A Wireless Sensor Network for Residential Building Energy and Indoor Environmental Quality Monitoring: Design, Instrumentation, Data Analysis and Feedback

Bourdeau, Mathieu; Waeytens, Julien; Aouani, Nedia; Basset, Philippe; Nefzaoui, Elyes

doi:10.3390/s23125580

Cited by 8 publications

(5 citation statements)

References 36 publications

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“…Furthermore, such an evaluation would be highly dependent on the utilized model and the available data, while both aspects should be separated from the methodology. As we will outline in this paper, obtaining accurate or even sufficiently complete data is a non-trivial task, especially when older heating systems have to be retrofitted with measurement devices (sensors), as data acquisition is a research topic in itself [37][38][39]. Our main contribution lies in the methodology and the development of a customizable pipeline from measured data to optimized parameters, which is applied to measured data of a real heating system.…”

Section: Focus and Contributionmentioning

confidence: 99%

Integrated Simulation and Calibration Framework for Heating System Optimization

Djebko,

Weidner,

Waleska

et al. 2024

Sensors

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In a time where sustainability and CO2 efficiency are of ever-increasing importance, heating systems deserve special considerations. Despite well-functioning hardware, inefficiencies may arise when controller parameters are not well chosen. While monitoring systems could help to identify such issues, they lack improvement suggestions. One possible solution would be the use of digital twins; however, critical values such as the water consumption of the residents can often not be acquired for accurate models. To address this issue, coarse models can be employed to generate quantitative predictions, which can then be interpreted qualitatively to assess “better or worse” system behavior. In this paper, we present a simulation and calibration framework as well as a preprocessing module. These components can be run locally or deployed as containerized microservices and are easy to interface with existing data acquisition infrastructure. We evaluate the two main operating modes, namely automatic model calibration, using measured data, and the optimization of controller parameters. Our results show that using a coarse model of a real heating system and data augmentation through preprocessing, it is possible to achieve an acceptable fit of partially incomplete measured data, and that the calibrated model can subsequently be used to perform an optimization of the controller parameters in regard to the simulated boiler gas consumption.

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Section: Focus and Contributionmentioning

confidence: 99%

Integrated Simulation and Calibration Framework for Heating System Optimization

Djebko,

Weidner,

Waleska

et al. 2024

Sensors

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“…Their work emphasized the advantages of UDP in scenarios where occasional data loss is acceptable, making it a suitable choice for applications with time-sensitive data such as temperature monitoring and sensor data transmission. Bourdeau et al [26] presented a wireless sensor network-based thermal imaging system for building energy management. Their study focused on utilizing thermal sensors and wireless communication to monitor and analyze thermal patterns in buildings.…”

Section: Early Researchmentioning

confidence: 99%

Seamless real-time thermal imaging system with ESP8266: wireless data transfer and display using UDP

Moon,

Kaimujjaman,

Hossain

et al. 2023

SN Appl. Sci.

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Thermal imaging technology has become increasingly popular for various applications, including industrial monitoring, building automation, and medical diagnostics. However, existing thermal imaging systems often come with high costs and limited connectivity options. In this paper, we propose a method to address these challenges by utilizing the ESP8266 microcontroller to create a thermal imaging system that can measure thermal pixel values, transfer the data wirelessly using the ESP8266’s networking capabilities and display the pixel data in real-time on a Thin-film-transistor liquid-crystal (TFT) display. The objective is to establish a seamless and real-time transfer of thermal images within a local network environment. User datagram protocol (UDP) supports transmission via broadcast and multicast, making it highly efficient for delivering data to multiple clients or devices on a network. It allows a single UDP packet to be simultaneously sent to multiple destinations, enhancing its effectiveness. This feature simplifies the implementation of network protocols and applications, reducing their overall complexity. UDP is particularly well-suited for devices with limited resources, such as microcontrollers or embedded systems, where memory and computing power are constrained. Experimental results demonstrate the successful transmission and display of thermal pixel data between the ESP8266 microcontrollers using the UDP protocol. The project utilizes the Arduino framework along with ESP8266WiFi and UDP libraries to enable network connectivity and UDP communication. The sender and receiver devices are connected to the same local network, guaranteeing efficient and low-latency transmission of thermal pixel data. The system achieves real-time communication within a radius of approximately 15–18 m, ensuring immediate visualization of thermal images on connected displays. By minimizing latency, the system enables a seamless and instantaneous viewing experience offering seamless and instantaneous image visualization for the users.

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“…Submetering systems involve the installation of additional meters at specific points within a facility to monitor energy consumption in different areas or with specific equipment. Wireless Sensor Networks use wireless communication to connect sensors and devices for monitoring various parameters, including electric quantities and energy consumption [ 3 , 4 ]. These sensors can be deployed in both indoor and outdoor environments.…”

Section: Introductionmentioning

confidence: 99%

Spectrogram Inversion for Reconstruction of Electric Currents at Industrial Frequencies: A Deep Learning Approach

Lalla,

Albini,

Di Barba

et al. 2024

Sensors

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In this paper, we present a deep learning approach for identifying current intensity and frequency. The reconstruction is based on measurements of the magnetic field generated by the current flowing in a conductor. Magnetic field data are collected using a magnetic probe capable of generating a spectrogram, representing the spectrum of frequencies of the magnetic field over time. These spectrograms are saved as images characterized by color density proportional to the induction field value at a given frequency. The proposed deep learning approach utilizes a convolutional neural network (CNN) with the spectrogram image as input and the current or frequency value as output. One advantage of this approach is that current estimation is achieved contactless, using a simple magnetic field probe positioned close to the conductor.

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A Wireless Sensor Network for Residential Building Energy and Indoor Environmental Quality Monitoring: Design, Instrumentation, Data Analysis and Feedback

Cited by 8 publications

References 36 publications

Integrated Simulation and Calibration Framework for Heating System Optimization

Integrated Simulation and Calibration Framework for Heating System Optimization

Seamless real-time thermal imaging system with ESP8266: wireless data transfer and display using UDP

Spectrogram Inversion for Reconstruction of Electric Currents at Industrial Frequencies: A Deep Learning Approach

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