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Die digitale Impulsformung als Werkzeug für die Analyse und Synthese von Blasinstrumentenklängen /Oehler, Michael. January 2008 (has links)
Hochsch. für Musik und Theater, Diss.--Hannover, 2007.
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Die digitale Impulsformung als Werkzeug für die Analyse und Synthese von BlasinstrumentenklängenOehler, Michael January 2007 (has links)
Zugl.: Hannover, Hochsch. für Musik und Theater, Diss., 2007
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Trompeten, Hörner und Klarinetten in der in Frankfurt am Main überlieferten "Ordentlichen Kirchenmusik" Georg Philipp TelemannsRettelbach, Simon January 2006 (has links)
Zugl.: Frankfurt (Main), Univ., Diss., 2006
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Zum Entwicklungsprinzip der Blasinstrumente im 16. und 17. JahrhundertBerner, Alfred 24 January 2020 (has links)
No description available.
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Aufführungspraktische Fragen bei Verwendung von Naturtrompeten, Naturhörnern und ZinkenKarstädt, Georg 24 March 2020 (has links)
No description available.
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Blasinstrumentenbau in Dresden in der ersten Hälfte des 19. JahrhundertsGoldammer, Kathleen 03 November 2015 (has links) (PDF)
No description available.
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Blasinstrumentenbau in Dresden in der ersten Hälfte des 19. JahrhundertsGoldammer, Kathleen 03 November 2015 (has links)
No description available.
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Experimental Investigations of Bassoon Acoustics / Experimentelle Untersuchung der Akustik des FagottsGrothe, Timo 19 August 2014 (has links) (PDF)
The bassoon is a conical woodwind instrument blown with a double-reed mouthpiece. The sound is generated by the periodic oscillation of the mouthpiece which excites the air column. The fundamental frequency of this oscillation is determined to a large extent by the resonances of the air column. These can be varied by opening or closing tone-holes. For any given tone hole setting a fine-tuning in pitch is necessary during playing. Musicians adjust the slit opening of the double-reed by pressing their lips against the opposing reed blades. These so-called embouchure corrections are required to tune the pitch, loudness and sound color of single notes. They may be tedious, especially if successive notes require inverse corrections. However, such corrections are essential: Due to the very high frequency sensitivity of the human ear playing in tune is the paramount requirement when playing music. This implies, that embouchure actions provide an important insight into a subjective quality assessment of reed wind instruments from the viewpoint of the musician: An instrument requiring only small corrections will be comfortable to play.
Theoretical investigations of the whole system of resonator, reed, and musician by use of a physical model nowadays still seem insufficient with respect to the required precision. Therefore the path of well-described artificial mouth measurements has been chosen here. For the separate treatment of the resonator and the double-reed, existing classical models have been used. Modifications to these models are suggested and verified experimentally. The influence of the musician is incorporated by the lip force-dependent initial reed slit height. For this investigation a measurement setup has been built that allows precise adjustment of lip force during playing. With measurements of the artificial mouth parameters blowing pressure, mouthpiece pressure, volume-flow rate and axial lip position on reed, the experiment is fully described for a given resonator setting represented by an input impedance curve. By use of the suggested empirical model the adjustment parameters can be turned into model parameters. A large data set from blowing experiments covering the full tonal and dynamical range on five modern German bassoons of different make is given and interpreted.
The experimental data presented with this work can be a basis for extending the knowledge and understanding of the interaction of instrument, mouthpiece and player. On the one hand, they provide an objective insight into tuning aspects of the studied bassoons. On the other hand the experiments define working points of the coupled system by means of quasi-static model parameters.
These may be useful to validate dynamical physical models in further studies. The experimental data provide an important prerequisite for scientific proposals of optimizations of the bassoon and other reed wind instruments. It can further serve as a fundament for the interdisciplinary communication between musicians, musical instrument makers and scientists.
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Experimental Investigations of Bassoon AcousticsGrothe, Timo 03 June 2014 (has links)
The bassoon is a conical woodwind instrument blown with a double-reed mouthpiece. The sound is generated by the periodic oscillation of the mouthpiece which excites the air column. The fundamental frequency of this oscillation is determined to a large extent by the resonances of the air column. These can be varied by opening or closing tone-holes. For any given tone hole setting a fine-tuning in pitch is necessary during playing. Musicians adjust the slit opening of the double-reed by pressing their lips against the opposing reed blades. These so-called embouchure corrections are required to tune the pitch, loudness and sound color of single notes. They may be tedious, especially if successive notes require inverse corrections. However, such corrections are essential: Due to the very high frequency sensitivity of the human ear playing in tune is the paramount requirement when playing music. This implies, that embouchure actions provide an important insight into a subjective quality assessment of reed wind instruments from the viewpoint of the musician: An instrument requiring only small corrections will be comfortable to play.
Theoretical investigations of the whole system of resonator, reed, and musician by use of a physical model nowadays still seem insufficient with respect to the required precision. Therefore the path of well-described artificial mouth measurements has been chosen here. For the separate treatment of the resonator and the double-reed, existing classical models have been used. Modifications to these models are suggested and verified experimentally. The influence of the musician is incorporated by the lip force-dependent initial reed slit height. For this investigation a measurement setup has been built that allows precise adjustment of lip force during playing. With measurements of the artificial mouth parameters blowing pressure, mouthpiece pressure, volume-flow rate and axial lip position on reed, the experiment is fully described for a given resonator setting represented by an input impedance curve. By use of the suggested empirical model the adjustment parameters can be turned into model parameters. A large data set from blowing experiments covering the full tonal and dynamical range on five modern German bassoons of different make is given and interpreted.
The experimental data presented with this work can be a basis for extending the knowledge and understanding of the interaction of instrument, mouthpiece and player. On the one hand, they provide an objective insight into tuning aspects of the studied bassoons. On the other hand the experiments define working points of the coupled system by means of quasi-static model parameters.
These may be useful to validate dynamical physical models in further studies. The experimental data provide an important prerequisite for scientific proposals of optimizations of the bassoon and other reed wind instruments. It can further serve as a fundament for the interdisciplinary communication between musicians, musical instrument makers and scientists.:1 Introduction 1
1.1 Motivation 1
1.2 Scientific Approaches to Woodwind Musical Instruments 3
1.3 Organization of the Thesis 6
2 Acoustical Properties of the Bassoon Air Column 7
2.1 Wave propagation in tubes 7
2.1.1 Theory 7
2.1.2 Transmission Line Modeling 8
2.1.3 Implementation 18
2.1.4 Remarks on Modeling Wall Losses in a Conical Waveguide 19
2.2 Input Impedance Measurement 23
2.2.1 Principle 23
2.2.2 Device 23
2.2.3 Calibration and Correction 24
2.3 Comparison of Theory and Experiment 27
2.3.1 Repeatability and Measurement Uncertainty 27
2.3.2 Comparison of numerical and experimental Impedance Curves 32
2.4 Harmonicity Analysis of the Resonator 35
2.4.1 The Role of the Resonator 35
2.4.2 The reed equivalent Volume 35
2.4.3 Harmonicity Map 36
2.5 Summary 38
3 Characterization of the Double Reed Mouthpiece 41
3.1 Physical Model of the Double-Reed 41
3.1.1 Working Principle 41
3.1.2 Structural Mechanical Characteristics 42
3.1.3 Fluid Mechanical Characteristics 44
3.2 Measurement of Reed Parameters 49
3.2.1 Quasi-stationary Measurement 49
3.2.2 Dynamic Measurement 50
3.3 Construction of an Artificial Mouth 52
3.3.1 Requirements Profile 52
3.3.2 Generic Design 53
3.3.3 The artificial Lip 54
3.3.4 Air Supply 55
3.3.5 Sensors and Data Acquisition 57
3.3.6 Experimental setup 59
3.4 Summary 59
4 Modeling Realistic Embouchures with Reed Parameters 61
4.1 Reed Channel Geometry and Flow Characteristics 61
4.1.1 The Double-Reed as a Flow Duct 61
4.1.2 Bernoulli Flow-Model with Pressure Losses 65
4.1.3 Discussion of the Model 68
4.2 Quasi-static Interaction of Flow and Reed-Channel 72
4.2.1 Pressure-driven Deformation of the Duct Intake 72
4.2.2 Reed-Flow Model including Channel Deformation 75
4.2.3 Influence of Model Parameters 76
4.2.4 Experimental Verification 78
4.3 Effect of the Embouchure on the Reed-Flow 81
4.3.1 Adjustment of the Initial Slit Height 81
4.3.2 Quasi-static Flow in the Deformed Reed-Channel 83
4.3.3 Simplified empirical Model including a Lip Force 85
4.4 Summary 93
5 Survey of Performance Characteristics of the Modern German Bassoon
5.1 Experimental Procedure and Data Analysis 95
5.1.1 Description of the Experiment 95
5.1.2 Time Domain Analysis 97
5.1.3 Spectral Analysis – Period Synchronized Sampling 98
5.1.4 Spectral Centroid and Formants 99
5.1.5 Embouchure parameters 100
5.2 Observations on the Bassoon under Operating Conditions 105
5.2.1 Excitation Parameter Ranges 106
5.2.2 Characteristics of the radiated Sound 110
5.2.3 Reed Pressure Waveform Analysis 115
5.2.4 Summarizing Overview 118
5.3 Performance Control with the Embouchure 120
5.3.1 Register-dependent Embouchure Characteristics 120
5.3.2 Intonation Corrections 123
5.3.3 Sound Color Adjustments 127
5.3.4 Relation to the acoustical Properties of the Resonator 129
5.4 Summary 137
6 Conclusion 139
6.1 Summary 139
6.2 Outlook 141
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