theory.

[11]  François Baccelli,et al.  An Aloha protocol for multihop mobile wireless networks , 2006, IEEE Transactions on Information Theory.

[12]  T. Mattfeldt Stochastic Geometry and Its Applications , 1996 .

[13]  Pierre Brémaud,et al.  Mathematical principles of signal processing , 2002 .

[14]  David Tse,et al.  Fundamentals of Wireless Communication , 2005 .

[15]  Jorma Virtamo,et al.  Exact distribution of Poisson shot noise with constant marks under power-law attenuation , 2006 .

[16]  Bartlomiej Blaszczyszyn,et al.  Using Transmit-Only Sensors to Reduce Deployment Cost of Wireless Sensor Networks , 2008, IEEE INFOCOM 2008 - The 27th Conference on Computer Communications.