F
Federico Avanzini
Researcher at University of Milan
Publications - 196
Citations - 2251
Federico Avanzini is an academic researcher from University of Milan. The author has contributed to research in topics: Rendering (computer graphics) & Binaural recording. The author has an hindex of 24, co-authored 188 publications receiving 1958 citations. Previous affiliations of Federico Avanzini include University of Padua & University of Verona.
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Multisensory integration of drumming actions: musical expertise affects perceived audiovisual asynchrony
Karin Petrini,Sofia Dahl,Davide Rocchesso,Carl Haakon Waadeland,Federico Avanzini,Aina Puce,Frank E. Pollick +6 more
TL;DR: The results indicated that through musical practice the authors learn to ignore variations in stimulus characteristics that otherwise would affect their multisensory integration processes.
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Mobile virtual reality for musical genre learning in primary education
Edoardo Degli Innocenti,Michele Geronazzo,Diego Vescovi,Rolf Nordahl,Stefania Serafin,Luca A. Ludovico,Federico Avanzini +6 more
TL;DR: The results show that the use of mobile VR technologies in synergy with traditional teaching methodologies can improve the music learning experience in primary education, in terms of active listening, attention, and time.
Modeling collision sounds: non-linear contact force
TL;DR: A model for physically based synthesis of collision sounds is proposed, focused on the non-linear contact force, for which both analytical and experimental results are presented.
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On the Relation Between Pinna Reflection Patterns and Head-Related Transfer Function Features
TL;DR: A model for real-time HRTF synthesis that allows to control separately the evolution of different acoustic phenomena such as head diffraction, ear resonances, and reflections is proposed through the design of distinct filter blocks.
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Interactive Simulation of rigid body interaction with friction-induced sound generation
TL;DR: An algorithmic realization that combines recently proposed physical models of friction with the lumped modal description of resonating bodies is presented, and it is shown that the resulting nonlinear dynamical system can be discretized using a numerical technique that allows efficient and accurate simulation.