Ing. Pavel Švancara, Ph.D. |
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Education and academic qualification
- 2007, Ph.D., Faculty of Mechanical Engineering,Brno University of Technology, specialization Applied Mechanics
- 2000, MSc., Faculty of Mechanical Engineering,Brno University of Technology, specialization Engineering Mechanics
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Career overview
- 2004-present, assistant professor, Institute of Solid Mechanics Mechatronics and Biomechanics Faculty of Mechanical Engineering BUT Brno
- 2003-present, researcher, Institute of Thermomechanics Academy of Science of the Czech Republic
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Pedagogic activities
- Statics
- Kinematics
- Dynamics
- Sound and Vibration
- Bioacoustics
- Dynamics of processing machines
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Scientific activities
- Bioacoustics - computational modelling of acoustics of human vocal tract and vocal folds function - analysis of defects and surgical procedures at vocal tract (effect of tonsillectomy), FE model of interaction between fluid induced oscillating vocal folds and acoustic procesess in the vocal tract.
- Sound and vibration - computational and experimental modelling of high-frequency sound and vibration - SEA method (Statistical Energy Analysis), analysis of sound and vibration in mid-frequency and lower frequency range - Finite Element Method FEM, Boundary Element Method BEM, combination FEM + SEA.
- Biomechanics of the cardiovascular system - computational modelling of the interaction between blood flow and the artery wall.
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Prizing by scientific community
- Gunnar Rugheimer Prize at 7th Pan European Voice Conference PEVOC 7 Groningen 2007
- Prize for the best paper from young author at conference Engineering mechanics 2010
- Gunnar Rugheimer Prize at 12th Pan European Voice Conference PEVOC 12 Ghent 2017
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Projects
- Participation on grants projects:
- Czech Science Foundation project No. 21-21935S: Computational modelling of pulsatile flow in compliant tubes with application for tandem carotid stenosis, 2021-2024
- Czech Science Foundation project No. 19-04477S: Modelling and measurements of fluid-structure-acoustic interactions in biomechanics of human voice production, 2019-2021
- Czech Science Foundation project No. 18-13663S: Computational modelling of rupture risk of atherosclerotic plaques in carotid arteries, 2018-2020
- Grant Agency of the Czech Republic, project No P101/12/1306: Biomechanical modelling of human voice production - way to artificial vocal folds. 2012-2015
- Pilot project of Institute of Thermomechanics AS CR, project No 903077: Biomechanics of human voice - acoustic properties of vocal cavities and creation of 3D FEM phonation model. 2011
- Grant Agency of the Czech Republic, project No 101/08/1155: Computer and physical modelling of vibroacoustic properties of human vocal tract for optimization of voice quality. 2008-2010
- Pilot project of Institute of Thermomechanics AS CR, project No 07-03065: Acoustic properties of cavities and their optimization with respect to applications at human voice biomechanics. 2007
- Grant Agency of the Czech Republic, project No 106/04/1025: Modelling of vibroacoustic systems focusing on human vocal tract. 2004-2006
- Grant Agency of the Czech Republic, project No 101/00/0069: The high-grequency noise analysis of vibroacoustic systems. 2000-2002
- Grant Agency of the Czech Republic, project No 106/98/K019: Mathematical and physical modeling of vibroacoustic systems in voice and hearing biomechanics. 1998-2003
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Sum of citations (without self-citations) indexed within SCOPUS
54
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Sum of citations (without self-citations) indexed within ISI Web of Knowledge
36
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Sum of other citations (without self-citations)
10
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Supervised courses:
Publications:
- Švancara, P., Horáček, J., Hrůza V.:
FE modelling of the fluid-structure-acoustic interaction for the vocal folds self-oscillation,
Vibration Problems ICOVP 2011, pp.801-807, ISBN 978-94-007-2068-8, (2011), Springer
conference paper
akce: The 10th International Conference on Vibration Problems - ICOVP 2011, Praha, 05.09.2011-08.09.2011
- MIŠUN, V.; ŠVANCARA, P.; VAŠEK, M.:
Experimental Analysis of the Characteristics of Artificial Vocal Folds, Journal of Voice
journal article in Web of Science
- ŠVANCARA, P., HORÁČEK, J.:
Numerical Modelling of Effect of Tonsillectomy on Production of Czech Vowels, S. Hirzel Verlag
journal article in Web of Science
- ŠVANCARA, P., HORÁČEK, J., VOKŘÁL, J., ČERNÝ, L.:
Computational modelling of effect of tonsillectomy on voice production,
Logopedics Phoniatrics Vocology, Vol.31, (2006), No.3, pp.117-125, ISSN 1401-5439, Taylor & Francis
journal article - other
- ŠVANCARA, P.; HORÁČEK, J.:
FE modelling of effect of tonsillectomy on production of Czech vowels,
Inženýrská mechanika - Engineering Mechanics, Vol.12, (2005), No.5, pp.347-354, ISSN 1210-2717
journal article - other
List of publications at Portal BUT
- Švancara, P., Horáček, J., Hrůza V.:
FE modelling of the fluid-structure-acoustic interaction for the vocal folds self-oscillation,
Vibration Problems ICOVP 2011, pp.801-807, ISBN 978-94-007-2068-8, (2011), Springer
conference paper
akce: The 10th International Conference on Vibration Problems - ICOVP 2011, Praha, 05.09.2011-08.09.2011
The flow induced self/oscillation of the human vocal folds in interaction with acoustic processes on the simplified vocal tract model was explored by 3D FE model. Developed FE model includes vocal folds pretension before phonation, large deformations of the vocal tissue, vocal folds contact, fluid-structure interaction, morphing the fluid mesh according the vocal folds motion (ALE approach), unsteady viscous compressible airflow described by the Navier-Stokes equations and airflow separation during the glottis closure. Iterative partitioned approach is used for modelling the fluid-structure interaction. Computed results prove that the developed model can be used for simulation of the vocal folds self-oscillation and resulting acoustic waves. The developed model enables to numerically simulate an influence of some pathological changes in the vocal fold tissue on the voice production.
- MIŠUN, V.; ŠVANCARA, P.; VAŠEK, M.:
Experimental Analysis of the Characteristics of Artificial Vocal Folds, Journal of Voice
journal article in Web of Science
The article focuses on the constructional definition of artificial vocal folds and their experimental analysis. The analysis is conducted for voiced source voice phonation and for the changing mean value of the subglottal pressure. The article further deals with the analysis of the pressure of the airflow through the vocal folds, which is cut (separated) into individual pulses by the vibrating vocal folds. The analysis results show that air pulse characteristics are relevant to voice generation, as they are produced by the flowing air and vibrating vocal folds.
- LAUKANNEN, A. M., HORÁČEK, J., ŠVANCARA, P., LEHTINEN, E.:
Effects of FE Modelled Consequences of Tonillectomy on Perceptual Evaluation of Voice,
INTERSPEECH 2007: 8TH ANNUAL CONFERENCE OF THE INTERNATIONAL SPEECH COMMUNICATION ASSOCIATION, pp.1182-1185, ISBN 978-1-60560-316-2, (2007), ISCA-INST SPEECH COMMUNICATION ASSOC,
conference paper
akce: INTERSPEECH 2007: 8TH ANNUAL CONFERENCE OF THE INTERNATIONAL SPEECH COMMUNICATION ASSOCIATION, Antwerp, Belgium, 27.08.2007-31.08.2007
This study aimed to investigate the effects of a tonsillectomy on the perceived overall voice quality and timbre. Computer simulations of five Czech vowels were made, including both the calculated resonance effects of large tonsils (size 1.6 cm3) and the resonances without tonsils. The simulations were made using a finite element model of the vocal tract, based on magnetic resonance images. The size and shape of the tonsils were ascertained from clinical data. The generated pressure outputs were transformed into sound records presented to 10 trained listeners. Formant frequencies of the simulated samples were measured. The samples with and without tonsils did not differ significantly from each other in voice quality. F3 was significantly lower and the timbre was darker without tonsils. Thus, the effects of tonsillectomy on voice may be perceptible, at least in the case of large tonsils. The effect, however, may disappear in time due to changes in the tissue and due to compensatory changes in articulation.
- ŠVANCARA, P., HORÁČEK, J.:
Numerical Modelling of Effect of Tonsillectomy on Production of Czech Vowels, S. Hirzel Verlag
journal article in Web of Science
Aim of the study is to numerically examine the effect of tonsillectomy on production of Czech vowels. Similar experimental studies on living subjects are not easily realisable. The finite element (FE) models of the acoustic spaces corresponding to the human vocal tracts and acoustic space around the human head are used in numerical simulations of phonation. Models for Czech vowels /a/, /e/, /i/, /o/ and /u/ are analyzed. The acoustic resonant characteristics of the FE models are studied using modal and transient analyses (excitation by a short pulse). The production of vowels is simulated in time domain using transient analysis of the FE models excited by Liljencrants-Fants (LF) glottal signal model. Calculated results show that tonsillectomy causes frequency shifts of some formant frequencies mostly down to lower frequencies. Biggest shifts were obtained for 3rd and 4th formants for vowel /o/ ~300Hz down to lower frequencies, for 3rd (~450Hz) and 4th (~150Hz) formants for vowel /u/ and for 4th (~200Hz) formant of vowel /e/ down too. The frequency shifts of the formants are significantly dependent on position and size of the tonsils.
- ŠVANCARA, P., HORÁČEK, J., VOKŘÁL, J., ČERNÝ, L.:
Computational modelling of effect of tonsillectomy on voice production,
Logopedics Phoniatrics Vocology, Vol.31, (2006), No.3, pp.117-125, ISSN 1401-5439, Taylor & Francis
journal article - other
The aim of this study is to develop mathematical 3D finite element (FE) models for numerical simulations of vibroacoustic properties of the human vocal tract after a tonsillectomy. Similar experimental studies are not easily realisable on living subjects.
The FE models of the acoustic spaces corresponding to the human vocal tract for the Czech vowels /A/ and /I/ and the acoustic space around the human head were used in numerical simulations of phonation. The acoustic resonant characteristics of the FE models were studied using modal and transient analyses (excitation by a short pulse).
Calculated results show that a tonsillectomy causes a frequency shift of the 3rd (~180Hz) and 4th (~120Hz) formants down to the lower frequencies for the vowel /A/ and similarly for the 2nd, 4th and 5th formants for the vowel /I/ (all ~100Hz). Similar effects and results can be found in experimental studies in literature. The formant changes are dependent on the size of additional acoustic spaces that occur after a tonsillectomy. The verification of the model was performed on the recordings of patients before and after the tonsillectomy operation. Multi-Dimensional Voice Program (MDVP Advanced, KAY Elemetrics) was used for the comparing of the formant center frequencies. Very small differences in the results of subjective evaluation of the voice before and after tonsillectomy were found.