1,899 research outputs found
Latency Optimal Broadcasting in Noisy Wireless Mesh Networks
In this paper, we adopt a new noisy wireless network model introduced very
recently by Censor-Hillel et al. in [ACM PODC 2017, CHHZ17]. More specifically,
for a given noise parameter any sender has a probability of
of transmitting noise or any receiver of a single transmission in its
neighborhood has a probability of receiving noise.
In this paper, we first propose a new asymptotically latency-optimal
approximation algorithm (under faultless model) that can complete
single-message broadcasting task in time units/rounds in any
WMN of size and diameter . We then show this diameter-linear
broadcasting algorithm remains robust under the noisy wireless network model
and also improves the currently best known result in CHHZ17 by a
factor.
In this paper, we also further extend our robust single-message broadcasting
algorithm to multi-message broadcasting scenario and show it can broadcast
messages in time rounds. This new robust
multi-message broadcasting scheme is not only asymptotically optimal but also
answers affirmatively the problem left open in CHHZ17 on the existence of an
algorithm that is robust to sender and receiver faults and can broadcast
messages in time rounds.Comment: arXiv admin note: text overlap with arXiv:1705.07369 by other author
Towards Optimal Distributed Node Scheduling in a Multihop Wireless Network through Local Voting
In a multihop wireless network, it is crucial but challenging to schedule
transmissions in an efficient and fair manner. In this paper, a novel
distributed node scheduling algorithm, called Local Voting, is proposed. This
algorithm tries to semi-equalize the load (defined as the ratio of the queue
length over the number of allocated slots) through slot reallocation based on
local information exchange. The algorithm stems from the finding that the
shortest delivery time or delay is obtained when the load is semi-equalized
throughout the network. In addition, we prove that, with Local Voting, the
network system converges asymptotically towards the optimal scheduling.
Moreover, through extensive simulations, the performance of Local Voting is
further investigated in comparison with several representative scheduling
algorithms from the literature. Simulation results show that the proposed
algorithm achieves better performance than the other distributed algorithms in
terms of average delay, maximum delay, and fairness. Despite being distributed,
the performance of Local Voting is also found to be very close to a centralized
algorithm that is deemed to have the optimal performance
A Self-Organization Framework for Wireless Ad Hoc Networks as Small Worlds
Motivated by the benefits of small world networks, we propose a
self-organization framework for wireless ad hoc networks. We investigate the
use of directional beamforming for creating long-range short cuts between
nodes. Using simulation results for randomized beamforming as a guideline, we
identify crucial design issues for algorithm design. Our results show that,
while significant path length reduction is achievable, this is accompanied by
the problem of asymmetric paths between nodes. Subsequently, we propose a
distributed algorithm for small world creation that achieves path length
reduction while maintaining connectivity. We define a new centrality measure
that estimates the structural importance of nodes based on traffic flow in the
network, which is used to identify the optimum nodes for beamforming. We show,
using simulations, that this leads to significant reduction in path length
while maintaining connectivity.Comment: Submitted to IEEE Transactions on Vehicular Technolog
Precoder Design for Physical Layer Multicasting
This paper studies the instantaneous rate maximization and the weighted sum
delay minimization problems over a K-user multicast channel, where multiple
antennas are available at the transmitter as well as at all the receivers.
Motivated by the degree of freedom optimality and the simplicity offered by
linear precoding schemes, we consider the design of linear precoders using the
aforementioned two criteria. We first consider the scenario wherein the linear
precoder can be any complex-valued matrix subject to rank and power
constraints. We propose cyclic alternating ascent based precoder design
algorithms and establish their convergence to respective stationary points.
Simulation results reveal that our proposed algorithms considerably outperform
known competing solutions. We then consider a scenario in which the linear
precoder can be formed by selecting and concatenating precoders from a given
finite codebook of precoding matrices, subject to rank and power constraints.
We show that under this scenario, the instantaneous rate maximization problem
is equivalent to a robust submodular maximization problem which is strongly NP
hard. We propose a deterministic approximation algorithm and show that it
yields a bicriteria approximation. For the weighted sum delay minimization
problem we propose a simple deterministic greedy algorithm, which at each step
entails approximately maximizing a submodular set function subject to multiple
knapsack constraints, and establish its performance guarantee.Comment: 37 pages, 8 figures, submitted to IEEE Trans. Signal Pro
A General Class of Throughput Optimal Routing Policies in Multi-hop Wireless Networks
This paper considers the problem of throughput optimal routing/scheduling in
a multi-hop constrained queueing network with random connectivity whose special
case includes opportunistic multi-hop wireless networks and input-queued switch
fabrics. The main challenge in the design of throughput optimal routing
policies is closely related to identifying appropriate and universal Lyapunov
functions with negative expected drift. The few well-known throughput optimal
policies in the literature are constructed using simple quadratic or
exponential Lyapunov functions of the queue backlogs and as such they seek to
balance the queue backlogs across network independent of the topology. By
considering a class of continuous, differentiable, and piece-wise quadratic
Lyapunov functions, this paper provides a large class of throughput optimal
routing policies. The proposed class of Lyapunov functions allow for the
routing policy to control the traffic along short paths for a large portion of
state-space while ensuring a negative expected drift. This structure enables
the design of a large class of routing policies. In particular, and in addition
to recovering the throughput optimality of the well known backpressure routing
policy, an opportunistic routing policy with congestion diversity is proved to
be throughput optimal.Comment: 31 pages (one column), 8 figures, (revision submitted to IEEE
Transactions on Information Theory
Random Geometric Graphs and the Initialization Problem for Wireless Networks
32 pages. Tutorial invitéInternational audienceThe initialization problem, also known as naming, assigns one unique identifier (ranging from 1 to ) to a set of n indistinguishable nodes (stations or processors) in a given wireless network . is composed of nodes randomly deployed within a square (or a cube) . We assume the time to be slotted and to be synchronous; two nodes are able to communicate if they are within a distance at most of each other ( is the transmitting/receiving range). Moreover, if two or more neighbors of a processor transmit concurrently at the same round, does not receive either messages. After the analysis of various critical transmitting/sensing ranges for connectivity and coverage of randomly deployed sensor networks, we design sub-linear randomized initialization and gossip algorithms achieving and O(n^3/4 \log (n)^1/4) rounds
Making recommendations bandwidth aware
This paper asks how much we can gain in terms of bandwidth and user
satisfaction, if recommender systems became bandwidth aware and took into
account not only the user preferences, but also the fact that they may need to
serve these users under bandwidth constraints, as is the case over wireless
networks. We formulate this as a new problem in the context of index coding: we
relax the index coding requirements to capture scenarios where each client has
preferences associated with messages. The client is satisfied to receive any
message she does not already have, with a satisfaction proportional to her
preference for that message. We consistently find, over a number of scenarios
we sample, that although the optimization problems are in general NP-hard,
significant bandwidth savings are possible even when restricted to polynomial
time algorithms
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