| Preface |
|
xvii | |
|
|
|
1 | (22) |
|
1.1 Introduction to the Linear Theory of Sound Wave Motion |
|
|
1 | (7) |
|
1.1.1 Linearization Hypothesis |
|
|
1 | (1) |
|
1.1.2 Partitioning Turbulent Fluctuations |
|
|
2 | (2) |
|
1.1.3 Linearization of Inviscid Fluid Flow |
|
|
4 | (3) |
|
1.1.4 Evolution of Non-Linear Waves |
|
|
7 | (1) |
|
1.2 Representation of Acoustic Waves in the Frequency Domain |
|
|
8 | (6) |
|
|
|
8 | (2) |
|
|
|
10 | (1) |
|
|
|
11 | (1) |
|
1.2.4 Power Spectral Density |
|
|
12 | (2) |
|
1.3 Representation of Waves in the Wavenumber Domain |
|
|
14 | (1) |
|
1.3.1 Spatial Fourier Transform |
|
|
14 | (1) |
|
|
|
15 | (1) |
|
1.4 Intensity and Power of Sound Waves |
|
|
15 | (4) |
|
1.5 Introduction to the Linear System View of Duct Acoustics |
|
|
19 | (2) |
|
|
|
21 | (2) |
|
2 Introduction To Acoustic Block Diagrams |
|
|
23 | (36) |
|
|
|
23 | (2) |
|
2.2 Classification of Acoustic Models of Ducts |
|
|
25 | (4) |
|
2.2.1 Classification by Number of Ports |
|
|
25 | (1) |
|
2.2.2 Classification by Type of Port |
|
|
26 | (1) |
|
2.2.2.1 One-Dimensional Elements |
|
|
27 | (1) |
|
|
|
27 | (2) |
|
2.3 Mathematical Models of Acoustic Elements |
|
|
29 | (4) |
|
|
|
29 | (2) |
|
|
|
31 | (1) |
|
2.3.3 Multi-Port Elements |
|
|
32 | (1) |
|
|
|
33 | (11) |
|
2.4.1 Assembly of Two-Ports |
|
|
34 | (2) |
|
2.4.2 Assembly of Multi-Ports |
|
|
36 | (5) |
|
2.4.3 Optimization of Global Matrix Size |
|
|
41 | (1) |
|
2.4.4 Contraction of Assembled Modal Two-Ports |
|
|
42 | (2) |
|
2.5 Acoustic Elements Based on Numerical Methods |
|
|
44 | (7) |
|
2.5.1 The Finite Element Method |
|
|
45 | (4) |
|
2.5.2 The Boundary Element Method |
|
|
49 | (2) |
|
2.6 Programming Considerations |
|
|
51 | (7) |
|
|
|
58 | (1) |
|
3 Transmission Of Low-Frequency Sound Waves In Ducts |
|
|
59 | (66) |
|
|
|
59 | (1) |
|
3.2 One-Dimensional Theory of Sound Propagation in Ducts |
|
|
60 | (5) |
|
3.2.1 Unsteady Flow Equations |
|
|
60 | (3) |
|
3.2.2 Equations Governing Acoustic Wave Motion |
|
|
63 | (2) |
|
3.3 Solution of Linearized Acoustic Equations |
|
|
65 | (7) |
|
3.3.1 Homogeneous Ducts (ε' = 0) |
|
|
66 | (1) |
|
|
|
67 | (1) |
|
3.3.1.2 Homogeneous Non-Uniform Ducts |
|
|
68 | (1) |
|
3.3.2 Inhomogeneous Ducts (ε' ≠ 0) |
|
|
68 | (1) |
|
3.3.3 Numerical Matrizant Method |
|
|
69 | (3) |
|
3.4 Time-Averaged Power of One-Dimensional Acoustic Waves |
|
|
72 | (1) |
|
3.5 Hard-Walled Uniform Ducts |
|
|
73 | (7) |
|
3.5.1 Wave Transfer Matrix |
|
|
74 | (1) |
|
3.5.2 Traveling Waves and Direction of Propagation |
|
|
75 | (2) |
|
3.5.3 Reflection Coefficient and Standing Waves |
|
|
77 | (2) |
|
3.5.4 Lumped Acoustic Elements |
|
|
79 | (1) |
|
3.6 Hard-Walled Homogeneous Ducts with Non-Uniform Cross Section |
|
|
80 | (5) |
|
3.6.1 Wave Transfer Matrix |
|
|
81 | (3) |
|
3.6.2 High Frequency Approximation |
|
|
84 | (1) |
|
3.7 Ducts Packed with Porous Material |
|
|
85 | (2) |
|
3.8 Acoustic Boundary Conditions on Duct Walls |
|
|
87 | (5) |
|
|
|
87 | (1) |
|
|
|
87 | (1) |
|
|
|
88 | (1) |
|
3.8.1.3 Partial-Slip Model |
|
|
88 | (1) |
|
|
|
89 | (1) |
|
3.8.1.5 Unified Boundary Condition |
|
|
90 | (1) |
|
|
|
91 | (1) |
|
3.9 Homogeneous Ducts with Impermeable Finite Impedance Walls |
|
|
92 | (14) |
|
|
|
93 | (2) |
|
|
|
95 | (2) |
|
3.9.2.1 Direction of Propagation |
|
|
97 | (1) |
|
|
|
98 | (1) |
|
3.9.2.3 Impedance Eduction Formula |
|
|
98 | (1) |
|
3.9.2.4 Peripherally Non-Uniform Wall Impedance |
|
|
98 | (1) |
|
3.9.3 Finite Wall Impedance Models |
|
|
99 | (1) |
|
3.9.3.1 Lined Impermeable Walls |
|
|
99 | (3) |
|
3.9.3.2 Permeable Rigid Porous Walls |
|
|
102 | (1) |
|
3.9.3.3 Perforated Rigid Walls |
|
|
103 | (2) |
|
3.9.3.4 Turbulent Boundary Layer Over Rigid Walls |
|
|
105 | (1) |
|
|
|
105 | (1) |
|
|
|
106 | (6) |
|
3.10.1 Linearized Energy Equation |
|
|
106 | (1) |
|
3.10.2 Matrizant of a Duct with Finite Impedance Walls |
|
|
107 | (2) |
|
3.10.3 Hard-Walled Ducts with Mean Temperature Gradient |
|
|
109 | (3) |
|
3.11 Ducts with Two-Phase Flow |
|
|
112 | (4) |
|
3.12 Ducts with Time-Variant Mean Temperature |
|
|
116 | (6) |
|
|
|
122 | (3) |
|
4 Transmission Of One-Dimensional Waves In Coupled Ducts |
|
|
125 | (48) |
|
|
|
125 | (1) |
|
4.2 Quasi-Static Theory of Wave Transmission at Compact Junctions |
|
|
125 | (4) |
|
4.2.1 Quasi-Static Conservation Laws |
|
|
125 | (3) |
|
4.2.2 Transformation to Pressure Wave Components |
|
|
128 | (1) |
|
4.3 Two Ducts Coupled by Forming Sudden Area Change |
|
|
129 | (14) |
|
|
|
131 | (3) |
|
4.3.1.1 The Case of Zero Mean Flow |
|
|
134 | (1) |
|
|
|
134 | (5) |
|
4.3.1.3 Effect of Inner Duct Wall Thickness |
|
|
139 | (1) |
|
4.3.2 Closed Area Changes |
|
|
140 | (1) |
|
|
|
141 | (2) |
|
4.4 Sudden Area Changes Formed by Multiple Ducts |
|
|
143 | (4) |
|
4.4.1 Identical Inner Ducts |
|
|
144 | (1) |
|
4.4.2 Staggered Inner Duct Extensions |
|
|
145 | (1) |
|
|
|
146 | (1) |
|
4.5 Wave Transmission Through a Perforated Rigid Baffle |
|
|
147 | (3) |
|
|
|
148 | (1) |
|
4.5.2 Lumped Impedance Model |
|
|
149 | (1) |
|
4.6 Wave Transmission in Junction Cavities |
|
|
150 | (3) |
|
4.6.1 Multi-Duct Junction |
|
|
151 | (1) |
|
|
|
152 | (1) |
|
4.7 Continuously Coupled Perforated Ducts |
|
|
153 | (9) |
|
4.7.1 Single-Coupled Perforated Ducts |
|
|
156 | (3) |
|
4.7.1.1 Identical Perforated Ducts |
|
|
159 | (1) |
|
4.7.2 Double-Coupled Perforated Ducts |
|
|
160 | (2) |
|
4.8 Row-Wise Coupled Perforated Ducts |
|
|
162 | (6) |
|
4.8.1 Wave Transfer Across a Row of Apertures |
|
|
163 | (2) |
|
4.8.2 Single-Coupled n-Duct Section |
|
|
165 | (1) |
|
4.8.3 Double-Coupled n-Duct Section |
|
|
166 | (1) |
|
4.8.4 Wave Transfer Matrix of n-Duct Element |
|
|
167 | (1) |
|
4.9 Dissipative Units and Lined Ducts |
|
|
168 | (1) |
|
4.10 Wave Transfer Across Adiabatic Pressure Loss Devices |
|
|
169 | (3) |
|
|
|
172 | (1) |
|
5 Resonators, Expansion Chambers And Silencers |
|
|
173 | (65) |
|
|
|
173 | (4) |
|
5.1.1 Mufflers and Silencers |
|
|
173 | (1) |
|
5.1.2 The System and Its Environment |
|
|
174 | (3) |
|
|
|
177 | (3) |
|
5.2.1 Single-Frequency Analysis |
|
|
177 | (2) |
|
5.2.2 Overall Transmission Loss |
|
|
179 | (1) |
|
|
|
180 | (17) |
|
5.3.1 Resonance and Anti-Resonance Frequencies |
|
|
180 | (1) |
|
|
|
181 | (1) |
|
5.3.3 Single-Duct Resonator |
|
|
182 | (2) |
|
5.3.4 Resonators with Open Outlet |
|
|
184 | (1) |
|
5.3.5 Helmholtz Resonator |
|
|
185 | (2) |
|
5.3.6 Transmission Loss of Resonators |
|
|
187 | (2) |
|
5.3.7 Interferential Resonator |
|
|
189 | (1) |
|
5.3.7.1 Wave Transfer Matrix of Parallel Two-Ports |
|
|
190 | (2) |
|
5.3.7.2 Wave Transfer Matrix of the HQ Tube |
|
|
192 | (1) |
|
5.3.7.3 Herschel-Quincke Tube Resonator |
|
|
193 | (2) |
|
5.3.8 Straight-Through Resonator |
|
|
195 | (2) |
|
|
|
197 | (16) |
|
5.4.1 Through-Flow Expansion Chambers |
|
|
198 | (3) |
|
5.4.2 Transmission Loss of Expansion Chambers |
|
|
201 | (1) |
|
5.4.3 Pure Expansion Chambers |
|
|
202 | (1) |
|
5.4.4 The Strongest Pure Expansion Chamber |
|
|
203 | (2) |
|
5.4.5 Tuning Inlet and Outlet Duct Extensions |
|
|
205 | (2) |
|
5.4.6 Effect of Inlet and Outlet Duct Configurations |
|
|
207 | (1) |
|
5.4.7 Division of a Pure Expansion Chamber |
|
|
208 | (2) |
|
5.4.8 Low-Frequency Response of Chambers |
|
|
210 | (1) |
|
5.4.9 Chambers with a Perforated Duct Bridge |
|
|
211 | (2) |
|
|
|
213 | (1) |
|
|
|
213 | (2) |
|
5.6 Some Practical Issues |
|
|
215 | (9) |
|
|
|
215 | (2) |
|
5.6.2 Variable Mean Flow Conditions |
|
|
217 | (2) |
|
5.6.3 Multiple Outlet Ducts |
|
|
219 | (4) |
|
5.6.4 Flow Excited Resonators and Chambers |
|
|
223 | (1) |
|
5.7 Flow Rate and Back-Pressure Calculation |
|
|
224 | (7) |
|
5.7.1 Calculation of Mean Temperature Drop |
|
|
230 | (1) |
|
|
|
231 | (5) |
|
|
|
236 | (2) |
|
6 Multi-Modal Sound Propagation In Ducts |
|
|
238 | (88) |
|
|
|
238 | (1) |
|
6.2 Uniform Ducts with Axial Mean Flow |
|
|
239 | (4) |
|
6.3 Boundary Condition on Impermeable Walls |
|
|
243 | (4) |
|
|
|
243 | (1) |
|
6.3.2 Partial--Slip Model |
|
|
244 | (1) |
|
|
|
244 | (1) |
|
6.3.4 Modified Ingard--Myers Models |
|
|
245 | (2) |
|
6.4 Wave Transmission in a Uniform Duct with Uniform Mean Flow |
|
|
247 | (3) |
|
6.4.1 General Solution of the Convected Wave Equation |
|
|
247 | (2) |
|
6.4.2 Modal Wave Transfer Matrix |
|
|
249 | (1) |
|
6.5 Hard-Walled Ducts with Uniform Mean Flow |
|
|
250 | (18) |
|
6.5.1 Eigenvalues and the Orthogonality of Eigenfunctions |
|
|
251 | (1) |
|
6.5.2 Propagating and Evanescent Modes |
|
|
252 | (1) |
|
6.5.3 Modal Propagation Angles |
|
|
253 | (2) |
|
6.5.4 Transverse Modes of Common Duct Sections |
|
|
255 | (1) |
|
6.5.4.1 Rectangular Ducts |
|
|
255 | (2) |
|
6.5.4.2 Hollow Circular Ducts |
|
|
257 | (3) |
|
6.5.4.3 Annular Circular Ducts |
|
|
260 | (1) |
|
|
|
261 | (2) |
|
6.5.5 Numerical Determination of Transverse Duct Modes |
|
|
263 | (2) |
|
6.5.6 Time-Averaged Acoustic Power |
|
|
265 | (3) |
|
6.6 Hard-Walled Uniform Ducts Packed with Porous Material |
|
|
268 | (1) |
|
6.7 Lined Uniform Ducts with Uniform Mean Flow |
|
|
269 | (18) |
|
6.7.1 Dispersion Equation for Uniformly Lined Circular Ducts |
|
|
270 | (1) |
|
6.7.1.1 Hard-Liner Solution for Hollow Ducts |
|
|
270 | (2) |
|
6.7.1.2 Iterative Graphical Solution |
|
|
272 | (1) |
|
6.7.2 Dispersion Equations for Uniformly Lined Rectangular Ducts |
|
|
273 | (3) |
|
6.7.3 Discussion of Transverse Modes |
|
|
276 | (2) |
|
|
|
278 | (1) |
|
6.7.3.2 Orthogonolity of Modes |
|
|
279 | (1) |
|
|
|
280 | (2) |
|
6.7.5 Multi-Modal Attenuation Characteristics |
|
|
282 | (3) |
|
6.7.6 Non-Uniformly Lined Ducts |
|
|
285 | (2) |
|
6.8 Uniform Ducts with Sheared Mean Flow |
|
|
287 | (7) |
|
6.8.1 Solution of the Pridmore-Brown Equation |
|
|
288 | (2) |
|
6.8.2 Effect of the Mean Boundary Layer Thickness |
|
|
290 | (4) |
|
6.9 Ducts with Axially Non-Uniform Cross-Sectional Area |
|
|
294 | (5) |
|
6.10 Circularly Curved Ducts |
|
|
299 | (13) |
|
|
|
303 | (6) |
|
6.10.2 Numerical Determination of Angular Wavenumbers |
|
|
309 | (1) |
|
6.10.3 Fundamental-Mode Approximation |
|
|
310 | (2) |
|
6.11 Uniform Ducts with Mean Swirl |
|
|
312 | (4) |
|
6.12 Ducts with Mean Temperature Gradient |
|
|
316 | (6) |
|
6.12.1 Ducts without Mean Flow |
|
|
317 | (4) |
|
6.12.2 Effect of Mean Flow |
|
|
321 | (1) |
|
|
|
322 | (4) |
|
7 Transmission Of Wave Modes In Coupled Ducts |
|
|
326 | (43) |
|
|
|
326 | (1) |
|
7.2 Weak Form of the Convected Wave Equation |
|
|
327 | (1) |
|
7.3 Ducts with Identical Sections |
|
|
328 | (4) |
|
|
|
332 | (8) |
|
7.4.1 Open Sudden Expansion |
|
|
333 | (2) |
|
7.4.1.1 Closed Through-Flow Expansion |
|
|
335 | (1) |
|
7.4.1.2 Closed Flow-Reversing Expansion |
|
|
336 | (1) |
|
7.4.2 Sudden Area Contraction |
|
|
337 | (1) |
|
7.4.3 Open Area Change with Multiple Ducts |
|
|
337 | (3) |
|
|
|
340 | (2) |
|
7.6 Cavity Coupled with Multiple Ducts |
|
|
342 | (5) |
|
7.6.1 Closed Cavity Modes |
|
|
343 | (1) |
|
7.6.2 The Green Function of the Cavity |
|
|
344 | (1) |
|
7.6.3 Coupling the Cavity with Ducts |
|
|
345 | (2) |
|
7.7 Coupled Perforated Ducts |
|
|
347 | (11) |
|
7.7.1 Acoustic Field in a Duct with a Single Aperture |
|
|
349 | (2) |
|
7.7.2 Wave Transfer Across a Row of Apertures |
|
|
351 | (4) |
|
7.7.3 Dissipative Silencers |
|
|
355 | (3) |
|
|
|
358 | (1) |
|
7.8 Contracted Models of Silencers |
|
|
358 | (9) |
|
7.8.1 Expansion Chamber with Offset Inlet and Outlet Ducts |
|
|
359 | (2) |
|
7.8.2 Expansion Chamber with Double Outlet |
|
|
361 | (1) |
|
7.8.3 Flow-Reversing Chamber |
|
|
362 | (1) |
|
7.8.4 Through-Flow Resonator and Muffler |
|
|
363 | (2) |
|
|
|
365 | (2) |
|
|
|
367 | (2) |
|
8 Effects Of Viscosity And Thermal Conductivity |
|
|
369 | (30) |
|
|
|
369 | (1) |
|
8.2 Convected Wave Equation for a Viscothermal Fluid |
|
|
370 | (2) |
|
8.3 Low Reduced Frequency Theory |
|
|
372 | (14) |
|
8.3.1 Circular Hollow Ducts |
|
|
373 | (2) |
|
8.3.1.1 Hard-Walled Ducts |
|
|
375 | (2) |
|
8.3.1.2 Wide-Duct Approximation |
|
|
377 | (2) |
|
8.3.1.3 Effect of Parabolic Mean Flow Velocity Profile |
|
|
379 | (1) |
|
8.3.1.4 Effect of Turbulent Boundary Layer |
|
|
380 | (1) |
|
8.3.2 Circular Annular Ducts |
|
|
381 | (2) |
|
|
|
383 | (3) |
|
8.4 Time-Averaged Acoustic Power |
|
|
386 | (2) |
|
8.5 Sudden Area Changes and Junctions |
|
|
388 | (4) |
|
8.6 Coupled Narrow Ducts with Porous Walls |
|
|
392 | (5) |
|
|
|
397 | (2) |
|
9 Reflection And Radiation At Open Duct Terminations |
|
|
399 | (39) |
|
|
|
399 | (1) |
|
9.2 Reflection Matrix and End-Correction |
|
|
400 | (1) |
|
9.3 Flanged and Unflanged Open Terminations without Mean Flow |
|
|
401 | (7) |
|
9.3.1 Exterior Surface Helmholtz Equation |
|
|
401 | (1) |
|
|
|
402 | (2) |
|
|
|
404 | (2) |
|
|
|
406 | (2) |
|
9.4 Reflection Matrix at an Unflanged Open End with Mean Flow |
|
|
408 | (11) |
|
9.4.1 The Exhaust Problem |
|
|
408 | (3) |
|
|
|
411 | (3) |
|
9.4.2.1 Plane-Wave Reflection Coefficient |
|
|
414 | (2) |
|
9.4.2.2 Reflection of Higher-Order Incident Modes |
|
|
416 | (1) |
|
9.4.3 Reflection at Flow Intakes |
|
|
417 | (1) |
|
9.4.3.1 Plane-Wave Reflection Coefficient |
|
|
418 | (1) |
|
9.5 Acoustic Radiation from Open Ends of Ducts |
|
|
419 | (16) |
|
9.5.1 Modal Radiation Transfer Function |
|
|
419 | (1) |
|
9.5.2 Radiated Acoustic Power |
|
|
419 | (2) |
|
9.5.3 Flanged Open End without Mean Flow |
|
|
421 | (1) |
|
|
|
422 | (2) |
|
9.5.3.2 Rectangular Ducts |
|
|
424 | (2) |
|
9.5.4 Unflanged Circular Open End without Mean Flow |
|
|
426 | (1) |
|
9.5.5 Radiation from Unflanged Circular Open End with Mean Flow |
|
|
427 | (2) |
|
9.5.6 Simple-Source Approximation |
|
|
429 | (2) |
|
9.5.6.1 Effect of Vorticity |
|
|
431 | (1) |
|
|
|
432 | (1) |
|
9.5.8 Effect of Reflecting Surfaces |
|
|
433 | (2) |
|
|
|
435 | (3) |
|
10 Modeling Of Ducted Acoustic Sources |
|
|
438 | (36) |
|
|
|
438 | (2) |
|
10.2 One-Port Sources Characterized by Unsteady Mass Injection |
|
|
440 | (6) |
|
10.3 Moving the Active Plane of One-Port Sources |
|
|
446 | (5) |
|
10.4 Two-Port Sources Characterized by Fluctuating Force Application |
|
|
451 | (8) |
|
|
|
457 | (2) |
|
10.5 Two-Port Sources Characterized by Ducted Combustion |
|
|
459 | (10) |
|
10.5.1 Combustion Oscillations and Instability |
|
|
463 | (6) |
|
10.6 Moving Source Planes of Two-Port Sources |
|
|
469 | (1) |
|
|
|
470 | (2) |
|
|
|
472 | (2) |
|
11 Radiated Sound Pressure Prediction |
|
|
474 | (27) |
|
|
|
474 | (1) |
|
11.2 Calculation of Sound Pressure Field of Ducted Sources |
|
|
474 | (9) |
|
11.2.1 Ducted One-Port Sources |
|
|
476 | (2) |
|
11.2.1.1 One-Dimensional Sources |
|
|
478 | (2) |
|
11.2.2 Ducted Two-Port Sources |
|
|
480 | (2) |
|
11.2.3 Multiple Radiating Outlets |
|
|
482 | (1) |
|
11.3 Analysis of Sound Pressure |
|
|
483 | (4) |
|
|
|
487 | (4) |
|
|
|
488 | (2) |
|
|
|
490 | (1) |
|
11.5 Multi-Modal Transmission Loss Calculations |
|
|
491 | (3) |
|
11.6 In-Duct Sources Characterized by Acoustic Power |
|
|
494 | (6) |
|
|
|
497 | (3) |
|
|
|
500 | (1) |
|
|
|
501 | (32) |
|
|
|
501 | (1) |
|
12.2 Measurement of In-Duct Acoustic Field |
|
|
501 | (9) |
|
12.2.1 Multi-Modal Wave Field Decomposition |
|
|
502 | (1) |
|
12.2.2 The Two-Microphone Method |
|
|
503 | (2) |
|
12.2.2.1 Calibration of Microphones |
|
|
505 | (2) |
|
12.2.2.2 Signal Enhancement |
|
|
507 | (1) |
|
12.2.3 Measurement of the Plane-Wave Reflection Coefficient |
|
|
507 | (1) |
|
12.2.4 Measurement of Wavenumbers |
|
|
508 | (2) |
|
12.3 Measurement of Passive Acoustic Two-Ports |
|
|
510 | (4) |
|
12.3.1 Basics of the Four Microphone Method |
|
|
510 | (1) |
|
12.3.2 Measurement of Attenuation |
|
|
511 | (1) |
|
12.3.3 Measurement of Transmission Loss |
|
|
512 | (1) |
|
12.3.4 Measurement of the Wave Transfer Matrix |
|
|
512 | (2) |
|
12.4 Measurement of One-Port Source Characteristics |
|
|
514 | (16) |
|
12.4.1 The Two-Load Method |
|
|
516 | (1) |
|
12.4.1.1 Implementation with Non-Calibrated Loads |
|
|
516 | (1) |
|
12.4.1.2 Implementation with Calibrated Loads |
|
|
517 | (1) |
|
12.4.2 Geometrical Interpretation of the Two-load Method |
|
|
517 | (1) |
|
12.4.3 The Apollonian Circle of Two Loads |
|
|
518 | (2) |
|
12.4.3.1 Upper and Lower Bounds for Source Pressure Strength |
|
|
520 | (2) |
|
12.4.4 Calculation Bounds to Sound Pressure |
|
|
522 | (1) |
|
12.4.5 The Three-Load Method |
|
|
523 | (1) |
|
12.4.6 Over-Determined Methods |
|
|
524 | (1) |
|
12.4.6.1 Over-Determined Two-Load Method |
|
|
525 | (1) |
|
12.4.6.2 Over-Determined Three-Load Method |
|
|
525 | (1) |
|
12.4.7 The Fuzzy Two-Load Method |
|
|
526 | (1) |
|
12.4.8 The Explicit N-Load Method |
|
|
527 | (3) |
|
12.5 Measurement of Two-Port Source Characteristics |
|
|
530 | (1) |
|
|
|
530 | (3) |
|
13 System Search And Optimization |
|
|
533 | (19) |
|
|
|
533 | (1) |
|
13.2 Direct Random Search |
|
|
534 | (5) |
|
|
|
539 | (1) |
|
|
|
540 | (11) |
|
13.4.1 Acoustic Path Space |
|
|
540 | (3) |
|
13.4.2 Acoustic Path Space on the Attenuation Plane |
|
|
543 | (3) |
|
13.4.3 Signature of Acoustic Paths |
|
|
546 | (2) |
|
13.4.4 System Search in Acoustic Path Space |
|
|
548 | (1) |
|
13.4.5 Acoustic Path Spaces for Different Targets |
|
|
549 | (1) |
|
|
|
549 | (1) |
|
|
|
550 | (1) |
|
|
|
551 | (1) |
|
Appendix A Basic Equations of Fluid Motion |
|
|
552 | (9) |
|
A.1 Integral Forms of Conservation Laws |
|
|
552 | (3) |
|
A.1.1 Conservation of Mass |
|
|
553 | (1) |
|
A.1.2 Conservation of Momentum |
|
|
553 | (1) |
|
A.1.3 Conservation of Energy |
|
|
554 | (1) |
|
A.2 State Equations and the Speed of Sound |
|
|
555 | (1) |
|
A.3 Equations of Motion of Ideal Fluids |
|
|
556 | (2) |
|
A.3.1 Continuity Equation |
|
|
556 | (1) |
|
|
|
557 | (1) |
|
|
|
557 | (1) |
|
A.4 Equation of Motion of Newtonian Fluids |
|
|
558 | (2) |
|
|
|
558 | (1) |
|
|
|
559 | (1) |
|
|
|
560 | (1) |
| Appendix B Acoustic Properties of Rigid-Frame Fibrous Materials |
|
561 | (4) |
| References |
|
565 | (2) |
| Appendix C Impedance of Compact Apertures |
|
567 | (1) |
| C.1 Empirical and Semi-Empirical Models |
|
567 | (4) |
| C.2 Theoretical Models |
|
571 | (6) |
| References |
|
577 | (2) |
| Index |
|
579 | |
