Introduction to Auditory Simulation Methods Applicable to NIHL Study June 22, 2009 Won Joon Song and Jay Kim Mechanical Engineering Department University.

Slides:

Advertisements

Similar presentations

ANATOMY AND PHYSIOLOGY OF THE EAR

Advertisements

Physiology of Hearing & Equilibrium

Revised estimates of human cochlear tuning from otoacoustic and behavioral measurements Christopher A. Shera, John J. Guinan, Jr., and Andrew J. Oxenham.

CSD 3103 anatomy of speech and hearing mechanisms Hearing mechanisms Fall 2008 The Middle Ear.

The external ear funnels sound waves to the external auditory meatus The external ear funnels sound waves to the external auditory meatus.tsound.

Psychoacoustics Riana Walsh Relevant texts Acoustics and Psychoacoustics, D. M. Howard and J. Angus, 2 nd edition, Focal Press 2001.

Purpose The aim of this project was to investigate receptive fields on a neural network to compare a computational model to the actual cortical-level auditory.

Human Hearing and Nature’s Applications

The peripheral auditory system David Meredith Aalborg University.

Physics of Sounds Overview Properties of vibrating systems Free and forced vibrations Resonance and frequency response Sound waves in air Frequency, wavelength,

Audition. Sound Any vibrating material which can be heard.

1 Human Research & Engineering Directorate Paul D. Fedele Joel T. Kalb U.S. Army Research Laboratory Human Research & Engineering Directorate U.S. Army.

Alessandro Altoè The Mechanics of Hearing. About today’s lecture Many methodological mistakes when dealing with hearing: Oversimplifications (engineers):

Development of Improved Noise Metrics and Auditory Risk Assessment Procedure June 22, 2009 Won Joon Song and Jay Kim Mechanical Engineering Department.

EE-2027 SaS 06-07, L11 1/12 Lecture 11: Fourier Transform Properties and Examples 3. Basis functions (3 lectures): Concept of basis function. Fourier series.

The fish inner ear Swim bladder Weberian ossicle.

Signal and Systems Introduction to Signals and Systems.

THE HUMAN EAR AND SIMPLE TESTS OF HEARING Ear Anatomy  Outer Ear  Auricle, external auditory canal and the tympanic membrane  Middle Ear  An air filled.

The Ear: Hearing and Balance

S 319 < Auditory system >

Nise/Control Systems Engineering, 3/e

Physics 1251 The Science and Technology of Musical Sound Unit 2 Session 12 MWF The Human Ear Unit 2 Session 12 MWF The Human Ear.

EE Audio Signals and Systems Kevin D. Donohue Electrical and Computer Engineering University of Kentucky.

Applied Psychoacoustics Lecture 1: Anatomy and Physiology of the human auditory system Jonas Braasch.

Chucri A. Kardous, M.S., P.E. William J. Murphy, Ph.D. U.S. Department of Health and Human Services Centers for Disease Control and Prevention National.

SENSE OF HEARING EAR. Ear Consists of 3 parts –External ear Consists of pinna, external auditory meatus, and tympanum Transmits airborne sound waves to.

Senior Design Fall 06 and Spring 07 Speech Strategy for the Cochlear Implant.

Methods Neural network Neural networks mimic biological processing by joining layers of artificial neurons in a meaningful way. The neural network employed.

Figure 1.1 Simplified description of a control system

Hearing Anatomy.

ANATOMY AND PHYSIOLOGY OF THE EAR

Chapter 5: Normal Hearing. Objectives (1) Define threshold and minimum auditory sensitivity The normal hearing range for humans Define minimum audible.

CHAPTER 6 Outer and Middle Ears.

IB Assessment Statements Option I-1, The Ear and Hearing: I.1.1.Describe the basic structure of the human ear. I.1.2.State and explain how sound pressure.

Figure 7 Measured equal loudness curves. 4 Modelling random changes in the parameters along the length of the cochlea and the effect on hearing sensitivity.

Peng Lei Beijing University of Aeronautics and Astronautics IGARSS 2011, Vancouver, Canada July 26, 2011 Radar Micro-Doppler Analysis and Rotation Parameter.

Gammachirp Auditory Filter

Anatomy and physiology of the ear. External ear Pinna (auricle) & External auditory meatus Pinna (auricle) & External auditory meatus Function: Localization.

AUDIOLOGY IN ORL DR. BANDAR MOHAMMED AL- QAHTANI, M.D KSMC.

52 The Sense of Hearing Dr. A.R. Jamshidi Fard 2011.

Aims To use the linear fractional transformations (LFT) modelling framework to reconstruct an existing state-space model of the cochlea in terms of a stable.

Physiology Middle ear space stiffness dominated: High- frequency emphasis.

Anatomy and Physiology of the Ear

Temporal bone. Left bone.

HUMAN EAR GSS 106. The Human Ear Quiz: A student guitarist plays a chord on his electric guitar. When he mutes the strings he notices that his acoustic.

대학원 생체신호처리 - 4 이상민.

The Ear Hearing and Balance. The Ear: Hearing and Balance The three parts of the ear are the inner, outer, and middle ear The outer and middle ear are.

Chapter 2 Modeling in the frequency domain

Force Vibration Response Spectrum

ANATOMY AND PHYSIOLOGY OF THE EAR Yard.Doc.Dr.Müzeyyen Doğan.

MESB374 System Modeling and Analysis

Sarah Robinson, Suzanne Thompson, Jont Allen

ANATOMY THE EAR Dr. J.K. GERALD, (MD, MSc.).

Physics of hearing.

ANATOMY AND PHYSIOLOGY OF THE EAR

Peripheral Auditory System

Radar Micro-Doppler Analysis and Rotation Parameter Estimation for Rigid Targets with Complicated Micro-Motions Peng Lei, Jun Wang, Jinping Sun Beijing.

Effect of asymmetrical organ of Corti mechanics on the onset-delay of the cochlea Wenxiao Zhou1, and Jong-Hoon Nam1, 2 1Department of Mechanical.

Structure and Function

Neurology of The Ear.

Hearing, not trying out for a play

Signals and Systems Networks and Communication Department Chapter (1)

Peripheral Auditory System

Modeling in the Time Domain

Mechanisms of air- and bone-conducted sound in healthy and third window anatomy. Mechanisms of air- and bone-conducted sound in healthy and third window.

Ossicular connections

ANATOMY AND PHYSIOLOGY OF THE EAR

1/17/19 Open your notes to page 18. I will be checking for a summary on this page(s) Also be ready to flip to pages 20 and 22. I will be checking for.

Presentation transcript:

Introduction to Auditory Simulation Methods Applicable to NIHL Study June 22, 2009 Won Joon Song and Jay Kim Mechanical Engineering Department University of Cincinnati

Contents Network model Transfer function model Applicability of simulation models to NIHL study

Auditory pathways in conventional network models External ear TM Ossicular chain Inner ear Mechanical transmission Acoustic transmission Bone conduction Generally replaced by cochlear input impedance B.C Modeled as independent block ME air space Skull

Schematic of network ear model

Classical middle ear network model Tympanic membrane & ossicular chain up to I-S joint Two-port network of conductive pathway Middle ear cavity Decoupled from mechanical pathway Stapes complex & cochlear input impedance Impedance B.C. for ME transmission Network sub-structures and parameter values are different, but three- impedance-block concept is common in typical network models.

Available outputs from network model Time-domain response: Steady state response: Inner Ear Middle Ear External Ear Source U ST (t)d BM (x, t)P TM (t) Z ME Z C0 H UP (ω) P C0 (t) HP (ω)HP (ω)H C (x, ω) ZEEZEE H FT (ω) P FF (t) H DP (ω) d ST (t)

Limitations of middle ear network models Complex vibrational mode of the tympanic membrane: single-piston or mechanically coupled two-piston modeling Rocking motion of the stapes footplate: translational motion only Variable middle ear transformer ratio –Moving axis of rotation –Flexible ossicular joints: rigid M-I joint assumed –Effective area change in TM and stapes footplate Nonlinear acoustic reflex characteristics –Time-frequency dependent –Threshold, adaptation, and saturation features Nonlinear mechanical properties of the annular ligament Highly complicated cochlear input impedance: over-simplified

Network model simulation example : Simulink version of AHAAH TM input pressure Stapes displacement Acoustic wave Nonlinear model block

Network model simulation example : Human cochlear model in AHAAH BM characteristic freq.-time BM location-time d ST (t) d ST (ω)d BM (x,ω)d BM (x,t) FFT IFFT H C (x,ω) Network model (Simulink) Cochlear model (Matlab) Cochlear model (Matlab)

Transfer function method : An alternative to network model Free from modeling artifacts Wider valid frequency range Responses only up to stapes Linear concept Inner Ear External Ear Source Middle Ear Replaced by measured TFs

Transfer function method : Stapes response calculation FFT TF from free-field sound pressure to stapes volume velocity Stapes response in frequency domain Stapes response in time domain IFFT

Available transfer functions Human H FT H UP ChinchillaGuinea pigCat Shaw, E. A. G. (1974)** Mehrgardt & Mellert (1977) Bismarck & Pfeiffer (1967)* Murphy & Davis (1998) Sinyor & Laszlo (1973)** Wiener et al. (1965)** Ruggero et al. (1990) Guinan & Peake (1967) Nuttall (1974) Kringlebotn & Gundersen (1985) * Azimuth: 0° ** Phase data not available

Currently available data : Magnitude of H FT Chinchilla: Bismarck & Pfeiffer (1967) Chinchilla: Murphy & Davis (1998) Cat: Wiener et al. (1965) Guinea pig: Sinyor & Laszlo (1973) Human: Shaw (1974) Human: Mehrgardt & Mellert (1977)

Currently available data : Phase of H FT Chinchilla: Murphy & Davis (1998) Human: Mehrgardt & Mellert (1977)

Currently available data : Magnitude of H UP Chinchilla: Ruggero et al. (1990) Cat: Guinan & Peake (1967) Guinea pig: Nuttall (1974) Human: Kringlebotn & Gundersen (1985); Rosowski (1994) Human: Kringlebotn & Gundersen (1985); Rosowski (1991)

Currently available data : Phase of H UP Chinchilla: Ruggero et al. (1990) Cat: Guinan & Peake (1967) Guinea pig: Nuttall (1974) Human: Kringlebotn & Gundersen (1985); Rosowski (1994) Human: Kringlebotn & Gundersen (1985); Rosowski (1991)

Transfer function reconstruction Target –Spectral range up to 25 kHz –Species: human and chinchilla (due to insufficient data for guinea pig and cat) Within measured frequency range –Approximated by spline function passing through the measured data points Out of measured frequency range –Curve-fitting of measured data subset –Extrapolation of the fitted curve

Transfer function reconstruction example: H FT Human: Mehrgardt & Mellert (1977) Chinchilla: Murphy & Davis (1998) Gauss2 (0.96, f<1 kHz) Poly1 (0.91, f> 8 kHz) Sin4 (0.97, f<1 kHz) Fourier6 (0.92, f>15 kHz)

Transfer function reconstruction example: H UP Human: Kringlebotn & Gundersen (1985); Rosowski (1994) Chinchilla: Ruggero et al. (1990) Poly7 (0.99, f<1 kHz) Exp2 (0.99, f>1 kHz) Poly5 (0.99, f<1 kHz) Power2 (0.84, f>1 kHz)

Reconstructed transfer function Chinchilla Human

TF model simulation example :Stapes response to complex noise Human Chinchilla Complex (G-44)

TF model simulation example :Stapes response to impulsive noise Human Chinchilla Test impulse ±20 μm

Velocity-based metric Displacement-based metric Application to NIHL study : Auditory response metric Network / TF model EARM curve NIHL study EARM curve NIHL study

Questions?