Large-Scale Physical Modeling Synthesis, Parallel Computing, and Musical Experimentation: The NESS Project in Practice

Sound synthesis using physical modeling, emulating systems of a complexity approaching and even exceeding that of real-world acoustic musical instruments, is becoming possible, thanks to recent theoretical developments in musical acoustics and algorithm design. Severe practical difficulties remain,...

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Bibliographic Details
Published in:Computer music journal 2019-06, Vol.43 (2-3), p.31-47
Main Authors: Bilbao, Stefan, Perry, James, Graham, Paul, Gray, Alan, Kavoussanakis, Kostas, Delap, Gordon, Mudd, Tom, Sassoon, Gadi, Wishart, Trevor, Young, Samson
Format: Article
Language:English
Subjects:
Acoustics
Algorithms
Modelling
Musical instruments
Synthesis
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Summary:Sound synthesis using physical modeling, emulating systems of a complexity approaching and even exceeding that of real-world acoustic musical instruments, is becoming possible, thanks to recent theoretical developments in musical acoustics and algorithm design. Severe practical difficulties remain, both at the level of the raw computational resources required, and at the level of user control. An approach to the first difficulty is through the use of large-scale parallelization, and results for a variety of physical modeling systems are presented here. Any progress with regard to the second difficulty requires, necessarily, the experience and advice of professional musicians. A basic interface to a parallelized large-scale physical modeling synthesis system is presented here, accompanied by first-hand descriptions of the working methods of five composers, each of whom generated complete multichannel pieces using the system.
ISSN:0148-9267
1531-5169
DOI:10.1162/comj_a_00517