Sensor Data Validation for IoT Applications

Applications in the IoT domain need to manage and integrate huge amounts of heterogeneous devices. Usually these devices are treated as external dependencies residing at the edge of the infrastructure mainly transmitting sensed data or reacting to their environment. Recently, these devices will fuel the evolution of the IoT as they feed sensor data to the Internet at a societal scale. Leveraging volunteers and their mobiles as a sensing data collection outlet is known as Mobile Crowd Sensing (MCS) and poses interesting challenges, with particular regard to the management of sensing resource contributors, dealing with their subscription, random and unpredictable join and leave, and node churn. In addition, with the advent of new wireless technologies, it is expected that the use of Machine-Type Communication (MTC) will significantly increase in next generation IoT. MTC has broad application prospects and market potential. In this chapter, we explore new IoT applications for future IoT paradigms.

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Automatic Sensor Data Validation: Improving the Quality and Reliability of Rig Data

10.2118/163726-ms ◽

2013 ◽

Cited By ~ 3

Author(s):

Pradeep Ashok ◽

Eric van Oort ◽

Adrian Ambrus

Keyword(s):

Sensor Data ◽

Data Validation ◽

Quality And Reliability

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A cross-layer framework for sensor data aggregation for IoT applications in smart cities

2016 IEEE International Smart Cities Conference (ISC2) ◽

10.1109/isc2.2016.7580853 ◽

2016 ◽

Cited By ~ 15

Author(s):

Abrar Alkhamisi ◽

Mohamed Saleem Haja Nazmudeen ◽

Seyed M. Buhari

Keyword(s):

Data Aggregation ◽

Smart Cities ◽

Sensor Data ◽

Cross Layer ◽

Iot Applications

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An Adaptive Fuzzy Diagnosis System for On-Line Sensor Data Validation

IFAC Proceedings Volumes ◽

10.1016/s1474-6670(17)37548-1 ◽

1998 ◽

Vol 31 (10) ◽

pp. 131-135 ◽

Cited By ~ 1

Author(s):

A.N. Boudaoud ◽

M.H. Masson

Keyword(s):

Sensor Data ◽

Data Validation ◽

Diagnosis System ◽

Adaptive Fuzzy ◽

On Line ◽

Fuzzy Diagnosis

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An Evaluation of Engine Faults Diagnostics Using Artificial Neural Networks

Volume 4: Manufacturing Materials and Metallurgy; Ceramics; Structures and Dynamics; Controls, Diagnostics and Instrumentation; Education ◽

10.1115/2000-gt-0029 ◽

2000 ◽

Cited By ~ 10

Author(s):

Pong-Jeu Lu ◽

Ming-Chuan Zhang ◽

Tzu-Cheng Hsu ◽

Jin Zhang

Keyword(s):

Neural Network ◽

Fault Diagnosis ◽

Success Rate ◽

Neural Nets ◽

Sensor Data ◽

Trend Detection ◽

Influence Coefficient ◽

Data Validation ◽

Engine Operation ◽

Artificial Neural

Application of artificial neural network (ANN)-based method to perform engine condition monitoring and fault diagnosis is evaluated. Back-propagation, feedforward neural nets are employed for constructing engine diagnostic networks. Noise-contained training and testing data are generated using an influence coefficient matrix and the data scatters. The results indicate that under high-level noise conditions ANN fault diagnosis can only achieve a 50–60% success rate. For situations where sensor scatters are comparable to those of the normal engine operation, the success rates for both 4-input and 8-input ANN diagnoses achieve high scores which satisfy the minimum 90% requirement. It is surprising to find that the success rate of the 4-input diagnosis is almost as good as that of the 8-input. Although the ANN-based method possesses certain capability in resisting the influence of input noise, it is found that a preprocessor that can perform sensor data validation is of paramount importance. Auto-associative neural network (AANN) is introduced to reduce the noise level contained. It is shown that the noise can be greatly filtered to result in a higher success rate of diagnosis. This AANN data validation preprocessor can also serve as an instant trend detector which greatly improves the current smoothing methods in trend detection. It is concluded that ANN-based fault diagnostic method is of great potential for future use. However, further investigations using actual engine data have to be done to validate the present findings.

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Streaming Sensor Data Validation in Networked Infrastructure Systems through Synergic Auto and Cross Similarity Discovery and Analysis

Computing in Civil Engineering 2019 ◽

10.1061/9780784482445.044 ◽

2019 ◽

Author(s):

Lu Xing ◽

Amin Rasekh ◽

M. Ehsan Shafiee ◽

Lina Sela ◽

Ami Preis

Keyword(s):

Sensor Data ◽

Data Validation ◽

Infrastructure Systems

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A Modeling Study of Sensor Data

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.765-767.1259 ◽

2013 ◽

Vol 765-767 ◽

pp. 1259-1262

Author(s):

Feng Liu ◽

Jian Yong Wang ◽

Ming Liu

Keyword(s):

Wireless Sensor Networks ◽

Sensor Networks ◽

Internet Of Things ◽

Statistical Methods ◽

Research Topic ◽

Environmental Data ◽

Sensor Data ◽

Wireless Sensor ◽

Iot Applications ◽

Data Estimation

Nowadays, Internet of Things (IoT) has been becoming a hot research topic. Being an important part of Internet of Things, the wireless sensor networks collect various types of environmental data and construct the fundamental structure of the IoT applications. In order to find out the characteristics of the environmental data, in this paper, we focus on four types of these sensor data: temperature, humidity, light and voltage, and employ statistical methods to analyze and model these sensor data. The results of our research can be used to solve the missing sensor data estimation problem which is inevitable in the wireless sensor networks.

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Dempster–Shafer Theory for Modeling and Treating Uncertainty in IoT Applications Based on Complex Event Processing

Sensors ◽

10.3390/s21051863 ◽

2021 ◽

Vol 21 (5) ◽

pp. 1863

Author(s):

Eduardo Devidson Costa Bezerra ◽

Ariel Soares Teles ◽

Luciano Reis Coutinho ◽

Francisco José da Silva e Silva

Keyword(s):

Performance Metrics ◽

Detection System ◽

Complex Event Processing ◽

Sensor Data ◽

Outbreak Detection ◽

Event Processing ◽

Iot Applications ◽

Dempster Shafer Theory ◽

Shafer Theory ◽

High Level

The Internet of Things (IoT) has emerged from the proliferation of mobile devices and objects connected, resulting in the acquisition of periodic event flows from different devices and sensors. However, such sensors and devices can be faulty or affected by failures, have poor calibration, and produce inaccurate data and uncertain event flows in IoT applications. A prominent technique for analyzing event flows is Complex Event Processing (CEP). Uncertainty in CEP is usually observed in primitive events (i.e., sensor readings) and rules that derive complex events (i.e., high-level situations). In this paper, we investigate the identification and treatment of uncertainty in CEP-based IoT applications. We propose the DST-CEP, an approach that uses the Dempster–Shafer Theory to treat uncertainties. By using this theory, our solution can combine unreliable sensor data in conflicting situations and detect correct results. DST-CEP has an architectural model for treating uncertainty in events and its propagation to processing rules. We describe a case study using the proposed approach in a multi-sensor fire outbreak detection system. We submit our solution to experiments with a real sensor dataset, and evaluate it using well-known performance metrics. The solution achieves promising results regarding Accuracy, Precision, Recall, F-measure, and ROC Curve, even when combining conflicting sensor readings. DST-CEP demonstrated to be suitable and flexible to deal with uncertainty.

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