Pages that link to "Q73551509"
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The following pages link to Human middle-ear sound transfer function and cochlear input impedance (Q73551509):
Displaying 50 items.
- Auditory capacities in Middle Pleistocene humans from the Sierra de Atapuerca in Spain (Q24564407) (← links)
- Mass and Stiffness Impact on the Middle Ear and the Cochlear Partition (Q26799555) (← links)
- Békésy's contributions to our present understanding of sound conduction to the inner ear. (Q26829393) (← links)
- Early hominin auditory capacities (Q27340328) (← links)
- Evolution of the auditory ossicles in extant hominids: metric variation in African apes and humans (Q28655303) (← links)
- Early hominin auditory ossicles from South Africa (Q28682596) (← links)
- Predictions of middle-ear and passive cochlear mechanics using a finite element model of the pediatric ear. (Q30359769) (← links)
- Identifying Mechanisms Behind the Tullio Phenomenon: a Computational Study Based on First Principles (Q30359797) (← links)
- A Loudness Model for Time-Varying Sounds Incorporating Binaural Inhibition. (Q30362006) (← links)
- Feasibility study of transfer function model on electrocardiogram change caused by acupuncture (Q30363362) (← links)
- Temporal-Bone Measurements of the Maximum Equivalent Pressure Output and Maximum Stable Gain of a Light-Driven Hearing System That Mechanically Stimulates the Umbo (Q30364704) (← links)
- Human middle-ear model with compound eardrum and airway branching in mastoid air cells. (Q30384656) (← links)
- Analysis of the mechano-acoustic influence of the tympanic cavity in the auditory system. (Q30386929) (← links)
- The importance of the hook region of the cochlea for bone-conduction hearing (Q30407685) (← links)
- Comparisons of electromagnetic and piezoelectric floating-mass transducers in human cadaveric temporal bones (Q30421190) (← links)
- Superior-semicircular-canal dehiscence: effects of location, shape, and size on sound conduction (Q30422399) (← links)
- Development and current status of the "Cambridge" loudness models (Q30425390) (← links)
- An analysis of the acoustic input impedance of the ear (Q30429720) (← links)
- A three-dimensional finite-element model of a human dry skull for bone-conduction hearing (Q30430516) (← links)
- A prediction of the minke whale (Balaenoptera acutorostrata) middle-ear transfer function (Q30433166) (← links)
- Sound transmission along the ossicular chain in common wild-type laboratory mice (Q30435668) (← links)
- Comparison of forward (ear-canal) and reverse (round-window) sound stimulation of the cochlea (Q30435671) (← links)
- A three-dimensional finite element model of round window membrane vibration before and after stapedotomy surgery. (Q30446920) (← links)
- Reverse transmission along the ossicular chain in gerbil (Q30451526) (← links)
- Ear-Canal Reflectance, Umbo Velocity, and Tympanometry in Normal-Hearing Adults (Q30459503) (← links)
- Reply to “On Cochlear Impedances and the Miscomputation of Power Gain” by Shera et al. J. Assoc. Re. Otolaryngol (Q30460321) (← links)
- Inertial Bone Conduction: Symmetric and Anti-Symmetric Components (Q30467092) (← links)
- Feed-Forward and Feed-Backward Amplification Model from Cochlear Cytoarchitecture: An Interspecies Comparison (Q30471595) (← links)
- The Floating Mass Transducer on the Round Window Versus Attachment to an Ossicular Replacement Prosthesis (Q30471841) (← links)
- Otoacoustic emissions from residual oscillations of the cochlear basilar membrane in a human ear model (Q30473437) (← links)
- Performance considerations of prosthetic actuators for round-window stimulation (Q30475635) (← links)
- Middle ear function and cochlear input impedance in chinchilla (Q30476663) (← links)
- Finite element modeling of sound transmission with perforations of tympanic membrane (Q30480756) (← links)
- Ossicular resonance modes of the human middle ear for bone and air conduction (Q30482089) (← links)
- Differential intracochlear sound pressure measurements in normal human temporal bones (Q30482954) (← links)
- Simultaneous measurements of ossicular velocity and intracochlear pressure leading to the cochlear input impedance in gerbil (Q30489359) (← links)
- Basic auditory processes involved in the analysis of speech sounds (Q30490751) (← links)
- Effects of low-frequency biasing on spontaneous otoacoustic emissions: amplitude modulation (Q30491406) (← links)
- Testing a method for quantifying the output of implantable middle ear hearing devices (Q30492255) (← links)
- Similarity of traveling-wave delays in the hearing organs of humans and other tetrapods (Q30492484) (← links)
- Middle-ear transmission in humans: wide-band, not frequency-tuned? (Q30498873) (← links)
- Development of wide-band middle ear transmission in the Mongolian gerbil (Q30498881) (← links)
- Diagnostic utility of laser-Doppler vibrometry in conductive hearing loss with normal tympanic membrane (Q30500079) (← links)
- Basilar membrane and osseous spiral lamina motion in human cadavers with air and bone conduction stimuli (Q30961446) (← links)
- A normative study of tympanic membrane motion in humans using a laser Doppler vibrometer (LDV). (Q33196285) (← links)
- Effect of cochlear implant electrode insertion on middle-ear function as measured by intra-operative laser Doppler vibrometry (Q33399299) (← links)
- First results of a novel adjustable-length ossicular reconstruction prosthesis in temporal bones (Q35955523) (← links)
- Finite-Element Modelling of the Acoustic Input Admittance of the Newborn Ear Canal and Middle Ear. (Q36158227) (← links)
- Stapes displacement and intracochlear pressure in response to very high level, low frequency sounds (Q36277896) (← links)
- Attenuating the ear canal feedback pressure of a laser-driven hearing aid. (Q36332930) (← links)