EDP Sciences logo
Submit your paper
Search
Menu
All issues Volume 9 (2025) Acta Acust., 9 (2025) 55 References
Issue
Acta Acust.
Volume 9, 2025
Topical Issue - Development of European Acoustics in 20th Century
Article Number 55
Number of page(s) 20
DOI https://doi.org/10.1051/aacus/2025042
Published online 09 September 2025
  1. S.J. Elliott: The Institute of Sound and Vibration Research at the University of Southampton, in Forum Acusticum, Turin, Italy, 11–15 September, 2023. [Google Scholar]
  2. ISVR Annual Reports, University of Southampton. Available at https://viewer.soton.ac.uk/collections/isvr-annual-reports (accessed 19-05-2025). [Google Scholar]
  3. A. Ichino: Sorting into tertiary education: lessons from the UK, European University Institute, 2020. Available at https://www.eui.eu/research-hub?id=sorting-into-tertiary-education-lessons-from-the-uk (accessed 30-09-2024). [Google Scholar]
  4. B.V. Bowden: Britain’s backwardness in higher education. New Scientist 10, 216 (1961) 22–25. [Google Scholar]
  5. B.L. Clarkson: The Institute of Sound and Vibration Research: the first ten years. Journal of Sound Vibration 28 (1973) 307–311. [Google Scholar]
  6. E.J. Richards, D.J. Mead (Eds.): Noise and acoustic fatigue in aeronautics. John Wiley and Sons, London, 1968. [Google Scholar]
  7. https://www.legislation.gov.uk/ukpga/1960/68/contents/enacted (accessed 01-01-2025). [Google Scholar]
  8. A. Wilson: Noise – final report of the committee on the problem of noise, Cmnd 2056, HMSO, London, 1963. [Google Scholar]
  9. F.J. Fahy: Study in excellence: a brief history of the Institute of Sound and Vibration Research. Acoustics Bulletin Jan–Feb (2014) 27–32. [Google Scholar]
  10. S.G. Hooker: Not much of an engineer: an autobiography. Airlife Publishing Ltd, Shrewsbury, UK, 1984. [Google Scholar]
  11. P.E. Doak: Fundamentals of aerodynamic sound theory and flow duct acoustics. Journal of Sound Vibration 28 (1973) 527–561. [Google Scholar]
  12. C.L. Morfey: Acoustic energy in non-uniform flows. Journal of Sound Vibration 14 (1971) 159–170. [Google Scholar]
  13. C.L. Morfey: Amplification of aerodynamic noise by convected flow inhomogeneities. Journal of Sound Vibration 31 (1973) 391–397. [Google Scholar]
  14. C.L. Morfey, V.M. Szewczyk, B.J. Tester: New scaling laws for hot and cold jet mixing noise based on geometric acoustics model. Journal of Sound Vibration 61 (1978) 255–292. [Google Scholar]
  15. B.J. Tester, C.L. Morfey: Developments in jet noise modelling – theoretical predictions and comparisons with measured data. Journal of Sound Vibration 46 (1976) 79–103. [Google Scholar]
  16. P.E. Doak: Excitation, transmission and radiation of sound from source distributions in hard-walled ducts of finite length (I): The effects of duct cross-section geometry and source distribution space-time pattern. Journal of Sound Vibration 31 (1973) 1–72. [Google Scholar]
  17. C.L. Morfey: The acoustics of axial flow machines. Journal of Sound Vibration 22 (1972) 445–466. [Google Scholar]
  18. M.J. Fisher, P.O.A.L. Davies: Correlation measurements in a non-frozen pattern of turbulence. Journal of Fluid Mechanics 18 (1964) 97–116. [Google Scholar]
  19. P.O.A.L. Davies, M.J. Fisher: Heat transfer from electrically heated cylinders. Proceedings of the Royal Society A 280 (1964) 486. [Google Scholar]
  20. M.K. Davis, P.O.A.L. Davies: Factors influencing heat transfer from cylindrical anemometer probes. International Journal of Heat and Mass Transfer 15 (1972) 1659–1677. [Google Scholar]
  21. M.J. Fisher, M. Harper Bourne, S. Glegg: Jet noise source location: the polar correlation technique. Journal of Sound Vibration 51 (1977) 23–54. [Google Scholar]
  22. P.O.A.L. Davies: Flow acoustic coupling in ducts. Journal of Sound Vibration 77 (1981) 191–209. [Google Scholar]
  23. C.L. Morfey, G.P. Howell: Nonlinear propagation of aircraft noise in the atmosphere. AIAA Journal 19 (1981) 986–992. [Google Scholar]
  24. P.A. Nelson, N.A. Halliwell, P.E. Doak: Fluid dynamics of a flow excited resonance. Part I: experiment. Journal of Sound Vibration 78 (1981) 15–38. [Google Scholar]
  25. M.J. Fisher, G.A. Preston, W.D. Bryce: A modelling of the noise from simple coaxial jets, Part I: with unheated primary flow. Journal of Sound Vibration 209 (1998) 385–403. [Google Scholar]
  26. Z. Hu, C.L. Morfey, N.D. Sandham: Sound radiation in turbulent channel flows. Journal of Fluid Mechanics 475 (2003) 269–302. [Google Scholar]
  27. R.D. Sandberg, N.D. Sandham, P.F. Joseph: Direct numerical simulations of trailing-edge noise generated by boundary-layer instabilities. Journal of Sound Vibration 304 (2007) 677–690. [Google Scholar]
  28. B.L. Clarkson: The Institute of Sound and Vibration Research, University of Southampton. Review of Physics in Technology, 2 (1971) 1–24. [Google Scholar]
  29. D. Anderton, E.C. Grover, N. Lalor, T. Priede: Assessment and control of combustion-induced noise in IC engines, in Combustion engine progress, Temple Press Limited, 1969 48–53. [Google Scholar]
  30. T. Priede, E.C. Grover, N. Lalor: Assessment and control of combustion-induced noise in I.C. engines, Relation between noise and basic structural vibration of diesel engines. Society of Automotive Engineers, SAE Paper 690450, 1969. [Google Scholar]
  31. T. Priede: Noise of diesel engine injection equipment. Journal of Sound Vibration 6 (1967) 443–459. [Google Scholar]
  32. S.K. Jha: Characteristics and sources of noise and vibration and their control in motor cars. Journal of Sound Vibration 47 (1976) 543–558. [Google Scholar]
  33. P.E. Waters: Control of road noise by vehicle operation. Journal of Sound Vibration 13 (1970) 445–453. [Google Scholar]
  34. P.O.A.L. Davies, K.R. Holland: IC engine intake and exhaust noise assessment. Journal of Sound Vibration 223 (1999) 425–444. [Google Scholar]
  35. J.A. Raff, R.D.H. Perry: A review of vehicle noise studies carried out at the Institute of Sound and Vibration Research with a reference to some recent research on petrol engine noise. Journal of Sound Vibration 28 (1973) 433–470. [Google Scholar]
  36. E.C. Grover, N. Lalor: A review of low noise diesel engine design. Journal of Sound Vibration 28 (1973) 403–431. [Google Scholar]
  37. J.D. Dixon, A.V. Philips: In-vehicle engine noise simulation, in IMechE Conf Autotech, 1989. [Google Scholar]
  38. J. Dixon, J.M. Baker, B. Challen: A hybrid method for modelling engine noise, in IMechE Conf C577/036, 2000. [Google Scholar]
  39. B.L. Clarkson, D.J. Mead: High frequency vibration of aircraft structures. Journal of Sound Vibration 28 (1973) 487–504. [Google Scholar]
  40. Engineering Sciences Data Unit Design Guide Series: Vibration and Acoustic Fatigue, Vols 1–7, Augst 2001, Supplement level 48, ESDU International, London. [Google Scholar]
  41. R.G. White: A comparison of some statistical properties of the response of aluminium alloy and CFRP plates to acoustic excitation. Composites 9 (1978) 251–258. [Google Scholar]
  42. R.G. White: Developments in the acoustic fatigue design process for composite aircraft structures. Composite Structures 16 (1990) 171–192. [Google Scholar]
  43. R.G. White: Some measurements of the dynamic properties of mixed, carbon reinforced plastic beams and plates. The Aeronautical Journal of the Royal Aeronautical Society 79 (1975) 318–325. [Google Scholar]
  44. T.A. Willway, R.G. White: The effects of matrix complex moduli on the dynamic properties of CFRP laminae. Composites Science and Technology 36 (1989) 77–94. [Google Scholar]
  45. T.A. Willway, R.G. White: Optimisation of CFRP laminae dynamic properties using combinations of short/continuous fibres and stiff/flexible resin matrices. Composites 19 (1988) 205–210. [Google Scholar]
  46. P.R. Cunningham, R.G. White: Dynamic response of doubly curved honeycomb sandwich panels to random acoustic excitation. Part 1: experimental study. Journal of Sound Vibration 264 (2003) 579–603. [Google Scholar]
  47. P.R. Cunningham, R.S. Langley, R.G. White: Dynamic response of doubly curved honeycomb sandwich panels to random acoustic excitation. Part 2: theoretical study. Journal of Sound Vibration 264 (2003) 605–637. [Google Scholar]
  48. J.M.M. Hernandez (Ed.): Advances in acoustics technology (European Commission Aeronautics Research Series). John Wiley and Sons, 1995. [Google Scholar]
  49. P. Ribeiro, M. Petyt: Nonlinear vibration of plates by the hierarchical finite element and continuation methods. International Journal of Mechanical Sciences 41 (1999) 437–459. [Google Scholar]
  50. M. Petyt: Introduction to finite element vibration analysis. Cambridge University Press, Cambridge, 1990. [Google Scholar]
  51. D.J. Mead: Passive vibration control. John Wiley and Sons, 1998. [Google Scholar]
  52. R.G. White, R.J. Pinnington: Practical application of the rapid frequency sweep technique for structural frequency response measurement. The Aeronautical Journal of the Royal Aeronautical Society 86 (1982) 179–199. [Google Scholar]
  53. H.G.D. Goyder, R.G. White: Vibrational power flow from machines into built-up structures, I: introduction and approximate analysis of beam and plate-like foundations. Journal of Sound Vibration 68 (1980) 59–75. [Google Scholar]
  54. R.J. Pinnington, R.G. White: Power flow through machine isolators to resonant and non-resonant beams. Journal of Sound Vibration 75 (1981) 179–197. [Google Scholar]
  55. J.L. Horner, R.G. White: Prediction of vibrational power transmission through bends and joints in beam-like structures. Journal of Sound Vibration 147 (1991) 87–103. [Google Scholar]
  56. J.L. Horner, R.G. White: Vibrational power transmission through discontinuities, in International Conference on Recent Advances in Structural Dynamics, Southampton, UK, 1988. [Google Scholar]
  57. J.M. Muggleton, M.J. Brennan, R.J. Pinnington: Wavenumber prediction of waves in buried pipes for water leak detection. Journal of Sound Vibration 249 (2003) 939–954. [Google Scholar]
  58. R.J. Pinnington, A.R. Briscoe: A wave model for a pneumatic tyre belt. Journal of Sound Vibration 253 (2002) 941–959. [Google Scholar]
  59. L.C. Chow, R.J. Pinnington: Practical industrial method of increasing structural damping in machinery, I: Squeeze-film damping with air. Journal of Sound Vibration 118 (1987) 123–139. [Google Scholar]
  60. L.C. Chow, R.J. Pinnington: Practical industrial method of increasing structural damping in machinery, II: Squeeze-film damping with liquids. Journal of Sound Vibration 128 (1989) 333–347. [Google Scholar]
  61. M.J. Brennan: Vibration control using a tunable vibration neutralizer. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science 211 (1997) 91–107. [Google Scholar]
  62. F.J. Fahy: Measurement of acoustic intensity using the cross-spectral density of two microphone signals. Journal of the Acoustical Society of America 62 (1977) 1057–1059. [Google Scholar]
  63. F.J. Fahy: Sound intensity, 2nd edn. E and FN Spon, London, 1995. [Google Scholar]
  64. ISO 9614-1: Acoustics – determination of sound power levels of noise sources using sound intensity. International Organization for Standardization, Geneva, 1993. [Google Scholar]
  65. F.J. Fahy: Sound and structural vibration, Academic Press, Oxford, 1985. [Google Scholar]
  66. F.J. Fahy: The vibro-acoustic reciprocity principle and applications to noise control. Acustica 81 (1995) 544–558. [Google Scholar]
  67. J.M. Mason, F.J. Fahy: Development of a reciprocity technique for the prediction of propeller noise transmission through aircraft fuselages. Noise Control Engineering Journal 34 (1990) 43–52. [Google Scholar]
  68. J. Zheng, F.J. Fahy, D. Anderton: Application of a vibro-acoustic reciprocity technique to the prediction of sound radiated by a motored IC engine. Applied Acoustics 42 (1994) 333–346. [Google Scholar]
  69. F.J. Fahy: Statistical energy analysis: a critical overview. Philosophical Transactions of the Royal Society A 346 (1994) 431–447. [Google Scholar]
  70. F.J. Fahy, H.M. Ruivo: Determination of statistical energy analysis loss factors by means of an input power modulation technique. Journal of Sound Vibration 203 (1997) 763–779. [Google Scholar]
  71. R.S. Langley, J.R.D. Smith, F.J. Fahy: Statistical energy analysis of periodically stiffened damped plate structures. Journal of Sound Vibration 208 (1997) 407–426. [Google Scholar]
  72. N.A. Halliwell, J.E. Rizzo: Multi-component frequency shifting self-aligning laser velocimeters. Review of Scientific Instruments 49 (1978) 1180–1185. [Google Scholar]
  73. N.A. Halliwell: Laser-Doppler measurement of vibrating surfaces: a portable instrument. Journal of Sound Vibration 62 (1979) 312–315. [Google Scholar]
  74. C.J.D. Pickering, N.A. Halliwell: Speckle photography in fluid flows: signal recovery with two-step processing. Applied Optics 23 (1984) 1128–1129. [Google Scholar]
  75. E.J. Richards, M.E. Westcott, R.K. Jeyapalan: On the prediction of impact noise: Part I: acceleration noise. Journal of Sound Vibration 62 (1979) 547–575. [Google Scholar]
  76. E.J. Richards: On the prediction of impact noise: Part III: energy accountancy in industrial machines. Journal of Sound Vibration 76 (1981) 187–232. [Google Scholar]
  77. R.R.A. Coles, G.R. Garinther, D.C. Hodge, C.G. Rice: Hazardous exposure to impulse noise. Journal of the Acoustical Society of America 43 (1968) 336–346. [Google Scholar]
  78. Effects of Impulse Noise: NATO report on study group 6 document AC/243 (Panel 8/RSG6) D/9, 1987. [Google Scholar]
  79. C.G. Rice, G.M. Lilley: Report on Conference on Sonic Boom, Part 4. Response of humans and animals, OECD, 1969. [Google Scholar]
  80. OECD: Highlights of the Conference on Sonic Boom Research, Note by the Secretariat, ENV (71) 14, OECD, Paris, 1971. [Google Scholar]
  81. J.B. Large, J.E. Ludlow: Community reaction to noise from a construction site, Noise Control Engineering, 6, 2 (1976) 59–65. [Google Scholar]
  82. Commission of the European Communities: Workshop on the Effects of Noise, CEC Report D11992-0157-8, Part A 3-35 Impulsive noise – annoyance effects, 1991. [Google Scholar]
  83. C.G. Rice: Human response effects of impulse noise. Journal of Sound Vibration 190 (1996) 525–543. [Google Scholar]
  84. E.E. Zepler, B.M. Sullivan, C.G. Rice, M.J. Griffin, M. Oldman, P.J. Dickenson, K.P. Shepherd, J.E. Ludlow, J.B. Large: Human response to transportation noise and vibration. Journal of Sound Vibration, 28 (1973) 375–401. [Google Scholar]
  85. J.M. Fields, J.G. Walker: Comparing the relationship between noise level and annoyance in different surveys: a railway noise vs. aircraft and road traffic comparison. Journal of Sound Vibration, 81 (1982) 51–80. [Google Scholar]
  86. I. Flindell, P. Le Masurier, H. Le Masurier: Resolving uncertainties in understanding community attitudes to aircraft noise. Applied Acoustics 178 (2021) 108032. [CrossRef] [Google Scholar]
  87. BS 5108: Method for measurement of attenuation of hearing protectors at threshold. British Standards Institution, London, 1974. [Google Scholar]
  88. ISO 4869-1: Acoustics – Hearing protectors. Part 1: Subjective method for the measurement of sound attenuation. International Organization for Standardization, Geneva, 2018. [Google Scholar]
  89. D.W. Robinson, B.W. Lawton, C.G. Rice: Occupational hearing loss from low level noise. Health and Safety Executive (HSE) Contract Research Report 68/1994, 1994. [Google Scholar]
  90. P. Wilkins, A.M. Martin: Hearing protection and warning sounds in industry – a review. Applied Acoustics 21 (1987) 267–293. [Google Scholar]
  91. M.E. Lutman, A.M. Martin: Development of anelectroacoustic analogue model of the middle ear and acoustic reflex. Journal of Sound Vibration 64 (1979) 133–157. [Google Scholar]
  92. A. Reid, R.J. Marchbanks, A.M. Martin: The relationship between intracranial pressure and tympanic membrane displacement. British Journal of Audiology 24 (1990) 123–129. [Google Scholar]
  93. M.E. Lutman, D.W. Robinson: Quantification of hearing disability for medico-legal purposes based on self-rating. British Journal of Audiology 26 (1992) 296–306. [Google Scholar]
  94. S. Kapadia, M.E. Lutman: Are normal hearing thresholds a sufficient condition for click-evoked otoacoustic emissions? Journal of the Acoustical Society of America 101 (1997) 3566–3576. [Google Scholar]
  95. M. Tait, M.E. Lutman: The predictive value of measures of pre-verbal communicative behaviours in young deaf children with cochlear implants. Ear and Hearing 18 (1997) 472–478. [Google Scholar]
  96. B. Rafaely, M. Rocassalva-Firenze, E. Payne: Feedback path variability modelling for robust hearing aids. Journal of the Acoustical Society of America 107 (2000) 2665–2673. [Google Scholar]
  97. K.J. Munro, D. Cafarelli Dees: Clinical record: An improvement in hearing sensitivity following hearing aid fitting in a child with an apparent sensorineural hearing impairment. Journal of Laryngology and Otology 110 (1996) 362–365. [Google Scholar]
  98. NICE: Cochlear implants for children and adults with severe to profound deafness, NICE Technology Appraisal Guidance 166, National Health Service National Institute for Health and Care Excellence,2009. [Google Scholar]
  99. A.Q. Summerfield, D.H. Marshall (Eds): Cochlear implantation in the UK 1990-1994, HMSO, 1995. [Google Scholar]
  100. B.S. Wilson, M.F. Dorman: Cochlear implants: a remarkable past and a brilliant future. Hearing Research 242 (2008) 3–21. [Google Scholar]
  101. J. Brinton: Measuring language development in deaf children with cochlear implants. International Journal of Language and Communication Disorders 36, supp1 (2001) 121–125. [Google Scholar]
  102. J. Brinton: Symbolic play as a predictor of language development following cochlear implantation: preliminary results. Cochlear Implants International 4, Supp1 (2003) 11–12. [Google Scholar]
  103. C.A. Verschuur: Effect of stimulation rate on speech perception in adult users of the Med-El combi 40+ and ineraid cochlear implants. Cochlear Implants International 4, Supp1 (2003) 15–16. [Google Scholar]
  104. C.A. Verschuur, M.E. Lutman: Auditory localization abilities in bilateral cochlear implant recipients using the nucleus 24 cochlear implant. Cochlear Implants International 4, Supp1 (2003) 13–14. [Google Scholar]
  105. S.J. Brockmeier, M. Grasmeder, S. Passow, D. Mawmann, M. Vischer, A. Jappel, W. Baumgartner, T. Stark, J. Müller, S. Brill, T. Steffens, J. Strutz, J. Keifer, U. Baumann, W. Arnold: Comparison of musical activities of cochlear implant users with different speech-coding strategies. Ear and Hearing 28, supp2 (2007)49S–51S. [Google Scholar]
  106. M.J. Griffin: Handbook of human vibration. Elsevier Science, 1996. [Google Scholar]
  107. M.J. Griffin, C.H. Lewis: A review of the effects of vibration on visual acuity and continuous manual control, Part I: visual acuity. Journal of Sound Vibration 56 (1978) 383–413. [Google Scholar]
  108. G.S. Paddan, M.J. Griffin: Effect of seating on exposures to whole-body vibration in vehicles. Journal of Sound Vibration 253 (2002) 215–241. [Google Scholar]
  109. M.J. Griffin: A comparison of standardized methods for predicting the hazards of whole-body vibration and repeated shocks. Journal of Sound Vibration 215 (1989) 883–914. [Google Scholar]
  110. ISO 7096: Earth-moving machinery – laboratory evaluation of operator seat vibration. International Organization for Standardization, Geneva, 2020. [Google Scholar]
  111. BS 6841: Guide to measurement and evaluation of human exposure to whole-body mechanical vibration and repeated shock. British Standards Institution, London, 1987. [Google Scholar]
  112. ISO 2631: Mechanical vibration and shock – evaluation of human exposure to whole-body vibration. International Organization for Standardization, Geneva, 1997. [Google Scholar]
  113. E.M. Whitham, M.J. Griffin: The effects of vibration frequency and direction on the location of areas of discomfort caused by whole-body vibration. Applied Ergonomics 9, 4 (1978) 231–239. [Google Scholar]
  114. N.J. Mansfield, M.J. Griffin: Nonlinearities in apparent mass and transmissibility during exposure to whole-body vertical vibration. Journal of Biomechanics 33 (2000) 933–941. [Google Scholar]
  115. T.E. Fairley, M.J. Griffin: The apparent mass of the seated human body: vertical vibration. Journal of Biomechanics 22 (1989) 81–94. [Google Scholar]
  116. G.S. Paddan, M.J. Griffin: The transmission of translational seat vibration to the head. 1. Vertical seat vibration. Journal of Biomechanics, 21 (1988) 191–197. [Google Scholar]
  117. C. Corbridge, M.J. Griffin: Effects of vertical vibration on passenger activities: writing and drinking. Ergonomics 34 (1991) 1313–1332. [Google Scholar]
  118. H. Howarth, M.J. Griffin: Subjective response to combined noise and vibration: summation and interaction effects. Journal of Sound Vibration 143 (1990) 443–454. [Google Scholar]
  119. L. Wei, M.J. Griffin: Mathematical models for the apparent mass of the seated human body exposed to vertical vibration. Journal of Sound Vibration 212 (1998) 855–874. [Google Scholar]
  120. S. Kitazaki, M.J. Griffin: A modal analysis of whole-body vertical vibration, using a finite element model of the human body. Journal of Sound Vibration 200 (1997) 83–103. [Google Scholar]
  121. C.H. Lewis, M.J. Griffin: Evaluating the vibration isolation of soft seat cushions using an active anthropodynamic dummy. Journal of Sound Vibration 253, 1 (2002) 295–211. [Google Scholar]
  122. N. Harada, M.J. Griffin: Factors influencing vibration sense thresholds used to assess occupational exposures to hand transmitted vibration. Occupational and Environmental Medicine 48, 3 (1991) 185–192. [Google Scholar]
  123. 2002/44/EC, Directive of the European Parliament and of the Council of 25 June 2002 on the minimum health and safety requirements regarding the exposure of workers to the risks arising from physical agents (vibration). Official Journal of the European Communities L 177, 13–19. [Google Scholar]
  124. Health and Safety Executive: The control of vibration at work regulations 2005, UK Statutory Instruments No. 1093, 2005. [Google Scholar]
  125. BS 6842: Guide to measurement and evaluation of human exposure to vibration transmitted to the hand. British Standards Institution, London, 1987. [Google Scholar]
  126. ISO 5349: Mechanical vibration – measurement and evaluation of human exposure to hand-transmitted vibration – part 1: general requirements. International Organization for Standardization, Geneva, 2001. [Google Scholar]
  127. ISO 10819: Mechanical vibration and shock – hand-arm vibration – measurement and evaluation of the vibration transmissibility of gloves at the palm of the hand. International Organization for Standardization, Geneva, 2013. [Google Scholar]
  128. A. Lawther, M.J. Griffin: A survey of the occurrence of motion sickness amongst passengers at sea. Aviation, Space, and Environmental Medicine 59, 5 (1988) 399–406. [Google Scholar]
  129. A. Lawther, M.J. Griffin: Prediction of the incidence of motion sickness from the magnitude, frequency, and duration of vertical oscillation. Journal of the Acoustical Society of America 82 (1987) 957–966. [Google Scholar]
  130. M. Turner, M.J. Griffin: Motion sickness in public road transport: the effect of driver, route and vehicle. Ergonomics 42 (1999) 1646–1664. [Google Scholar]
  131. B.E. Donohew, M.J. Griffin: Motion sickness with combined lateral and roll oscillation: effect of percentage compensation. Aviation, Space, and Environmental Medicine 81, 1 (2010) 22–29. [Google Scholar]
  132. N.A. Webb, M.J. Griffin: Eye movement, vection, and motion sickness with foveal and peripheral vision. Aviation, Space, and Environmental Medicine 74 (2003) 622–625. [Google Scholar]
  133. B.L. Clarkson: Preface (to special issue as tribute to PE Doak). Journal of Sound Vibration 239 (2001) 569–571. [Google Scholar]
  134. G. Dodd: Listener habits and choices – and their implications for public performance venues. Journal of Sound Vibration 239 (2001) 589–606. [Google Scholar]
  135. M. Barron: Auditorium acoustics and architectural design, 2 edn. Spon Press, London, 2010. [Google Scholar]
  136. A.H. Marshall, M. Barron: Spatial responsiveness in concert halls and the origins of spatial impression. Applied Acoustics 62 (2001) 91–108. [Google Scholar]
  137. https://www.turnersims.co.uk/about-turner-sims/our-history/ (accessed 09/05/2025). [Google Scholar]
  138. C.A. Mercer: Development of data analysis in sound and vibration. Journal of Sound Vibration 28 (1973) 631–642. [Google Scholar]
  139. K. Shin, J.K. Hammond: Fundamentals of signal processing for sound and vibration engineers. John Wiley and Sons, Chichester, 2008. [Google Scholar]
  140. R.F. Harrison, J.K. Hammond: Analysis of the nonstationary response of vehicles with multiple wheels. ASME J Dynamic Systems, Measurement and Control 108 (1986) 69–73. [Google Scholar]
  141. Y.H. Tsao, J.K. Hammond: Nonstationarity in acoustic fields. Journal of the Acoustical Society of America 74 (1983) 827–839. [Google Scholar]
  142. T.S. Leung, P.R. White, J. Cook, W.B. Collis, E. Brown, A.P. Salmon: Analysis of the second heart sound for diagnosis of paediatric heart disease. IEE Proceedings – Science, Measurement and Technology 145, 6 (1998) 285–290. [Google Scholar]
  143. P. Clarkson, P. White: Simplified analysis of the LMS adaptive filter using a transfer function approximation. IEEE Transactions on Acoustics, Speech, and Signal Processing 35, 7 (1987) 987–993. [Google Scholar]
  144. P. Davies, J.K. Hammond: A comparison of Fourier and parametric methods for structural system identification. Trans. ASME Journal of Vibration, Acoustics, Stress and Reliability in Design 106 (1984) 40–48. [Google Scholar]
  145. P.M. Clarkson, J. Mourjopoulos, J.K. Hammond: Spectral, phase and transient equalisations for audio systems. Journal of the Audio Engineering Society 33 (1985) 127–132. [Google Scholar]
  146. M. Boltear, J.K. Hammond: Experimental study of the vibrational behaviour of a coupled non-linear mechanical system. Mechanical Systems and Signal Processing 13 (1999) 375–394. [Google Scholar]
  147. K. Shin, J.K. Hammond: Psuedo force-state mapping method: Incorporation of the embedding and force-state mapping methods. Journal of Sound Vibration, 211 (1998) 918–922. [Google Scholar]
  148. M. Moshrefi-Torbati, J.K. Hammond: Physical and geometrical interpretation of fractional operators. Journal of the Franklin Institute 335, 6 (1998) 1077–1086. [Google Scholar]
  149. W.B. Collis, P.R. White, J.K. Hammond: Higher-order spectra: the bispectrum and trispectrum. Mechanical Systems and Signal Processing 12, 3 (1998) 375–394. [Google Scholar]
  150. A. Rivola, P.R. White: Bispectral analysis of the bilinear oscillator with application to the detection of fatigue cracks. Journal of Sound Vibration 216, 5 (1998) 889–910. [Google Scholar]
  151. C.J. James, C.W. Hesse: Independent component analysis for biomedical signals. Physiological Measurement, 26, 1 (2004) R15. [Google Scholar]
  152. P.A. Nelson, H. Hamada, S.J. Elliott: Adaptive inverse filters for stereophonic sound reproduction. IEEE Transactions on Signal Processing 40 (1992) 1621–1622. [Google Scholar]
  153. P.A. Nelson, S.H. Yoon: Estimation of acoustic source strength by inverse methods: Part I, conditioning of the inverse problem. Journal of Sound Vibration 233 (2000) 639–664. [Google Scholar]
  154. S.H. Yoon, P.A. Nelson: Estimation of acoustic source strength by inverse methods: Part II, experimental investigation of methods for choosing regularisation parameters. Journal of Sound Vibration 233 (2000) 665–701. [Google Scholar]
  155. P.D. Wheeler, R.D. Rawlinson, S.F. Pelc, A.P. Dorey: An active noise reduction system for aircrew helmets. Helicopter Acoustics, NASA Langley Research Center, Paper 29 (1978) 545–550. [Google Scholar]
  156. P.D. Wheeler, S.G. Halliday: An active noise reduction system for aircrew helmets – flight trials in strike aircraft. Proceedings of the Institute of Acoustics 3 (1981) 5–8. [Google Scholar]
  157. P.A. Nelson, A.R.D. Curtis, S.J. Elliott, A.J. Bullmore: The active minimisation of harmonic enclosed sound fields, part I: theory. Journal of Sound Vibration 117 (1987) 1–13. [Google Scholar]
  158. A.J. Bullmore, P.A. Nelson, A.R.D. Curtis, S.J. Elliott: The active minimisation of harmonic enclosed sound fields, part II: a computer simulation. Journal of Sound Vibration 117 (1987) 15–23. [Google Scholar]
  159. S.J. Elliott, A.R.D. Curtis, A.J. Bullmore, P.A. Nelson: The active minimisation of harmonic enclosed sound fields, part III: experimental verification. Journal of Sound Vibration 117 (1987) 35–58. [Google Scholar]
  160. S.J. Elliott, I. Stothers, P. Nelson: A multiple error LMS algorithm and its application to the active control of sound and vibration. IEEE Transactions ASSP-35 (1987) 1423–1434. [Google Scholar]
  161. S.J. Elliott, P.A. Nelson, I.M. Stothers, C.C. Boucher: Preliminary in-flight experiments on the active control of propeller-induced cabin noise. Journal of Sound Vibration 128 (1989) 355–357 [Google Scholar]
  162. C.M. Dorling, G.P. Eatwell, S.M. Hutchins, C.F. Ross, S.G.C. Sutcliffe: A demonstration of active noise reduction in an aircraft cabin. Journal of Sound Vibration 128 (1989) 358–360. [Google Scholar]
  163. Ultra-PCS: https://www.ultra-pcs.com/media/3534/pcs-active-noise-vibration-control-v2.pdf (accessed 01-01-2025), 2020. [Google Scholar]
  164. S.J. Elliott, I.M. Stothers, P.A. Nelson, D. Quinn, M. McDonald: The active control of engine-induced noise inside cars. Proceedings of Internoise 88 (1988) 987-990. [Google Scholar]
  165. D.C. Park: Vehicle sound and human response, in 10th International Styrian Noise and Vibration Congress, 2018. [Google Scholar]
  166. T.J. Sutton, S.J. Elliott, A.M. McDonald, T.J. Saunders: Active control of road noise inside vehicles. Noise Control Engineering Journal 42 (1994) 137-147. [Google Scholar]
  167. Hyundai: https://www.hyundai.news/uk/articles/press-releases/hmg-develops-worlds-first-road-noise-active-noise-control-technology.html (accessed 01-01-2025), 2019. [Google Scholar]
  168. B. Rafaely, S.J. Elliott, J. Garcia-Bonito: Broadband performance on an active headrest. Journal of the Acoustical Society of America 106 (1999) 787–793. [Google Scholar]
  169. P.A. Nelson, A.R.D. Curtis, S.J. Elliott, A.J. Bullmore: The minimum power output of free field point sources and the active control of sound. Journal of Sound Vibration 116 (1987) 397–414. [Google Scholar]
  170. S.J. Elliott, M.E. Johnson: Radiation modes and the active control of sound power. Journal of the Acoustical Society of America 94 (1993) 2194–2204. [Google Scholar]
  171. P. Gardonio, S.J. Elliott: Active control of structure-borne and airborne sound transmission through double panels. Journal of Aircraft 36 (1999) 1023–1032. [Google Scholar]
  172. B. Lam, W.S. Gan, D.Y. Shi, M. Nishimura, S. Elliott: Ten questions concerning active noise control in the built environment. Building and Environment 200 (2021) 107928. [CrossRef] [Google Scholar]
  173. T.J. Sutton, S.J. Elliott, M.J. Brennan, K.H. Heron, D.A.C. Jesop: Active isolation of multiple structural waves on a helicopter gearbox support strut. Journal of Sound Vibration, 205 (1997) 81–101. [Google Scholar]
  174. P. Gardonio, S.J. Elliott, R.J. Pinnington: Active isolation of structural vibration on a multiple-degree-of-freedom system, Part I: the dynamics of the system. Journal of Sound Vibration 207 (1997) 61–93. [Google Scholar]
  175. P. Gardonio, S.J. Elliott, R.J. Pinnington: Active isolation of structural vibration on a multiple-degree-of-freedom system, Part II: effectiveness of active control strategies. Journal of Sound Vibration 207 (1997) 95–121. [Google Scholar]
  176. M.J. Brennan: Control of flexural waves on a beam using a tunable vibration neutraliser. Journal of Sound Vibration 222 (1999) 389–407. [Google Scholar]
  177. P.A. Nelson, S.J. Elliott: Active control of sound. Academic Press, London, 1992. [Google Scholar]
  178. C.R. Fuller, S.J. Elliott, P.A. Nelson: Active control of vibration. Academic Press, London, 1996. [Google Scholar]
  179. S.J. Elliott: Signal processing for active control, Academic Press, London, 2000. [Google Scholar]
  180. D.M.F. Chapman: A simple estimate of propagation loss fluctuations due to modal interference. Journal of the Acoustical Society of America 85 (1989) 1097–1106. [Google Scholar]
  181. T.G. Leighton: The acoustic bubble. Academic Press, London, 1994. [Google Scholar]
  182. A.D. Phelps, D.G. Ramble, T.G. Leighton: The use of a combination frequency technique to measure the surf zone bubble population. Journal of the Acoustical Society of America 101 (1997) 1981–1989. [Google Scholar]
  183. T.G. Leighton, S.D. Meers, P.R. White: Propagation through nonlinear time-dependent bubble clouds and the estimation of bubble populations from measured acoustic characteristics. Proceedings of the Royal Society of London A, 460 (2004) 2521–2550. [Google Scholar]
  184. P. Joseph: Complex reflection phase gradient as an inversion parameter for the prediction of shallow water propagation and the characterization of sea-bottoms. Journal of the Acoustical Society of America 113 (2003) 758–768. [Google Scholar]
  185. T.G. Leighton, P.R. White, M.A. Marsden: The one-dimensional bubble: An unusual oscillator, with applications to human bioeffects of underwater sound. European Journal of Physics 16 (1995) 275–281. [Google Scholar]
  186. T.G. Leighton, B.T. Cox, A.D. Phelps: The Rayleigh-like collapse of a conical bubble. Journal of the Acoustical Society of America 107 (2000) 130–142. [Google Scholar]
  187. T.G. Leighton, M. Farhat, J.E. Field, F. Avellan : Cavitation luminescence from flow over a hydrofoil in a cavitation tunnel. Journal of Fluid Mechanics 480 (2003) 43–60. [Google Scholar]
  188. T.G. Leighton, D.G. Ramble, A.D. Phelps, C.L. Morfey, P.P. Harris: Acoustic detection of gas bubbles in a pipe. Acustica with Acta Acustica 84 (1998) 801–814. [Google Scholar]
  189. E.R. Hughes, T.G. Leighton, G.W. Petley, P.R. White: Ultrasonic propagation in cancellous bone: a new stratified model. Ultrasound in Medicine and Biology 25 (1999) 811–821. [Google Scholar]
  190. E.R. Hughes, G.W. Petley, T.G. Leighton, P.R. White: A stratified model for ultrasonic waves in bone. Osteoporosis Internatonal 11, supp3 (2000) S34. [Google Scholar]
  191. J.G. Walker: Proceedings of the Workshop on Railway and Tracked Transit System Noise, Derby, England, 30 March–1 April 1976, Foreword. Journal of Sound Vibration, 51 (1977) 317. [Google Scholar]
  192. D.J. Thompson: Wheel-rail noise: theoretical modelling of the generation of vibrations. PhD thesis, University of Southampton, 1990. [Google Scholar]
  193. D.J. Thompson, B. Hemsworth, N. Hemsworth: Experimental validation of the TWINS prediction program for rolling noise, part 1: description of the model and method. Journal of Sound Vibration, 193 (1996) 123–135. [Google Scholar]
  194. B. Hemsworth, P.E. Gautier, R. Jones: Silent freight and silent track projects, in Proceedings of Internoise 2000, Nice, France, 2000. [Google Scholar]
  195. D. Thompson: Railway noise and vibration – mechanisms, modelling and means of control, 2nd edn, Elsevier, London, 2024. [Google Scholar]
  196. C.J.C. Jones, D.J. Thompson: Extended validation of a theoretical model for railway rolling noise using novel wheel and track designs. Journal of Sound Vibration 267 (2003) 509–522. [Google Scholar]
  197. D.J. Thompson, C.J.C. Jones, T.P. Waters, D. Farrington: A tuned damping device for reducing noise from railway track. Applied Acoustics 68 (2007) 43–57. [Google Scholar]
  198. X. Sheng, C.J.C. Jones, D.J. Thompson: A theoretical model for ground vibration from trains generated by vertical track irregularities. Journal of Sound Vibration 272 (2004) 937–965. [Google Scholar]
  199. X. Sheng, C.J.C. Jones, D.J. Thompson: Modelling ground vibration from railways using wavenumber finite- and boundary-element methods. Proceedings of the Royal Society of London A 461 (2005) 2043–2070. [Google Scholar]
  200. P. Jean, C. Guigou, M. Villot: 2.5D BEM model of ground-structure interaction. Building Acoustics 11 (2004) 157–173. [Google Scholar]
  201. L. Auersch: Ground vibration due to railway traffic – the calculation of the effects of moving static loads and their experimental verification. Journal of Sound Vibration 293 (2006) 599–610. [Google Scholar]
  202. G. Lombaert, G. Degrande, J. Kogut, S. François: The experimental validation of a numerical model for the prediction of railway induced vibrations. Journal of Sound Vibration 297 (2006) 512–535. [Google Scholar]
  203. C.G. Gordon: The ISVR Wolfson Unit, Journal of Sound Vibration 28 (1973) 643–648. [Google Scholar]
  204. ESA: Structural acoustics design manual, ESA PSS-03-204, ESTEC, Noordwijk, The Netherlands, 1996. [Google Scholar]
  205. J.N. Pinder, F.J. Fahy: Method for assessing noise reduction provided by cylinders. Proceedings of the Institute of Acoustics 15, 3 (1993) 195–205. [Google Scholar]
  206. N.S. Ferguson, J.N. Pinder, F.J. Fahy, P. Gardonio: Noise transmission through payload fairings: an investigation of the sensitivity to point mass loading, in: W.R. Burke, Ed. ESA International Conference on Spacecraft Structures, Materials and Mechanical Engineering, Noordwijk, 27–29 March ESA SP-386, European Space Agency, Paris, 1996, pp. 227–235. [Google Scholar]
  207. N.S. Ferguson, J.N. Pinder, D.E.L. Tunbridge: Spacecraft vibrations due to mechanisms: measurements from Olympus on-station, in Proceedings of the Fifth European Space Mechanisms and Tribology Symposium, ESTEC, Noordwijk, The Netherlands, ESA SP-334, 1993, p. 221–227. [Google Scholar]
  208. M.G. Smith: Validation of an SEA model of the Olympus Satellite, in ESA International Confernce on Spacecraft Structures, Materials and Mechanical Testing, Noordwijk, ESA SP-386, 1996, pp. 723–730. [Google Scholar]
  209. M.G. Smith, L.C. Chow: Prediction method for aerodynamic noise from landing gears, AIAA paper 98-2228, 1998. [Google Scholar]
  210. M.C. Lower, R.D. Patterson, G.M. Rood, J. Edworthy, M.J. Shailer, R Milroy, J. Chillery, P.D. Wheeler: The design and production of auditory warnings for helicopters 1; The Sea King, Report No AC527A, ISVR Consultancy Services, Southampton, 1986. [Google Scholar]
  211. M.C. Lower, P.D. Wheeler: Specifying the sound levels for auditory warnings in noisy environments, in I.D. Brown, R. Goldsmith, Eds, Ergonomics International ‘85, Taylor and Francis, London, 1985, pp. 226–228. ISBN 0850663008. [Google Scholar]
  212. G.M. Rood, R.D. Patterson, M.C. Lower: Modelling of auditory masked thresholds in humans, in G.R. McMillan, Ed., Applications of human performance models to system design, Plenum Press, New York, 1988, pp. 151–168. [Google Scholar]
  213. R.D. Patterson, J. Edworthy, M.J. Shailer, M.C. Lower, P.D. Wheeler: Alarm sounds for medical equipment in intensive care areas and operating theatres, Report AC598 ISVR Consultancy Services, University of Southampton, 1986. [Google Scholar]
  214. M.C. Lower, R.D. Patterson, P. Cosgrove, R. Milroy: Sound levels for the British Rail Inductive Loop Warning System. Poceedings of the Institute of Acoustics 11, 5 (1989) 43–50. [Google Scholar]
  215. M.C. Lower: Headphones and the noise at work regulations. Health and Safety at Work April (1992) 33. [Google Scholar]
  216. https://www.legislation.gov.uk/uksi/1989/1790/made (accessed 02-01-2025). [Google Scholar]
  217. ISO 11904-2: Acoustics. Determination of sound immission from sound sources placed close to the ear. Part 2: Technique using a manikin. International Organization for Standardization, Geneva, 2021. [Google Scholar]
  218. M.C. Lower, M. Bagshaw: Noise levels and communications on the flight decks of civil aircraft. Proceedings of the Inter-noise 96 (1996) 349–352. [Google Scholar]
  219. M. Bagshaw, M.C. Lower: Hearing loss on the flight deck – origin and remedy. Aeronautical Journal 106 (2002) 277–289. [Google Scholar]
  220. R.A. Davis, M.C. Lower: Noise measurements in windy conditions, ETSU Report W/13/00386/REP Energy Technology Support Unit, 1996. [Google Scholar]
  221. M.C. Lower, D.W. Hurst, A.R. Claughton, A. Thomas: Sources and levels of noise under motorcyclists’ helmets. Proceedings of the Institute of Acoustics 16, 2 (1994) 319–326. [Google Scholar]
  222. M.C. Lower, D.W. Hurst, A. Thomas: Noise levels and noise reduction under motorcycle helmets, in Proceedings of the Inter-Noise 96, Liverpool, 30 July–2 August, Institute of Acoustics, 1996, pp. 979-982. [Google Scholar]
  223. CEN: prEN71-1:1996. Safety of toys – part 1 mechanical and physical properties CEN/TC 52/WG3 (Latest version: EN 71-1:2014+A1:2018). European Committee for Standardization, Brussels, Belgium, 1996. [Google Scholar]
  224. M.C. Lower, B.W. Lawton, M.E. Lutman, R.A. Davis: Noise from toys and its effect on hearing, Report 97/944. Department of Trade and Industry, London, 1997. [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.