Sound Levels Forecasting in an Acoustic Sensor Network Using a Deep Neural Network

Navarro, Juan M.; Martínez‐España, Raquel; Bueno-Crespo, Andrés; Martínez, Roberto Fernández; Cecilia, José M.

doi:10.3390/s20030903

Cited by 14 publications

(9 citation statements)

References 41 publications

(42 reference statements)

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“…LSTM is an improved model of recurrent neural network (RNN) designed to avoid vanishing gradient problems and able to learn long as well as short term dependencies [19] [20]. LSTM was developed by Sepp Hochreiter and Jürgen Schmidhuber in 1997 [21].…”

Section: Long Short-term Memory (Lstm)mentioning

confidence: 99%

Crude Oil Price Forecasting Using Long Short-Term Memory

Maulana

Saadah

Yunanto

2021

Jurnal Ilmiah Teknik Elektro Komputer Dan Informatika

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Section: Long Short-term Memory (Lstm)mentioning

confidence: 99%

Crude Oil Price Forecasting Using Long Short-Term Memory

Maulana

Saadah

Yunanto

2021

Jurnal Ilmiah Teknik Elektro Komputer Dan Informatika

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“…Another interesting study is presented in [ 60 ], where the authors designed and developed specific noise sensors, placing them in fixed places in the city, so as to perform the monitoring activity, through a WSN. Moreover, the increased computing capacity of the nodes that create the network is allowing the addition of processing algorithms and artificial intelligence that provide more information the environment as exposed in [ 61 ].…”

Section: Related Workmentioning

confidence: 99%

RaveGuard: A Noise Monitoring Platform Using Low-End Microphones and Machine Learning

Monti

Vincenzi

Mirri

et al. 2020

Sensors

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Urban noise is one of the most serious and underestimated environmental problems. According to the World Health Organization, noise pollution from traffic and other human activities, negatively impact the population health and life quality. Monitoring noise usually requires the use of professional and expensive instruments, called phonometers, able to accurately measure sound pressure levels. In many cases, phonometers are human-operated; therefore, periodic fine-granularity city-wide measurements are expensive. Recent advances in the Internet of Things (IoT) offer a window of opportunities for low-cost autonomous sound pressure meters. Such devices and platforms could enable fine time–space noise measurements throughout a city. Unfortunately, low-cost sound pressure sensors are inaccurate when compared with phonometers, experiencing a high variability in the measurements. In this paper, we present RaveGuard, an unmanned noise monitoring platform that exploits artificial intelligence strategies to improve the accuracy of low-cost devices. RaveGuard was initially deployed together with a professional phonometer for over two months in downtown Bologna, Italy, with the aim of collecting a large amount of precise noise pollution samples. The resulting datasets have been instrumental in designing InspectNoise, a library that can be exploited by IoT platforms, without the need of expensive phonometers, but obtaining a similar precision. In particular, we have applied supervised learning algorithms (adequately trained with our datasets) to reduce the accuracy gap between the professional phonometer and an IoT platform equipped with low-end devices and sensors. Results show that RaveGuard, combined with the InspectNoise library, achieves a 2.24% relative error compared to professional instruments, thus enabling low-cost unmanned city-wide noise monitoring.

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“…Finally, in the Special Issue there are two contributions based on the prediction and the use of artificial intelligence on acoustic data. Navarro et al [ 11 ] proposed the forecasting of temporal short-term sound levels as a useful tool for urban planners and managers. A long short-term memory (LSTM) deep neural network technique models the temporal behavior of sound levels at a certain location—both SPL and loudness level—in order to predict near-time future values.…”

Section: Contributionsmentioning

confidence: 99%

Smart Wireless Acoustic Sensor Network Design for Noise Monitoring in Smart Cities

Alsina-Pagès

Bellucci²,

Zambon

2020

Sensors

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This Special Issue is focused on all the technologies necessary for the development of an efficient wireless acoustic sensor network, from the first stages of its design to the tests conducted during deployment; its final performance; and possible subsequent implications for authorities in terms of the definition of policies. This Special Issue collects the contributions of several LIFE and H2020 projects aimed at the design and implementation of intelligent acoustic sensor networks, with a focus on the publication of good practices for the design and deployment of intelligent networks in any locations.

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Sound Levels Forecasting in an Acoustic Sensor Network Using a Deep Neural Network

Cited by 14 publications

References 41 publications

Crude Oil Price Forecasting Using Long Short-Term Memory

Crude Oil Price Forecasting Using Long Short-Term Memory

RaveGuard: A Noise Monitoring Platform Using Low-End Microphones and Machine Learning

Smart Wireless Acoustic Sensor Network Design for Noise Monitoring in Smart Cities

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