Cooling schedules for optimal annealing
Mathematics of Operations Research
Computers and Intractability: A Guide to the Theory of NP-Completeness
Computers and Intractability: A Guide to the Theory of NP-Completeness
Geometry of information propagation in massively dense ad hoc networks
Proceedings of the 5th ACM international symposium on Mobile ad hoc networking and computing
Maximizing throughput in wireless networks via gossiping
SIGMETRICS '06/Performance '06 Proceedings of the joint international conference on Measurement and modeling of computer systems
On traffic load distribution and load balancing in dense wireless multihop networks
EURASIP Journal on Wireless Communications and Networking
Approximating maximum directed flow in a large wireless network
ICC'09 Proceedings of the 2009 IEEE international conference on Communications
On the achievable forwarding capacity of an infinite wireless network
Proceedings of the 13th ACM international conference on Modeling, analysis, and simulation of wireless and mobile systems
The capacity of wireless networks
IEEE Transactions on Information Theory
An Aloha protocol for multihop mobile wireless networks
IEEE Transactions on Information Theory
Closing the Gap in the Capacity of Wireless Networks Via Percolation Theory
IEEE Transactions on Information Theory
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We address the problem of finding efficient combinations of transmitting links between nodes distributed as a spatial Poisson process in an infinite plane using a stochastic optimization method called simulated annealing. A simple Boolean interference model with the interference radius equaling the transmission radius is used to verify the operation of the method. The same approach is then applied to SINR-determined data rates. The obtained numerical results shed light on the spatial reuse problem in wireless multihop networks. In particular, for the SINR-based interference model we obtain new results. We characterize the asymptotic behavior of the sum capacity of the optimal combination of transmitting links and the fraction of transmitting nodes in the low and high interference regimes. Additionally, the numerical results establish, in the interference-limited case of high node densities, the sum capacity (spectral efficiency) to be approximately equal to 1.2 bit/s/Hz per node.