Cover
Half Title
Title Page
Copyright Page
Brief Contents
Table of Contents
Preface
Authorsβ acknowledgements
Publisherβs acknowledgements
Terminology and notation
Chapter 1 The nature and behaviour of sound
1.1 A qualitative picture of wave motion
1.2 Frequency and wavelength and sound speed
1.3 A mathematical description of a plane progressive wave
1.4 The audible range of sound pressures and frequencies
1.5 Sound pressure, sound power, sound intensity and acoustic impedance
1.6 More complex waveforms β frequency analysis, peak and RMS values
1.7 The decibel scale
1.8 Equal loudness contours and the A-weighting network, dBA
1.9 Types of elastic waves in solids and fluids
1.10 Absorption and attenuation of sound
1.11 Diffraction
1.12 Reflection
1.13 Interference and standing waves
1.14 Refraction
Appendix 1.1 Octave and one third octave band centre bands and bandwidths
Questions
Chapter 2 Sound propagation
2.1 Introduction
2.2 The geometric spreading of sound
2.3 Monopole, dipole and vibrating piston sources
2.4 Near and far acoustic fields of sound sources
2.5 Directivity of sound sources
2.6 The prediction of sound levels from real sound sources
2.7 Outdoor sound propagation
2.8 Absorption of sound in air
2.9 Attenuation from propagation close to the ground
2.10 Refraction of sound in the atmosphere
2.11 Barriers
2.12 Other sound propagation effects
2.13 Prediction of outdoor sound levels and noise mapping
2.14 The Doppler effect
Questions
Chapter 3 Human response to noise
3.1 Introduction
3.2 The ear
3.3 Aspects of hearing
3.4 Audiometry
3.5 Types and sources of hearing loss
3.6 Estimation of risk of noise induced hearing loss
3.7 Assessment of loudness of sound
3.8 Noisiness, the Noy and PNdB
3.9 Acceptable noise levels inside buildings
3.10 Other adverse effects of noise on health
Questions
Chapter 4 Environmental noise
4.1 Introduction
4.2 Time varying noise β continuous equivalent noise level, LAeq,T
4.3 A review of time varying noise descriptors
4.4 The assessment of public response to environmental noise
4.5 A brief history of the development of noise indices and criteria
4.6 Prediction assessment and mitigation of environmental noise
4.7 Legislation, regulations, standards and codes of practice
Questions
Chapter 5 Room acoustics
5.1 Introduction
5.2 Sound absorption
5.3 Room acoustics
5.4 The transient case of Sabine acoustics
5.5 Sabine acoustics for steady state situations
5.6 Room acoustics measurements
5.7 Room modes
5.8 Design of rooms for a good acoustic environment
5.9 Sound intensity and energy density in a diffuse sound field
Appendix 5.1 Derivation of standing wave tube formula
Appendix 5.2 Derivation of Eyringβs formula
Appendix 5.3 Derivation of Sabineβs formula
Appendix 5.4 Derivation of formula for reverberant sound level in a room
Questions
Chapter 6 Sound insulation
6.1 Introduction
6.2 Sound reduction index of composite partitions
6.3 Sound transmission calculations
6.4 The measurement of sound insulation
6.5 Rating of sound insulation
6.6 Factors affecting sound reduction index of partitions
6.7 Summary of Building Regulations 2000 Part E (2003 edition)
6.8 Flanking paths and structure-borne sound
Appendix 6.1 Derivation of room to room transmission equation
Questions
Chapter 7 Vibration
7.1 Introduction
7.2 The nature of vibration
7.3 Displacement, velocity and acceleration
7.4 The behaviour of a massβspringβdamper system
7.5 Vibration isolation
7.6 The assessment of vibration
7.7 Radiation of sound from a vibrating surface
Appendix 7.1 The mathematical theory of the massβspringβdamper system
Questions
Chapter 8 Measurement and instrumentation
8.1 Introduction
8.2 The measurement of sound levels
8.3 Microphones
8.4 Linearity, frequency response and dynamic range
8.5 The use of analogue and digital signal processing in sound level meters
8.6 Frequency analysis
8.7 The performance of sound level meters
8.8 Introduction to the principles of the direct measurement of acoustic intensity
8.9 The measurement of sound power levels
8.10 The measurement of vibration
8.11 Calibration of noise and vibration measurements
8.12 Measurement uncertainty
8.13 A measurement and instrumentation exercise
Questions
Chapter 9 Noise control
9.1 Introduction
9.2 Control of noise by good planning and management
9.3 Noise control strategy for multiple sources
9.4 Mechanisms of noise generation
9.5 Noise from machinery β simple model
9.6 The reduction of noise from sound radiating surfaces
9.7 Diagnosis β sources, mechanisms, paths and radiating areas
9.8 Control of sound transmission: absorption, insulation, isolation and damping
9.9 Acoustic enclosures
9.10 Fan and duct noise and attenuators
9.11 Reactive silencers
9.12 Jets and exhausts
9.13 Active noise control
9.14 The specification of noise from machinery, sound pressure level and sound power level
9.15 Hearing protectors
9.16 The Control of Noise at Work Regulations 2005: a summary
Appendix 9.1 Derivation of enclosure insertion loss formula
Questions
Chapter 10 The law relating to noise
10.1 English law
10.2 European Union law
10.3 The eradication or reduction of noise or vibration at common law
10.4 Statute law: nuisances
10.5 Construction sites
10.6 Noise in streets and neighbourhoods
10.7 Noise abatement zones
10.8 Noise and personal health and welfare
10.9 The Land Compensation Act 1973: compensation for noise caused by public works
10.10 Insulation requirements under the Building Regulations
10.11 Spatial planning (town and country planning)
10.12 Civil aviation
10.13 Road traffic noise
10.14 Covenants in a lease
10.15 Restrictive covenants
10.16 By-laws
10.17 Human rights
Appendix 10.1 Industrial noise control: the integrated pollution prevention and control regime
Appendix 10.2 Case law: significance, operation and access β a short guide for non-lawyers
Appendix 10.3 General textbooks on environmental law (including law on noise)
Questions
Appendices
Appendix 1 Glossary of acoustical terms
Appendix 2 List of formulae
Appendix 3 Suggested list of experiments, tests and observations
Appendix 4 Some electrical principles
Answers
Bibliography
Index