Dynamic grids for finite-difference schemes in musical instrument simulations

Silvin Willemsen, Stefan Bilbao, Michele Ducceschi, Stefania Serafin

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract / Description of output

For physical modelling sound synthesis, many techniques are available; time-stepping methods (e.g., finite-difference time-domain (FDTD) methods) have an advantage of flexibility and generality in terms of the type of systems they can model. These methods do,however, lack the capability of easily handling smooth parameter changes while retaining optimal simulation quality and stability,something other techniques are better suited for. In this paper,we propose an efficient method to smoothly add and remove grid points from a FDTD simulation under sub-audio rate parameter variations. This allows for dynamic parameter changes in physical models of musical instruments. An instrument such as the trombone can now be modelled using FDTD methods, as well as physically impossible instruments where parameters such as e.g.material density or its geometry can be made time-varying. Results show that the method does not produce (visible) artifacts and stability analysis is ongoing.
Original languageEnglish
Title of host publicationProceedings of the 24th International Conference on Digital Audio Effects DAFx20in21
Subtitle of host publicationVienna, September 8-10, 2021
EditorsGianpaolo Evangelista, Nicki Holighaus
Place of PublicationVienna, Austria
Pages144-151
Number of pages8
Volume2
Publication statusPublished - 28 Aug 2021

Publication series

NameProceedings of the International Conference on Digital Audio Effects
ISSN (Print)2413-6700
ISSN (Electronic)2413-6689

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