Mobility increases the capacity of ad hoc wireless networks
IEEE/ACM Transactions on Networking (TON)
Wi-Fi Handbook: Building 802.11b Wireless Networks
Wi-Fi Handbook: Building 802.11b Wireless Networks
Big Omicron and big Omega and big Theta
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IEEE Transactions on Wireless Communications
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IEEE Transactions on Wireless Communications
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Joint scheduling and power control for wireless ad hoc networks
IEEE Transactions on Wireless Communications
Joint power and bandwidth allocation in downlink transmission
IEEE Transactions on Wireless Communications
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IEEE Transactions on Wireless Communications - Part 2
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IEEE Transactions on Information Theory
A network information theory for wireless communication: scaling laws and optimal operation
IEEE Transactions on Information Theory
A deterministic approach to throughput scaling in wireless networks
IEEE Transactions on Information Theory
The transport capacity of wireless networks over fading channels
IEEE Transactions on Information Theory
Communication over a wireless network with random connections
IEEE Transactions on Information Theory
Resource Allocation for Wireless Fading Relay Channels: Max-Min Solution
IEEE Transactions on Information Theory
Throughput Optimal Control of Cooperative Relay Networks
IEEE Transactions on Information Theory
Throughput Scaling Laws for Wireless Networks With Fading Channels
IEEE Transactions on Information Theory
Distributed interference compensation for wireless networks
IEEE Journal on Selected Areas in Communications
Spectrum sharing for unlicensed bands
IEEE Journal on Selected Areas in Communications
A framework for uplink power control in cellular radio systems
IEEE Journal on Selected Areas in Communications
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A distributed wireless network with K links is considered, where the links are partitioned into M clusters each operating in a subchannel with bandwidth W/M. The subchannels are assumed to be orthogonal to each other. A general shadow-fading model described by the probability of shadowing α and the average cross-link gains ω ≤ 1 is considered. The main goal is to find the maximum network throughput in the asymptotic regime of K → ∞, which is achieved by: (i) proposing a distributed power allocation strategy, where the objective of each user is to maximize its best estimate (based on its local information) of the average network throughput and (ii) choosing the optimumvalue for M. In the first part, the network throughput is defined as the average sum-rate of the network, which is shown to scale as Θ(log K). It is proved that the optimum power allocation strategy for each user for large K is a threshold-based on-off scheme. In the second part, the network throughput is defined as the guaranteed sumrate, when the outage probability approaches zero. It is demonstrated that the on-off power scheme maximizes the throughput, which scales as (W/αω) log K. Moreover, the optimumspectrum sharing for maximizing the average sum-rate and the guaranteed sum-rate is achieved at M = 1.