Minimum-latency aggregation scheduling in wireless sensor networks under physical interference model

Li, Hongxing; Hua, Qiang Sheng; Wu, Chuan; Lau, Francis C. M.

doi:10.1145/1868521.1868581

Cited by 48 publications

(41 citation statements)

References 19 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Data Aggregation. In single-channel networks, there is a long line of research on data aggregation under different settings in the protocol model [30,31,32] and the SINR model [1,2,10,14,16,17,23,24]. Regarding distributed solutions in the SINR model, a distributed aggregation algorithm with uniform power assignment was proposed in [24], which achieves a latency upper bound of O(D + ∆).…”

Section: Related Workmentioning

confidence: 99%

“…Regarding distributed solutions in the SINR model, a distributed aggregation algorithm with uniform power assignment was proposed in [24], which achieves a latency upper bound of O(D + ∆). Assuming a model where every node in the network knows its position, the network diameter and the number of neighbors, Li et al [23] presented a distributed algorithm with a latency bound of O(K), where K is the logarithm of the ratio between the length of the longest link and that of the shortest link. This result additionally needs that nodes can adjust the transmission power arbitrarily.…”

Section: Related Workmentioning

confidence: 99%

See 1 more Smart Citation

Leveraging multiple channels in ad hoc networks

Halldórsson

Wang

2018

Distrib. Comput.

View full text Add to dashboard Cite

We examine the utility of multiple channels of communication in wireless networks under the SINR model of interference. The central question is whether the use of multiple channels can result in linear speedup, up to some fundamental limit. We answer this question affirmatively for the data aggregation problem, perhaps the most fundamental problem in sensor networks. To achieve this, we form a hierarchical structure of independent interest, and illustrate its versatility by obtaining a new algorithm with linear speedup for the node coloring problem.

show abstract

Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Leveraging multiple channels in ad hoc networks

Halldórsson

Wang

2018

Distrib. Comput.

View full text Add to dashboard Cite

show abstract

“…, ← ⌀; (4) for all such that 1 ≤ ≤ do (5) if | | ≤ | | then (6) put into ; (7) else (8) put into ; (9) ← ∪ ⟨ , ⟩; (10) return ; Algorithm 3: ℎ (Δ).…”

Section: Building Ir-subgraphs Let the Th Cfd Bementioning

confidence: 99%

Data Inconsistency Evaluation for Cyberphysical System

Wang

Gao

2016

International Journal of Distributed Sensor Networks

View full text Add to dashboard Cite

Cyberphysical systems (CPSs) have been widely applied in a variety of applications to collect data, while data is often dirty in reality. We pay attention to the way of evaluating data inconsistency which is a major concern for evaluating quality of data and its source. This paper is the first study on data inconsistency evaluation problem for CPS based on conditional functional dependencies. Given a database instance including tuples and a CFD set Σ including CFDs, data inconsistency is defined as the ratio of the size of minimum culprit in , where a culprit is a set of tuples leading to integrity errors. Firstly, we give a sufficient analysis on the complexity and inapproximability of minimum culprit problem. Then, we provide a practical algorithm that gives a 2-approximation of the data dirtiness in ( log ) time based on independent residual subgraph. To deal with the large dynamic data, we provide a compact structure based on B-tree for storing independent residual subgraph in order to update inconsistency efficiently. At last, we test our algorithm on both synthetic and real-life datasets; the experiment results show the scalability of our algorithm and the quality of the evaluation result.

show abstract

“…Constraint (19) ensures that only one Iset is chosen in slot k and constraint (20) allows a link to be active in slot k if and only if an Iset containing it is active in that slot. Note that all the links in any given Iset satisfy the interference constraints by construction and hence the original interference constraints (15)(16) are redundant in the problem formulation.…”

Section: First Transformation: Averaging Over Timementioning

confidence: 99%

“…The discrete time dimension disappears from the constraints (7)(8)(9)(10)(11)(12)(13)(14) and (19)(20) when we sum each of them over k and divide with T m , leading to problem P 2 (m). Note that after this summation, all q s,w,p i (k) variables cancel from the equations (8), (9) and (10), except when k = 0 and k = T m .…”

Section: First Transformation: Averaging Over Timementioning

confidence: 99%

Maximum Achievable Throughput in a Wireless Sensor Network Using In-Network Computation for Statistical Functions

Sappidi

Girard²,

Rosenberg

2013

IEEE/ACM Trans. Networking

View full text Add to dashboard Cite

Abstract-Many applications require the sink to compute a function of the data collected by the sensors. Instead of sending all the data to the sink, the intermediate nodes could process the data they receive to significantly reduce the volume of traffic transmitted: this is known as in-network computation. Instead of focusing on asymptotic results for large networks as is the current practice, we are interested in explicitly computing the maximum achievable throughput of a given network when the sink is interested in the first M statistical moments of the collected data. Here, the k-th statistical moment is defined as the expectation of the k-th power of the data.Flow models have been routinely used in multi-hop wireless networks when there is no in-network computation and they are typically tractable for relatively large networks. However, deriving such models is not obvious when in-network computation is allowed. We develop a discrete-time model for the real-time network operation and perform two transformations to obtain a flow model that keeps the essence of in-network computation. This gives an upper bound on the maximum achievable throughput. To show its tightness, we derive a numerical lower bound by computing a solution to the discrete-time model based on the solution to the flow model. This lower bound turns out to be close to the upper bound proving that the flow model is an excellent approximation to the discrete-time model. We then provide several engineering insights on these networks.

show abstract

Minimum-latency aggregation scheduling in wireless sensor networks under physical interference model

Cited by 48 publications

References 19 publications

Leveraging multiple channels in ad hoc networks

Leveraging multiple channels in ad hoc networks

Data Inconsistency Evaluation for Cyberphysical System

Maximum Achievable Throughput in a Wireless Sensor Network Using In-Network Computation for Statistical Functions

Contact Info

Product

Resources

About