LOUD SPEAKER SOUND PRESSURE MEASUREMENTS

When agricultural machines are operated on pavements, the vibration and noise caused by the interaction between the tire lugs and the road surface are inevitable. In conventional studies, it is considered that the dynamic behavior of a rolling agricultural tire is influenced by the vibration characteristics of the tire. Resonance occurs when the lug excitation frequency of the tire, which is defined as the lug number multiplied by the number of revolutions of the tire, becomes equal to the natural frequency of the tire. In other words, the rolling tire shows large vibrations in the direction of the natural mode corresponding to the natural frequency of the tire. However, the vibration mode of the rolling tire in resonance state has not yet been clarified. In this study, it is confirmed that the dynamic behavior of the rolling tire can be evaluated by performing sound pressure measurements using closely located microphones to the tire. Further, the vibration mode in the resonance state is identified by performing simultaneous measurements of the sound pressure, and the vibration mode corresponds to the natural mode of the tire is confirmed as well.

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Delay-tuned combination-sensitive neurons in the auditory cortex of the vocalizing mustached bat

Journal of Neurophysiology ◽

10.1152/jn.1988.59.2.623 ◽

1988 ◽

Vol 59 (2) ◽

pp. 623-635 ◽

Cited By ~ 36

Author(s):

M. Kawasaki ◽

D. Margoliash ◽

N. Suga

Keyword(s):

Auditory Cortex ◽

Sound Pressure ◽

Pressure Level ◽

Target Range ◽

Mustached Bat ◽

Equivalent Effect ◽

Loud Speaker ◽

Cochlear Microphonic Potentials ◽

Self Stimulation ◽

Delay Tuning

1. FM-FM neurons in the auditory cortex of the mustached bat are sensitive to a pair of frequency-modulated (FM) sounds that simulates an FM component of the orientation sound and an FM component of the echo. These neurons are tuned to particular delays between the two FM components, suggesting an encoding of target range information. The response properties of these FM-FM neurons, however, have previously been studied only with synthesized orientation sounds and echoes delivered from a loud-speaker as substitutes for the bat's own orientation sounds and corresponding echoes. In this study, the combination sensitivity and delay tuning of FM-FM neurons were examined while the bat was actively vocalizing. 2. When the bat produced orientation sounds in an anechoic environment, or synthesized single FM echoes were delivered to a silent bat, the FM-FM neurons showed weak or no response. In contrast, when synthesized FM echoes were delivered with a particular delay from the FM component of the vocalized orientation sounds, the FM-FM neurons exhibited strong facilitative responses. 3. In both the vocalizing bats and the silent bats with substituted synthesized orientation sounds, all FM-FM neurons tested responded preferentially to the same echo harmonic (FM2, FM3, or FM4). 4. In vocalizing bats, FM-FM neurons showed maximum response to an echo FM component delivered with a particular delay (best delay) from an FM component in the orientation sound. Best delays measured with vocalized orientation sounds were nearly the same as those measured with synthesized orientation sounds. 5. The equivalent effect of a vocalized orientation sound and a synthesized FM1 component on the activity of FM-FM neurons indicates that, during echolocation, the FM1 component in the vocalized orientation sound stimulates the auditory system and conditions the FM-FM neurons to be sensitive to echoes with particular delays from the vocalized orientation sounds. 6. The amount of vocal self-stimulation to the inner ear by the bat's own vocalized sounds was measured by recording cochlear microphonic potentials (CMs). Spectral analysis of CM indicated that the amount of vocal self-stimulation by each harmonic of an orientation sound was equivalent to a sound of 70 dB sound pressure level (SPL) for the first harmonic (H1), 91 dB SPL for H2, 83 dB SPL for H3, and 70 dB SPL for H4, when the amplitude of the vocalized sound was 117 dB SPL at 5 cm in front of the bat's mouth.

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A study of brake disc modal behaviour during squeal generation using high-speed electronic speckle pattern interferometry and near-field sound pressure measurements

Proceedings of the Institution of Mechanical Engineers Part D Journal of Automobile Engineering ◽

10.1243/0954407001527420 ◽

2000 ◽

Vol 214 (3) ◽

pp. 285-296 ◽

Cited By ~ 15

Author(s):

M Reeves ◽

N Taylor ◽

C Edwards ◽

D Williams ◽

C. H. Buckberry

Keyword(s):

High Speed ◽

Sound Pressure ◽

Surface Deformation ◽

Speckle Pattern ◽

Near Field ◽

Electronic Speckle Pattern Interferometry ◽

Brake Disc ◽

Pressure Measurements ◽

Near Field Sound ◽

Field Sound

The out-of-plane surface vibration of a brake disc during naturally excited squeal has been investigated using a combination of high-speed electronic speckle pattern interferometry (ESPI) and near-field sound pressure measurements. Both techniques provide visualization and quantification of the time-resolved surface velocity. A mathematical description of disc brake squeal modal behaviour is proposed that predicts accurately all of the experimentally observed interferometry and sound field measurements. The complex mode description proposed here is in agreement with that proposed by others for drum brake squeal. This assumes that two identical diametral modes are excited simultaneously, identical except for a spatial and temporal phase shift. The use of a near-field microphone array provided a convenient multipoint, non-contacting vibration probe which may find use in the study of other vibrations characterized by high surface amplitudes and efficient sound radiation. The high-speed ESPI provided a real-time visualization of surface deformation analogous to double- pulsed holographic interferometry, with the benefit of giving a true time series of the surface deformation during a single vibration cycle.

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Estimation of the area function of human ear canals by sound pressure measurements

The Journal of the Acoustical Society of America ◽

10.1121/1.388857 ◽

1983 ◽

Vol 73 (1) ◽

pp. 24-31 ◽

Cited By ~ 18

Author(s):

Herbert Hudde

Keyword(s):

Sound Pressure ◽

Pressure Measurements ◽

Area Function ◽

Ear Canals ◽

Human Ear

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Characterization and Design of a Non Ported Conventional Speaker for Acoustic Control

Noise Control and Acoustics ◽

10.1115/imece2005-82116 ◽

2005 ◽

Author(s):

Taehyun Shim

Keyword(s):

Sound Pressure ◽

Active Noise Control ◽

Nonlinear Effects ◽

Measured Data ◽

Pressure Level ◽

Design Procedures ◽

Active Noise ◽

Acoustic Control ◽

Parameter Variations ◽

Loud Speaker

A loud speaker has been widely used as a major actuator in the field of active noise control (ANC). In this paper, the design procedures for a non-ported conventional speaker that must meet restrictive size constraint as well as required sound pressure level at a targeted frequency for an acoustic control was presented. Dynamic model of a speaker that includes linear and nonlinear effects such as radiation resistance on speaker damping, voice coil electrical resistance has been developed and its responses were compared to measured data. The effects of speaker design parameter variations on a sound pressure and power consumption were also assessed experimentally and through simulation. It was found that the simulation results are well collated with experimental data and the desired objective has been met.

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Differential Intracochlear Sound Pressure Measurements in Human Temporal Bones with an Off-the-Shelf Sensor

BioMed Research International ◽

10.1155/2016/6059479 ◽

2016 ◽

Vol 2016 ◽

pp. 1-10 ◽

Cited By ~ 6

Author(s):

Martin Grossöhmichen ◽

Rolf Salcher ◽

Klaus Püschel ◽

Thomas Lenarz ◽

Hannes Maier

Keyword(s):

Mechanical Stimulation ◽

Pressure Sensor ◽

Sound Pressure ◽

Ossicular Chain ◽

Acoustic Stimulation ◽

Pressure Measurements ◽

Output Level ◽

Custom Made ◽

Temporal Bones

The standard method to determine the output level of acoustic and mechanical stimulation to the inner ear is measurement of vibration response of the stapes in human cadaveric temporal bones (TBs) by laser Doppler vibrometry. However, this method is reliable only if the intact ossicular chain is stimulated. For other stimulation modes an alternative method is needed. The differential intracochlear sound pressure between scala vestibuli (SV) and scala tympani (ST) is assumed to correlate with excitation. Using a custom-made pressure sensor it has been successfully measured and used to determine the output level of acoustic and mechanical stimulation. To make this method generally accessible, an off-the-shelf pressure sensor (Samba Preclin 420 LP, Samba Sensors) was tested here for intracochlear sound pressure measurements. During acoustic stimulation, intracochlear sound pressures were simultaneously measurable in SV and ST between 0.1 and 8 kHz with sufficient signal-to-noise ratios with this sensor. The pressure differences were comparable to results obtained with custom-made sensors. Our results demonstrated that the pressure sensor Samba Preclin 420 LP is usable for measurements of intracochlear sound pressures in SV and ST and for the determination of differential intracochlear sound pressures.

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