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Abstract
The high acoustic sensitivity of the bottlenose dolphin is physically defined and
related to the anatomy of the middle ear. The paper presents a conceptual and parametric
analysis of the demands imposed by this high sensitivity upon the middle ear mechanisms:
the head and the middle ear structures must collect sound energy from a large area
and concentrate it onto the oval window. Assuming that the specific input impedance
of the mammalian cochlea is relatively constant, and smaller than the characteristic
acoustic impedance of water, we find that the impedance matching task of the cetacean
middle ear is very different from that of terrestrial mammals: instead of a large
pressure amplification, cetaceans need amplification of particle velocity. Our mechanical
four-bone model of the odontocete middle ear is based on the anatomy of the tympano-periotic
complex and consists of four rigid bone units (tympanic bone, the malleus-incus complex,
stapes, periotic bone) connected through elastic junctions. The velocity amplification
is brought about by lever mechanisms and elastic couplings. The model produced velocity
amplifications ranging from 7- to 23-fold when provided with middle ear parameters
from the six odontocete species for which audiograms are available. The model reproduces
the complete audiograms of these six species fairly well for frequencies up to about
100-120 kHz.