Actran

Actran
Developer(s) Free Field Technologies, MSC Software Company
Stable release
17.0
Operating system Cross-platform
Type CAE software
Acoustic simulation software
License Proprietary EULA
Website www.fft.be

ACTRAN (acronym of ACoustic TRANsmission, also known as the Acoustic NASTRAN) is a finite element-based computer aided engineering software modeling the acoustic behavior of mechanical systems and parts. Actran is being developed by Free Field Technologies, a Belgian software company founded in 1998 by Jean-Pierre Coyette and Jean-Louis Migeot. Free Field Technologies is a wholly owned subsidiary of the MSC Software Corporation since 2011.[1]

History

The development of Actran started in 1998 when Jean-Pierre Coyette, now professor of the Louvain School of Engineering – Université catholique de Louvain, and Jean-Louis Migeot, now professor at the Université Libre de Bruxelles and past-president of the Royal Academy of Science, Letters and Fine Arts of Belgium - Académie royale des sciences, des lettres et des beaux-arts de Belgique, cofounded the Free Field Technologies SA software company. The original idea was to develop a finite element-based simulation tool for vibro-acoustic applications able to overcome the limitations of the then dominant Boundary Element Method. The use of finite elements enabled the simulation of complex noise sources, the combination of multiple materials in the same model and the handling of multi-million degrees-of-freedom models. The initial target application was the prediction of the acoustic transmission through complex partitions (hence the name ACTRAN: ACoustic TRANsmission). A central feature of Actran was the use of Infinite Elements (IE) as an alternative to BEM for modelling non-reflecting boundary conditions and calculating the far field. Actran uses conjugated infinite elements, an extension of the wave envelope technique.[2][3][4][5][6][7]

Early developments were funded by an industrial consortium and the first commercial release was made broadly available in 2002, after the three-years exclusivity period given to the members of the consortium ended.

Software Modules

Actran is written in the python and C++ languages and is compatible with both linux and windows operating systems.

The Actran software is currently divided and licensed into different modules depending on the target application and the physics involved:

Software Interoperability

Actran is integrated with MSC Nastran for vibro-acoustic simulations. Either a MSC Nastran model is translated into an Actran input file, or structural modes are used as part of an Actran analysis. Structural modes can be computed also with other third party softwares.[19]

Actran is coupled with other MSC Software time domain solvers:

See also

References

  1. http://schnitgercorp.com/2011/09/06/msc-acquires-fft-actran/
  2. Astley, R. J., Macaulay, G. J., & Coyette, J. P. (1994). Mapped wave envelope elements for acoustical radiation and scattering. Journal of Sound and Vibration, 170(1), 97-118.
  3. Astley, R. J., Macaulay, G. J., Coyette, J. P., & Cremers, L. (1998). Three-dimensional wave-envelope elements of variable order for acoustic radiation and scattering. Part I. Formulation in the frequency domain. The Journal of the Acoustical Society of America, 103(1), 49-63.
  4. Astley, R. J., Coyette, J. P. (2001). The performance of spheroidal infinite elements. Int. J. Numer. Methods Engrg. 52 (12) 1379–1396.
  5. Astley, R. J., & Coyette, J. P. (2001). Conditioning of infinite element schemes for wave problems. Communications in Numerical Methods in Engineering, 17(1), 31-41.
  6. Coyette, J. P., & Van den Nieuwenhof, B. (2000). A conjugated infinite element method for half-space acoustic problems. The Journal of the Acoustical Society of America, 108(4), 1464-1473.
  7. Van den Nieuwenhof, B., & Coyette, J. P. (2001). Treatment of frequency-dependent admittance boundary conditions in transient acoustic finite/infinite-element models. The Journal of the Acoustical Society of America, 110(4), 1743-1751.
  8. Zhou, Z., & Copiello, D. (2013). Simulation of Exhaust Line Noise Using FEM and TMM. Sound & Vibration, 11.
  9. Caro, S., Ploumhans, P., Brotz, F., Schrumpf, M., Mendonca, F., & Read, A. (2005). Aeroacoustic simulation of the noise radiated by an Helmholtz resonator placed in a duct. AIAA paper, 3067.
  10. Cabrol, M., Detandt, Y., Hartmann, M., & Mutzke, A. (2012, June). A comparison between the effects of turbulent and acoustic wall pressure fluctuations inside a car. In 18th AIAA/CEAS Aeroacoustic Conference (pp. 2012-2202).
  11. d'Udekem, D., Saitoh, M., Van den Nieuwenhof, B., & Yamamoto, T. (2011). Numerical Prediction of the Exhaust Noise Transmission to the Interior of a Trimmed Vehicle by Using the Finite/Infinite Element Method (No. 2011-01-1710). SAE Technical Paper.
  12. Lidoine, S., & Caruelle, B. (2005, July). Fan noise radiation from intake: Comparisons between FEM predictions and fan rig test measurements with flare. In 12th International Congress on Sound and Vibration.
  13. Achunche, I., Astley, J., Sugimoto, R., & Kempton, A. (2009). Prediction of forward fan noise propagation and radiation from intakes. AIAA paper, 3239, 2009.
  14. Schuster, B., Lieber, L., & Vavalle, A. (2010, June). Optimization of a seamless inlet liner using an empirically validated prediction method. In 16th AIAA/CEAS Aeroacoustics Conference, Stockholm, Sweden.
  15. Simulation Helps Airbus Optimize Acoustic Liners and Reduce Noise
  16. Marotta, T. R., Lieber, L. S., & Dougherty, R. P. Validation of Beamforming Analysis Methodology with Synthesized Acoustic Time History Data: Sub-Scale Fan Rig System.
  17. Mosson, A., Binet D., Caprile J. (2014) Simulation of Installation Effects of Aircraft Engine Rear Fan Noise with ACTRAN/DGM. In 20th AIAA/CEAS Aeroacoustics Conference.
  18. Actran Student Edition
  19. www.fft.be
  20. T. El-Dsoki, MSC Software, J. Beuse, X. Robin, "Synergy between multi-body dynamics and acoustic simulation – Application to gear noise of a wind turbine" DAGA 2015
  21. Marriott, D., Ohtomo, T., and Wako, T., "Complete Multi-Discipline Simulation for Sloshing Noise," SAE Technical Paper 2015-01-0672, 2015, doi:10.4271/2015-01-0672.

External links

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