Prix bas
CHF155.20
Impression sur demande - l'exemplaire sera recherché pour vous.
The purpose of this book is to j.ir'~ 0l'l' a new technique for the experimental investigation of the free wave model sound field of acoustics. The technique is based on the use of spherical harmonic functions of angle. Acousticians frequently encounter random sound fields whose properties may be closely modelled by use of the "free wave" field. This model field is defined by two basic statistical properties: stationarity in time, and homogeneity in space. Stationarity means that any single order statistic measured by a microphone in the field will be independent of the time at which the recording is taken, while homogeneity means that the measurement will also be independent of the mic- phone's position in the field. Furthermore, second order statistics obtained from the measurements of two microphones will depend only on the time lapse between the two recordings, and the relative spatial separation of the micro phones, and not on the microphones' absolute positions in space and time. The free wave field may also (equivalently) be pictured as a collection of plane sound waves which approach an observation position from all angles. These are the "free waves" of the title, with no correlation between waves at different angles and frequencies, although there may exist an angle-dependant plane wave density function. This is a measure of the density of sound energy arriving from different angles. The free wave field has proved to be a simple but remarkably powerful model.
Texte du rabat
The purpose of this book is to j.ir '~ 0l'l' a new technique for the experimental investigation of the free wave model sound field of acoustics. The technique is based on the use of spherical harmonic functions of angle. Acousticians frequently encounter random sound fields whose properties may be closely modelled by use of the "free wave" field. This model field is defined by two basic statistical properties: stationarity in time, and homogeneity in space. Stationarity means that any single order statistic measured by a microphone in the field will be independent of the time at which the recording is taken, while homogeneity means that the measurement will also be independent of the mic- phone's position in the field. Furthermore, second order statistics obtained from the measurements of two microphones will depend only on the time lapse between the two recordings, and the relative spatial separation of the micro phones, and not on the microphones' absolute positions in space and time. The free wave field may also (equivalently) be pictured as a collection of plane sound waves which approach an observation position from all angles. These are the "free waves" of the title, with no correlation between waves at different angles and frequencies, although there may exist an angle-dependant plane wave density function. This is a measure of the density of sound energy arriving from different angles. The free wave field has proved to be a simple but remarkably powerful model.
Contenu
1 Introduction.- 2 The Free Wave Sound Field.- 2.1 Introduction.- 2.2 Properties of the Free Wave Field.- 2.3 Spectral Density Measurement in Free Wave Fields: Cook's Theorem.- 2.4 Extension of Cook's Theorem for Anisotropic Fields.- 2.5 Summary.- References.- Figures.- 3 Inference of the Plane Wave Weighting Function From Spectral Density Measurements.- 3.1 Introduction.- 3.2 Cook's Theorem and Nondiffuse Fields.- 3.3 Inductive Weighting Analysis: Parametric Models.- 3.4 Direct Weighting Analysis: Theoretical Inverse.- 3.5 Direct Weighting Analysis: Wavenumber Spectra.- 3.6 Direct Weighting Analysis: Stationary Phase Approximation.- 3.7 Direct Weighting Analysis: Spherical Harmonic Expansions.- 3.8 Conclusions.- References.- Figures.- 4 The Spherical Harmonic Analysis of Free Wave Fields in Practice.- 4.1 Introduction.- 4.2 Formulation of the Harmonic Search Problem: Least Squares Fitting.- 4.3 Harmonic Analysis of the Gravitational and Magnetic Fields of Planets.- 4.4 Development of Harmonic Search Procedure.- 4.5 Development of Axisymmetric Harmonic Search Procedure.- 4.6 Properties of Analysis Results.- 4.7 Conclusions.- References.- Figures.- Tables.- 5 Summary.- Appendix A.- Appendix B.- Appendix C.