Distributed QoS management for internet of things under resource constraints

Samie, Farzad; Tsoutsouras, Vasileios; Xydis, Sotirios; Bauer, Lars; Soudris, Dimitrios; Henkel, Jörg

doi:10.1145/2968456.2974005

Cited by 33 publications

(39 citation statements)

References 24 publications

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“…(1)), including [13], [15], and the recent variant [14] incorporating with adaptive stepsizes. Consider now the per-slot problem (1), which contains the current objective f t (x), the current constraint g t (x) ≤ 0, and a time-invariant feasible set X . With λ ∈ R N + denoting the Lagrange multiplier associated with the time-varying constraint, the online Lagrangian of (1) can be expressed as…”

Section: A Online Saddle-point Approach With Gradient Feedbackmentioning

confidence: 99%

Bandit Convex Optimization for Scalable and Dynamic IoT Management

Chen

Giannakis

2019

IEEE Internet Things J.

109

108

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The present paper deals with online convex optimization involving both time-varying loss functions, and timevarying constraints. The loss functions are not fully accessible to the learner, and instead only the function values (a.k.a. bandit feedback) are revealed at queried points. The constraints are revealed after making decisions, and can be instantaneously violated, yet they must be satisfied in the long term. This setting fits nicely the emerging online network tasks such as fog computing in the Internet-of-Things (IoT), where online decisions must flexibly adapt to the changing user preferences (loss functions), and the temporally unpredictable availability of resources (constraints). Tailored for such human-in-the-loop systems where the loss functions are hard to model, a family of bandit online saddlepoint (BanSaP) schemes are developed, which adaptively adjust the online operations based on (possibly multiple) bandit feedback of the loss functions, and the changing environment. Performance here is assessed by: i) dynamic regret that generalizes the widely used static regret; and, ii) fit that captures the accumulated amount of constraint violations. Specifically, BanSaP is proved to simultaneously yield sub-linear dynamic regret and fit, provided that the best dynamic solutions vary slowly over time. Numerical tests in fog computation offloading tasks corroborate that our proposed BanSaP approach offers competitive performance relative to existing approaches that are based on gradient feedback.

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Section: A Online Saddle-point Approach With Gradient Feedbackmentioning

confidence: 99%

Bandit Convex Optimization for Scalable and Dynamic IoT Management

Chen

Giannakis

2019

IEEE Internet Things J.

109

108

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“…Table 6 summarizes the researches reviewed in this section. Other resource allocation [222,233,255] Energy conservation is one of the main contributors to better system performance and to enhance life quality. Several reviewed ECG monitoring systems proposed solutions for lower energy consumption by reducing signal transmission, processing, and supporting signal compression.…”

Section: Performance-based Monitoring Systemsmentioning

confidence: 99%

“…However, the use of the aforementioned approaches implicate some challenges regarding the lack of interoperability of different wireless devices, short battery life, and some security problems. Another way of reducing energy consumption is optimizing processing techniques and proposing new enhanced algorithms for signal processing [222,233,236,237]. Alternatively, signal compression is used for lower energy consumption in [134,135,[239][240][241][242][243].…”

Section: Performance-based Monitoring Systemsmentioning

confidence: 99%

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ECG Monitoring Systems: Review, Architecture, Processes, and Key Challenges

Serhani

Kassabi

Ismail

et al. 2020

Sensors

179

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Health monitoring and its related technologies is an attractive research area. The electrocardiogram (ECG) has always been a popular measurement scheme to assess and diagnose cardiovascular diseases (CVDs). The number of ECG monitoring systems in the literature is expanding exponentially. Hence, it is very hard for researchers and healthcare experts to choose, compare, and evaluate systems that serve their needs and fulfill the monitoring requirements. This accentuates the need for a verified reference guiding the design, classification, and analysis of ECG monitoring systems, serving both researchers and professionals in the field. In this paper, we propose a comprehensive, expert-verified taxonomy of ECG monitoring systems and conduct an extensive, systematic review of the literature. This provides evidence-based support for critically understanding ECG monitoring systems’ components, contexts, features, and challenges. Hence, a generic architectural model for ECG monitoring systems is proposed, an extensive analysis of ECG monitoring systems’ value chain is conducted, and a thorough review of the relevant literature, classified against the experts’ taxonomy, is presented, highlighting challenges and current trends. Finally, we identify key challenges and emphasize the importance of smart monitoring systems that leverage new technologies, including deep learning, artificial intelligence (AI), Big Data and Internet of Things (IoT), to provide efficient, cost-aware, and fully connected monitoring systems.

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“…Related Work: A few attempts have been made to address similar problems in recent literature. For example, Samie et al have proposed a novel resource management scheme for IoT devices in [2], where they have reasoned out the need for a discrete number of resources at different stages of operation in the context of a smart health application. Further, authors have proposed a QoS based resource allocation approach for smarthealth care application in IoT-enabled networks.…”

Section: Introductionmentioning

confidence: 99%

On Maximizing Task Throughput in IoT-Enabled 5G Networks Under Latency and Bandwidth Constraints

Pratap

Gupta

Nadendla

et al. 2019

2019 IEEE International Conference on Smart Computing (SMARTCOMP)

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Fog computing in 5G networks has played a significant role in increasing the number of users in a given network. However, Internet-of-Things (IoT) has driven system designers towards designing heterogeneous networks to support diverse demands (tasks with different priority values) with different latency and data rate constraints. In this paper, our goal is to maximize the total number of tasks served by a heterogeneous network, labeled task throughput, in the presence of data rate and latency constraints and device preferences regarding computational needs. Since our original problem is intractable, we propose an efficient solution based on graph-coloring techniques. We demonstrate the effectiveness of our proposed algorithm using numerical results, real-world experiments on a laboratory testbed and comparing with the state-of-the-art algorithm.

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Distributed QoS management for internet of things under resource constraints

Cited by 33 publications

References 24 publications

Bandit Convex Optimization for Scalable and Dynamic IoT Management

Bandit Convex Optimization for Scalable and Dynamic IoT Management

ECG Monitoring Systems: Review, Architecture, Processes, and Key Challenges

On Maximizing Task Throughput in IoT-Enabled 5G Networks Under Latency and Bandwidth Constraints

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