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Boulandet Romain

Professeur HES assistant

Main skills

Professeur HES assistant

Phone: +41 22 558 65 14

Desktop: A122

Haute école du paysage, d'ingénierie et d'architecture de Genève
Rue de la Prairie 4, 1202 Genève, CH

Faculty
Technique et IT

Main Degree Programme
Microtechniques

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2023

Towards the detection and classification of indoor events using a loudspeaker

Scientific paper ArODES

Patrick Marmaroli, Mark Allado, Romain Boulandet

Applied Acoustics, 2023, vol. 202, article no. 109161

Link to the publication

Summary:

In recent decades, smart building has received considerable research attention due to the increased demand for connected and integrated technology. Based on data collected by sensors, alarms, lighting, access control, heating and cleaning can be adjusted according to human activity and the actual needs of the occupants, resulting in efficient energy management and operating cost savings. However, in most cases, these sensors are application-specific, which limits their usefulness and scalability. Of the available sensing technologies, acoustic methods often rely on the use of microphones, which can lead to privacy issues. In this work, we use an electrodynamic loudspeaker in combination with a convolutional neural network algorithm to extract and classify the features of indoor events from the sound field. We show how the loudspeaker impedance is sensitive, through the modal response of the room, to changes in occupancy or room layout (presence of people, movement or removal of furniture), door or window opening, or temperature variation. This gives the speaker a new functionality in addition to audio broadcasting. Theoretical analysis and experiments in real rooms demonstrate the accuracy and effectiveness of this acoustic-based approach for supervised classification of indoor events.

2023

Simulation of a hybrid (active/passive) acoustic measurement room

Conference ArODES

Romain Boulandet, Mark Rallie Allado, Cédric Pinhède, Emmanuel Friot, Renaud Côte, Philippe Herzog

COMSOL Conference 2023 Munich

Link to the conference

Summary:

The ideal way to measure the acoustic performance of heavy items such as vehicles or machines is in a semi-anechoic chamber, i.e. in an environment with no reflections except from the solid floor where the noise source is standing. To accurately measure low frequencies down to 20 Hz (lower limit of the audible frequency range), the walls and ceiling of the room should be non-reflective down to 20 Hz. This is a practical challenge as usual (passive) rooms involve absorbing material (wedges) on the anechoic walls, leading to a lower cut-off frequency related to the wedge thickness: the lower frequency limit corresponds to a thickness close to a quarter of the longest wavelength to be absorbed. For example, a typical wedge length of 0.9 m gives good measurements down to around 100 Hz. An anechoic chamber accurate to 20 Hz would therefore require more than 4 m thick wedges to provide adequate low-frequency absorption: such a test facility would be quite difficult to build and excessively expensive. An alternative has recently been proposed: the DADA (Dome Anti-Diffraction Acoustique). This hybrid control approach combines a thin layer of absorbent (passive) materials with an active system driving a set of loudspeakers designed to cancel out the low-frequency pressure field scattered by the walls. In this paper, we present the scattered field control strategy for room reflections and its implementation in a COMSOL Multiphysics model using the Pressure Acoustics, Frequency Domain interface and LiveLink™ for MATLAB® to run simulations. Results computed in a lightly damped rectangular room over a frequency range of 20 Hz to 200 Hz are provided to show the performance and limitations of the DADA solution in cancelling the scattered pressure field.

2022

Simulations d’un dispositif de semi-anéchoïcité active

Conference ArODES

Cédric Pinhède, Mark Rallie Allado, Romain Boulandet, R. Cote, Emmanuel Friot, Philippe Herzog

Actes du 16e Congrès Français d'Acoustique CFA2022, 11-15 Avril 2022, Marseille, France

Link to the conference

Summary:

Les salles semi-anéchoïques sont utilisées en recherche et pour la caractérisation acoustique de produits industriels. La réalisation de ces salles implique actuellement des infrastructures lourdes et des revêtements absorbants onéreux. L'objectif du projet Dôme Anti-Diffraction Acoustique (DADA) est de montrer qu'il est possible de réaliser une salle semi-anéchoïque à moindre coût, en complétant un revêtement passif par une technologie active. Ce projet vise à réaliser un démonstrateur fonctionnel grandeur nature qui serait aussi un jalon important avant la réalisation de la salle anéchoïque active du Laboratoire de Mécanique et d'Acoustique. De premiers travaux ont permis une première démonstration d'anéchoïcité active consistant à rendre invisible acoustiquement, dans la bande de fréquence 80-200 Hz, la paroi réfléchissante d'une salle semi-anéchoïque à partir d'un réseau de neuf sources anti-bruit et seize microphones. Ces résultats valident aussi une approche novatrice qui consiste à contrôler la pression acoustique à proximité des parois pour obtenir une annulation de la pression dans le volume de mesure. Cette approche comporte plusieurs avantages-notamment celui d'éviter de placer des microphones (et leur supports) dans le volume de mesure, ainsi totalement libéré pour les besoins expérimentaux. Le projet DADA proposé ici s'appuie sur ces résultats mais avec une complexité significativement accrue car il s'agit d'effacer l'effet de cinq parois. La présentation rappellera la méthode d'anéchoïcité active développée au LMA et présentera les premiers résultats de simulation de contrôle du champ réfléchi par cinq parois.

2021

Implementation and performance assessment of a MEMS-based sound level meter

Conference ArODES

Savanne Rémy Kham, Patrick Marmaroli, Jordan Minier, Romain Boulandet

Proceedings of Euronoise 2021, 25-27 October 2021, Madeira, Portugal (online)

Link to the conference

Summary:

Long-established industries in rural areas are now creating noise issues for new communities that have developed nearby. Proactive control of noise emission has therefore become a priority for industries concerned with respecting the tranquillity of residents. The traditional method of noise monitoring utilizes a sound level meter (SLM) which must be installed to areas of interest by trained and experienced personnel. Since a class 1 SLM is relatively expensive, long-term monitoring of large areas can hardly be considered. In this paper, we discuss the practical implementation of a stand-alone MEMS-based SLM capable of recording one-minute time samples and wirelessly transmitting sound level values in third octave bands in the range from 20 Hz to 8 kHz, every 15 minutes. The current prototype uses a digital MEMS microphone with I2S interface connected to an Arduino MKR WiFi 1010 microcontroller for an overall cost of less than 100 CHF. Technical choices for the implementation of the prototype as well as a benchmark with a class 1 SLM are discussed in this paper.

2020

Aeroacoustic measurements on a free-flying drone in a WindShaper wind tunnel

Conference ArODES

Roberto Putzu, Romain Boulandet, Benjamin Rutschmann, Thierry Bujard, Flavio Noca, Catry Guillaume, Nicolas Bosson

Proceedings of Quiet drones 2020 - International e-Symposium on Noise of UAV and UAS, 19-21st October 2020, Paris, France

Link to the conference

Summary:

In the near future, drone usage in inhabited areas is expected to grow exponentially. The inherent noise generated is one of the concerns for this kind of vehicle. Conventional aeroacoustic wind tunnels can be used to investigate uniform-flow generated noise. Flyers are generally solidly tethered to a sting in these wind tunnels. However, the interaction of complex environmental flows with the drone fans is expected to generate different harmonic content, especially during unsteady maneuvers. Being able to probe the aeroacoustic signature of a free-flying drone in a realistic urban and wind environment is a necessity, in particular for future certification procedures. We have developed a new family of wind tunnels, the “WindShaper” (Noca et al. 2019 Wind and Weather Facility for Testing Free-Flying Drones, AIAA Aviation Forum), able to generate complex unsteady flows reproducing environmental gusts and shear flows. The WindShaper consists of an array of a large number of fans (wind-pixels) that may be arranged in various patterns on demand. It is in some ways a digital wind facility that can be programmed to generate arbitrary winds of variable intensity and direction. Various weather conditions (such as rain, snow, hail, fog etc.) that reflect real world situations can be introduced. Drones are in a free-flight configuration (untethered) as in their natural state. These tests can rate drones according to their capacity in maintaining a proper flight attitude and tackling flight perturbations, especially in an urban environment. A WindShaper was modified in order to allow aeroacoustic measurements around a freeflying drone in a turbulent flow. Particular attention was given to a design that allows the drone aeroacoustic signature to be segregated from the aeroacoustic signature of the multi-fan facility. Details on the results achieved in this new infrastructure will be presented and discussed.

2019

Sensorless measurement of the acoustic impedance of a loudspeaker

Conference ArODES

Romain Boulandet

Proceedings of the 23rd International Congress on Acoustics, 9-13 September 2019, Aachen, Germany

Link to the conference

Summary:

This paper presents an experimental approach for estimating the front-side radiation impedance of a loudspeaker. This acoustic load impedance is the reaction of the sound field on the radiating diaphragm which may affect the loudspeaker response, particularly in the low freqauencies due to the coupling with the room modes. In general, this impedance can not be solved analytically because it depends both on the physical characteristics of the speaker and the complexity of the acoustic field in which it radiates. Conventional measurement techniques require sensors such as microphones and accelerometers. The approach proposed here relies mainly on the the reciprocal mechanism of electrodynamic transduction, making it possible to use the loudspeaker as a sensor simultaneously. This work shows that the front-side acoustic impedance can be derived from the speaker input impedance and the knowledge ot its electromechanical parameters. An analytical model is given and data measured in actual rooms provides proof of concept. Potential applications are also discussed.

2018

Tunable flat-plate absorber design for active sound absorption

Conference ArODES

Kristinn Bjornsson, Romain Boulandet, Hervé Lissek

Proceedings of COMSOL Conference, 14 October 2018, Lausanne Switzerland

Link to the conference

Summary:

Noise reduction at low frequencies is a major issue in many workspaces and indoor public places. Unlike mid- and high-frequency noise, low frequency noise is less attenuated by using conventional sound absorbing materials. This communication proposes an electro-mechano-acoustic absorber model that couples three physical domains using plate vibration and sound radiation theories. The mechanical system is an elastically suspended plate specifically developed to favor the piston-like movement thereof. An electromechanical transducer is attached to the plate in order to tailor its dynamic response to incident pressure waves, thereby improving the sound absorption capacity of the system. Structural Mechanics module and Acoustics module are used in this study. We present the design and modeling of this electro-mechano-acoustic system, including the feedback control law which allows to turn it into a tunable electroacoustic absorber. The acoustic performance experimentally achieved from a prototype absorber are then compared to the simulation results.

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Boulandet Romain

Professeur HES assistant

Main skills

Acoustique

Acoustics

Professeur HES assistant

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