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Erschienen in:
Enhancing Fairness and Accuracy in Machine Learning Through Similarity Networks Kapitel lesen Erstes Kapitel lesen

2024 | OriginalPaper | Buchkapitel

Relating Context and Self Awareness in the Internet of Things

verfasst von : David Arnaiz, Marc Vila, Eduard Alarcón, Francesc Moll, Maria-Ribera Sancho, Ernest Teniente

Erschienen in: Cooperative Information Systems

Verlag: Springer Nature Switzerland

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Abstract

Context- and self- awareness are two terms that have been living with us for many years. In principle, both state a similar meaning even though the literature points out a very different path. One is inspired by location-related mechanisms in mobile environments, whereas the other is inspired by biology. In the area of the Internet of Things, the term context-awareness has seen a higher adoption in the field of Cloud Computing, while the term self-awareness is more widely used in the area of Wireless Sensor Networks. This paper evaluates the entire IoT Cloud-to-Thing Continuum in an attempt to reconcile both terms. We contextualize and discuss the literature around context and self-awareness, and we propose a conceptual architecture that handles both concepts, with the aim of having a better understanding of how to develop a software environment that integrates both concepts. To show the real-life applicability of our proposed architecture, it is introduced in a realistic setting such as wildfire monitoring, including a conceptual overview of how the proposed architecture could be implemented in this domain. Additionally, our evaluation of a river flooding scenario concluded that the proposed architecture significantly reduced flood detection delay by over 47% compared to the naive method and over 20% compared to standalone self-awareness and context-awareness methods.

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Vorheriges Kapitel Learning Hierarchical Robot Skills Represented by Behavior Trees from Natural Language
Nächstes Kapitel BAnDIT: Business Process Anomaly Detection in Transactions
Fußnoten
1
Illustrated by dashed lines in Fig. 1 to emphasize the different interactions’ nature.
 
2
River Level and Flows dataset by Alberta Environment and Parks [4].
 
4
The water level prediction model–lightweight linear regression algorithm–employed in the sensor node has some energy overhead, but it is expected to have minimal impact on the sensor node’s overall energy consumption. Hence, this has not been factored into the simulation nor Table 1.
 
Literatur
1.
Aalen, O.O.: A linear regression model for the analysis of life times. Stat. Med. 8(8), 907–925 (1989)CrossRef
2.
3.
Agarwal, A., Miller, J., et al.: Self-aware computing. Technical report, Massachusetts Institute of Technology Cambridge (2009)
4.
5.
6.
Arif, M., Alghamdi, K.K., et al.: Role of machine learning algorithms in forest fire management: a literature review. J. Rob. Autom. 5(1), 212–226 (2021)
7.
Baldauf, M., Dustdar, S., Rosenberg, F.: A survey on context-aware systems. Int. J. Ad Hoc Ubiquitous Comput. 2(4), 263–277 (2007)CrossRef
8.
Brown, P., Bovey, J., Chen, X.: Context-aware applications: from the laboratory to the marketplace. IEEE Pers. Commun. 4(5), 58–64 (1997)CrossRef
9.
Chen, G., Kotz, D.: A survey of context-aware mobile computing research. Technical report, Dartmouth College, United States (2000)
10.
Dustdar, S., Avasalcai, C., Murturi, I.: Edge and fog computing: vision and research challenges. In: IEEE International Conference on Service-Oriented System Engineering, SOSE, pp. 96–105 (2019)
11.
Forooghifar, F., Aminifar, A., et al.: Self-aware anomaly-detection for epilepsy monitoring on low-power wearable electrocardiographic devices. In: IEEE 3rd International Conference on Artificial Intelligence Circuits and Systems, AICAS, pp. 1–4 (2021)
12.
Galar, D., Thaduri, A., et al.: Context awareness for maintenance decision making: a diagnosis and prognosis approach. Measurement 67, 137–150 (2015)CrossRef
13.
Guo, L., Wang, W., et al.: Research and implementation of forest fire early warning system based on UWB wireless sensor networks. In: 2nd International Conference Communication Systems, Networks and Applications, pp. 176–179. ICCSNA (2010)
14.
Hafshejani, E., TaheriNejad, N., et al.: Self-aware data processing for power saving in resource-constrained IoT cyber-physical systems. IEEE Sens. J. 22(4), 3648–3659 (2021)CrossRef
15.
Hoffmann, H., Holt, J., et al.: Self-aware computing in the angstrom processor. In: Proceedings of the 49th Annual Design Automation Conference, pp. 259–264 (2012)
16.
Horn, P.: Autonomic computing: IBM’s perspective on the state of information technology. Technical report, IBM Research (2001)
17.
Jantsch, A., Dutt, N., Rahmani, A.: Self-awareness in systems on chip-a survey. IEEE Design Test 34(6), 8–26 (2017)CrossRef
18.
Kounev, S., Zhu, X., et al.: Model-driven algorithms and architectures for self-aware computing systems (dagstuhl seminar 15041). Dagstuhl Rep. 5(1), 164–196 (2015)
19.
20.
Morin, A.: Levels of consciousness and self-awareness: a comparison and integration of various neurocognitive views. Conscious. Cogn. 15(2), 358–371 (2006)CrossRef
21.
Mudassar, B.A., Ko, J.H., Mukhopadhyay, S.: Edge-cloud collaborative processing for intelligent internet of things: a case study on smart surveillance. In: 55th Annual Design Automation Conference, DAC, pp. 1–6 (2018)
22.
Ortiz, G., Zouai, M., et al.: Atmosphere: context and situational-aware collaborative IoT architecture for edge-fog-cloud computing. Comput. Stand. Interfaces 79, 103550 (2022)CrossRef
23.
Pascoe, J.: Adding generic contextual capabilities to wearable computers. In: 2nd IEEE International Symposium on Wearable Computers, ISWC, pp. 92–99 (1998)
24.
Perera, C., Zaslavsky, A., et al.: CA4IOT: context awareness for internet of things. In: IEEE International Conference on Green Computing and Communications, GreenCom, pp. 775–782 (2012)
25.
Perera, C., Zaslavsky, A., et al.: Context aware computing for the internet of things: a survey. IEEE Commun. Surv. Tutor. 16(1), 414–454 (2014)CrossRef
26.
de Prado, A.G., Ortiz, G., Boubeta-Puig, J.: COLLECT: COLLaborativE ConText-aware service oriented architecture for intelligent decision-making in the Internet of Things. Expert Syst. Appl. 85, 231–248 (2017)CrossRef
27.
Sarwar, B., Bajwa, I., et al.: An intelligent fire warning application using IoT and an adaptive neuro-fuzzy inference system. Sensors 19(14), 3150 (2019)CrossRef
28.
Schilit, B., Adams, N., Want, R.: Context-aware computing applications. In: 1st Workshop on Mobile Computing Systems and Applications, pp. 85–90. HotMobile (1994)
29.
Schilit, B., Theimer, M.: Disseminating active map information to mobile hosts. IEEE Netw. 8(5), 22–32 (1994)CrossRef
30.
Sterritt, R., Bustard, D.: Towards an autonomic computing environment. In: 14th International Workshop Database and Expert Systems Applications, DEXA, pp. 694–698 (2003)
31.
Sunkpho, J., Ootamakorn, C.: Real-time flood monitoring and warning system. Songklanakarin J. Sci. Technol. 33(2) (2011)
32.
Wan, J., Zhang, D., et al.: Context-aware vehicular cyber-physical systems with cloud support: architecture, challenges, and solutions. IEEE Commun. Mag. 52(8), 106–113 (2014)CrossRef
33.
Zhuang, Y., Yu, L., et al.: Data collection with accuracy-aware congestion control in sensor networks. IEEE Trans. Mob. Comput. 18(5), 1068–1082 (2018)CrossRef
Metadaten
Titel
Relating Context and Self Awareness in the Internet of Things
verfasst von
David Arnaiz
Marc Vila
Eduard Alarcón
Francesc Moll
Maria-Ribera Sancho
Ernest Teniente
Copyright-Jahr
2024
Buch
Cooperative Information Systems

Print ISBN: 978-3-031-46845-2

Electronic ISBN: 978-3-031-46846-9

Copyright-Jahr: 2024

DOI
https://doi.org/10.1007/978-3-031-46846-9_21

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