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ORCIDStefan Bilbao
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2020 – today
- 2024
[j30]Samuel Poirot
, Stefan Bilbao, Richard Kronland-Martinet:
A simplified and controllable model of mode coupling for addressing nonlinear phenomena in sound synthesis processes. EURASIP J. Audio Speech Music. Process. 2024(1): 38 (2024)- [i6]Chin-Yun Yu, Christopher Mitcheltree, Alistair Carson, Stefan Bilbao, Joshua D. Reiss, György Fazekas:
Differentiable All-pole Filters for Time-varying Audio Systems. CoRR abs/2404.07970 (2024) - [i5]Alistair Carson, Alec Wright, Jatin Chowdhury, Vesa Välimäki, Stefan Bilbao:
Sample Rate Independent Recurrent Neural Networks for Audio Effects Processing. CoRR abs/2406.06293 (2024) - [i4]Alistair Carson, Alec Wright, Stefan Bilbao:
Interpolation filter design for sample rate independent audio effect RNNs. CoRR abs/2409.15884 (2024) - 2023
- [j29]Stefan Bilbao, Michele Ducceschi, Fabiana Zama:
Explicit exactly energy-conserving methods for Hamiltonian systems. J. Comput. Phys. 472: 111697 (2023) - [j28]Samuel Poirot, Stefan Bilbao, Mitsuko Aramaki, Sølvi Ystad, Richard Kronland-Martinet:
A Perceptually Evaluated Signal Model: Collisions Between a Vibrating Object and an Obstacle. IEEE ACM Trans. Audio Speech Lang. Process. 31: 2338-2350 (2023) - [i3]Alistair Carson, Cassia Valentini-Botinhao, Simon King, Stefan Bilbao:
Differentiable Grey-box Modelling of Phaser Effects using Frame-based Spectral Processing. CoRR abs/2306.01332 (2023) - 2022
- [j27]Stefan Bilbao:
3D Interpolation in Wave-Based Acoustic Simulation. IEEE Signal Process. Lett. 29: 384-388 (2022) - [j26]Michele Ducceschi, Stefan Bilbao:
Non-Iterative Simulation Methods for Virtual Analog Modelling. IEEE ACM Trans. Audio Speech Lang. Process. 30: 3189-3198 (2022) - [i2]Stefan Bilbao, Michele Ducceschi, Fabiana Zama:
Explicit Exactly Energy-conserving Methods for Hamiltonian Systems. CoRR abs/2206.12391 (2022) - 2021
- [j25]Jens Ahrens, Stefan Bilbao:
Computation of Spherical Harmonic Representations of Source Directivity Based on the Finite-Distance Signature. IEEE ACM Trans. Audio Speech Lang. Process. 29: 83-92 (2021) - [c30]Michele Ducceschi, Stefan Bilbao, Craig J. Webb:
Non-Iterative Schemes for the Simulation of Nonlinear Audio Circuits. DAFx 2021: 25-32 - [c29]Mohammed Danish, Stefan Bilbao, Michele Ducceschi:
Applications of Port Hamiltonian Methods to Non-Iterative Stable Simulations of the KORG35 and MOOG 4-Pole VCF. DAFx 2021: 33-40 - [c28]Silvin Willemsen, Stefan Bilbao, Michele Ducceschi, Stefania Serafin:
Dynamic Grids for Finite-Difference Schemes in Musical Instrument Simulations. DAFx 2021: 144-151 - [c27]Silvin Willemsen, Stefan Bilbao, Michele Ducceschi, Stefania Serafin:
A Physical Model of the Trombone Using Dynamic Grids for Finite-Difference Schemes. DAFx 2021: 152-159 - [i1]Michele Ducceschi, Stefan Bilbao:
Simulation of the Geometrically Exact Nonlinear String via Energy Quadratisation. CoRR abs/2112.15008 (2021) - 2020
- [j24]Stefan Bilbao, Charlotte Desvages, Michele Ducceschi, Brian Hamilton, Reginald Harrison-Harsley, Alberto Torin, Craig J. Webb:
Physical Modeling, Algorithms, and Sound Synthesis: The NESS Project. Comput. Music. J. 43(2-3): 15-30 (2020) - [j23]Stefan Bilbao, James Perry, Paul Graham, Alan Gray, Kostas Kavoussanakis, Gordon Delap, Tom Mudd, Gadi Sassoon, Trevor Wishart, Samson Young:
Large-Scale Physical Modeling Synthesis, Parallel Computing, and Musical Experimentation: The NESS Project in Practice. Comput. Music. J. 43(2-3): 31-47 (2020) - [c26]Jens Ahrens, Stefan Bilbao:
Interpolation and Range Extrapolation of Sound Source Directivity Based on a Spherical Wave Propagation Model. ICASSP 2020: 4662-4666
2010 – 2019
- 2019
- [j22]Stefan Bilbao, Archontis Politis, Brian Hamilton:
Local Time-Domain Spherical Harmonic Spatial Encoding for Wave-Based Acoustic Simulation. IEEE Signal Process. Lett. 26(4): 617-621 (2019) - [j21]Stefan Bilbao, Brian Hamilton:
Directional Sources in Wave-Based Acoustic Simulation. IEEE ACM Trans. Audio Speech Lang. Process. 27(2): 415-428 (2019) - 2018
- [j20]Stefan Bilbao, Brian Hamilton:
Higher-order accurate two-step finite difference schemes for the many-dimensional wave equation. J. Comput. Phys. 367: 134-165 (2018) - 2017
- [j19]Stefan Bilbao, Fabian Esqueda, Julian D. Parker, Vesa Välimäki:
Antiderivative Antialiasing for Memoryless Nonlinearities. IEEE Signal Process. Lett. 24(7): 1049-1053 (2017) - [j18]Brian Hamilton, Stefan Bilbao:
FDTD Methods for 3-D Room Acoustics Simulation With High-Order Accuracy in Space and Time. IEEE ACM Trans. Audio Speech Lang. Process. 25(11): 2112-2124 (2017) - [c25]Stefan Bilbao, Brian Hamilton:
Directional source modeling in wave-based room acoustics simulation. WASPAA 2017: 121-125 - [c24]Stefan Bilbao, Fabian Esqueda, Vesa Välimäki:
Antiderivative antialiasing, lagrange interpolation and spectral flatness. WASPAA 2017: 141-145 - 2016
- [j17]Stefan Bilbao, Brian Hamilton:
Passive time-domain numerical designs for room acoustics simulation. Proc. Meet. Acoust. 28(1) (2016) - [j16]Brian Hamilton, Stefan Bilbao:
Optimised 25-point finite difference schemes for the three-dimensional wave equation. Proc. Meet. Acoust. 28(1) (2016) - [j15]Stefan Bilbao, Brian Hamilton, Jonathan Botts, Lauri Savioja:
Finite Volume Time Domain Room Acoustics Simulation under General Impedance Boundary Conditions. IEEE ACM Trans. Audio Speech Lang. Process. 24(1): 161-173 (2016) - [j14]Fabian Esqueda, Stefan Bilbao, Vesa Välimäki:
Aliasing Reduction in Clipped Signals. IEEE Trans. Signal Process. 64(20): 5255-5267 (2016) - [c23]Fabian Esqueda, Vesa Välimäki, Stefan Bilbao:
Antialiased soft clipping using an integrated bandlimited ramp. EUSIPCO 2016: 1043-1047 - [c22]Thomas Resch, Stefan Bilbao:
Controlling complex virtuel instruments - A setup with note for Max and prepared piano sound synthesis. NIME 2016: 295-299 - 2015
- [j13]Reginald Langford Harrison, Stefan Bilbao, James Perry, Trevor Wishart:
An Environment for Physical Modeling of Articulated Brass Instruments. Comput. Music. J. 39(4): 80-95 (2015) - [c21]Fabian Esqueda, Vesa Välimäki, Stefan Bilbao:
Aliasing reduction in soft-clipping algorithms. EUSIPCO 2015: 2014-2018 - [c20]James Perry, Stefan Bilbao, Alberto Torin:
Hierarchical Parallelism in a Physical Modelling Synthesis Code. PARCO 2015: 207-216 - 2014
- [c19]Brian Hamilton, Stefan Bilbao, Craig J. Webb:
Revisiting Implicit Finite Difference Schemes for Three-Dimensional Room Acoustics Simulations on GPU. DAFx 2014: 41-48 - [c18]Stefan Bilbao, Alberto Torin:
Numerical Simulation of String/Barrier Collisions: The Fretboard. DAFx 2014: 137-144 - [c17]Alberto Torin, Brian Hamilton, Stefan Bilbao:
An Energy Conserving Finite Difference Scheme for the Simulation of Collisions in Snare Drums. DAFx 2014: 145-152 - [c16]Stefan Bilbao, Alberto Torin, Paul Graham, James Perry, Gordon Delap:
Modular Physical Modeling Synthesis Environments on GPU. ICMC 2014 - 2013
- [j12]Leonardo Gabrielli, Vesa Välimäki, Henri Penttinen, Stefano Squartini, Stefan Bilbao:
A digital waveguide-based approach for Clavinet modeling and synthesis. EURASIP J. Adv. Signal Process. 2013: 103 (2013) - [j11]Stefan Bilbao:
Modeling of Complex Geometries and Boundary Conditions in Finite Difference/Finite Volume Time Domain Room Acoustics Simulation. IEEE Trans. Speech Audio Process. 21(7): 1524-1533 (2013) - 2012
- [j10]Stefan Bilbao:
Optimized FDTD Schemes for 3-D Acoustic Wave Propagation. IEEE Trans. Speech Audio Process. 20(5): 1658-1663 (2012) - 2011
- [c15]Craig J. Webb, Stefan Bilbao:
Computing room acoustics with CUDA - 3D FDTD schemes with boundary losses and viscosity. ICASSP 2011: 317-320 - [c14]Leonardo Gabrielli, Vesa Välimäki, Stefan Bilbao:
Real-time emulation of the Clavinet. ICMC 2011 - 2010
- [j9]Stefan Bilbao, Julian Parker:
A Virtual Model of Spring Reverberation. IEEE Trans. Speech Audio Process. 18(4): 799-808 (2010) - [j8]Stefan Bilbao:
Percussion Synthesis Based on Models of Nonlinear Shell Vibration. IEEE Trans. Speech Audio Process. 18(4): 872-880 (2010)
2000 – 2009
- 2009
- [j7]Stefan Bilbao:
Direct Simulation of Reed Wind Instruments. Comput. Music. J. 33(4): 43-55 (2009) - [c13]Mark Kahrs, David Skulina, Stefan Bilbao, Murray Campbell:
An Electroacoustically Controlled Vibrating Plate. NIME 2009: 106-109 - 2007
- [j6]Stefan Bilbao:
Robust Physical Modeling Sound Synthesis for Nonlinear Systems. IEEE Signal Process. Mag. 24(2): 32-41 (2007) - [j5]Stefan Bilbao, Lauri Savioja, Julius O. Smith III:
Parameterized Finite Difference Schemes for Plates: Stability, the Reduction of Directional Dispersion and Frequency Warping. IEEE Trans. Speech Audio Process. 15(4): 1488-1495 (2007) - [j4]Erdem Motuk, Roger F. Woods, Stefan Bilbao, John McAllister:
Design Methodology for Real-Time FPGA-Based Sound Synthesis. IEEE Trans. Signal Process. 55(12): 5833-5845 (2007) - 2006
- [j3]Stefan Bilbao:
Fast modal synthesis by digital waveguide extraction. IEEE Signal Process. Lett. 13(1): 1-4 (2006) - [c12]David T. Fee, C. F. N. Cowan, Stefan Bilbao, Izzet Ozcelik:
Predictive deconvolution and kurtosis maximization for speech dereverberation. EUSIPCO 2006: 1-5 - [c11]Stefan Bilbao, Kevin Arcas, Antoine Chaigne:
A Physical Model for Plate Reverberation. ICASSP (5) 2006: 165-168 - 2005
- [j2]Stefan Bilbao:
Time-varying generalizations of all-pass filters. IEEE Signal Process. Lett. 12(5): 376-379 (2005) - [c10]Stefan Bilbao:
An energy-conserving difference scheme for nonlinear coupled transverse/longitudinal string vibration. EUSIPCO 2005: 1-4 - [c9]Erdem Motuk, Roger F. Woods, Stefan Bilbao:
Parallel implementation of finite difference schemes for the plate equation on a FPGA-based multi-processor array. EUSIPCO 2005: 1-4 - [c8]Erdem Motuk, Roger F. Woods, Stefan Bilbao:
FPGA-Based Hardware for Physical Modelling Sound Synthesis by Finite Difference Schemes. FPT 2005: 103-110 - [c7]Jyri Pakarinen, Matti Karjalainen, Vesa Välimäki, Stefan Bilbao:
Energy behavior in time-varying fractional delay filters for physical modeling synthesis of musical instruments. ICASSP (3) 2005: 1-4 - [c6]Erdem Motuk, Roger F. Woods, Stefan Bilbao:
Implementation of finite difference schemes for the wave equation on FPGA. ICASSP (3) 2005: 237-240 - [c5]Stefan Bilbao, Maarten van Walstijn:
A Finite difference plate Model. ICMC 2005 - [c4]Maarten van Walstijn, Michael Alcorn, Stefan Bilbao:
Spatialisation using Sounding Objects. ICMC 2005 - 2004
- [c3]Stefan Bilbao:
Energy-conserving finite difference schemes for tension-modulated strings. ICASSP (4) 2004: 285-288 - 2003
- [j1]Stefan Bilbao, Julius O. Smith III:
Finite difference schemes and digital waveguide networks for the wave equation: stability, passivity, and numerical dispersion. IEEE Trans. Speech Audio Process. 11(3): 255-266 (2003) - 2002
- [c2]Julien Bensa, Stefan Bilbao, Richard Kronland-Martinet, Julius O. Smith III:
From the Physics of Piano Strings to Digital Waveguides. ICMC 2002
1990 – 1999
- 1996
- [c1]Tony S. Verma, Stefan Bilbao, Teresa H.-Y. Meng:
The digital prolate spheroidal window. ICASSP 1996: 1351-1354
Coauthor Index
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