First published online July 20, 2007
Journal of Experimental Biology 210, 2637-2648 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.005025
Mechanics of a `simple' ear: tympanal vibrations in noctuid moths
J. F. C. Windmill1,*,
J. H. Fullard2 and
D. Robert1
1 School of Biological Sciences, University of Bristol, Woodland Road,
Bristol, BS8 1UG, UK
2 Department of Biology, University of Toronto at Mississauga, 3359
Mississauga Road, Mississauga, Ontario, L5L 1C6, Canada
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Fig. 1. (A) Close-up of the tympanum of the ear of Noctua pronuba. An
opaque membrane, the conjunctivum (Cj), is situated distally from the tympanic
membrane (TM), both of which lie above the tympanic cavity at the posterior
lateral margin of the metathoracic segment. The stigma (arrow) marks the
attachment site of the auditory receptor organ. Scale bar, 0.25 mm. (B)
Morphological features of the tympanal system, highlighted as they pertain to
the vibrational characteristics of the tympanum. The TM, sensu
stricto, is bordered distally by a nodular sclerite, the epaulette (Ep),
which separates it from the Cj. The attachment site of the auditory
chordotonal organ (arrow in A) appears as a dark spot at the centre of the
opaque zone (OZ), which is surrounded by the transparent zone (TZ).
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Fig. 2. Response of the moth tympanal membrane to sound. (A) The amplitude-phase
gain response of the transparent zone (TZ) of N. pronuba. (B) The
coherence signal for the measurement in A. (C) The amplitude gain response of
the TZ of A. exclamationis, X. c-nigrum and X. triangulum.
(D) Measurement of the auditory neural activity of X. c-nigrum
combined with the laser vibrometric measurement of TZ displacement (A1 and A2:
auditory mechanosensory neurones).
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Fig. 3. Area scan and deflection shapes of the tympanic membrane (TM) in N.
pronuba. (A) Orientation image relating tympanal topography (left image)
to the position of the scanning lattice (right image). (B) Area scans of
tympanal deflections for three different frequencies. The deflections are
shown each time for four different phases along the oscillation cycle (see
also Movies 1–3 in supplementary material). Deflections are additionally
shown as profiles, looking at the tympanum from its side. Red indicates
positive displacement (or outward tympanal deflections), and green indicates
negative displacement (or inward tympanal deflections).
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Fig. 4. Area scan and deflection shapes of the tympanic membrane (TM) in A.
exclamationis. Area scans of tympanal deflections for three different
frequencies. The deflections are shown each time for four different phases
along the oscillation cycle. Deflections are additionally shown as profiles,
as if looking at the tympanum from its side. Red indicates positive
displacement (or outward tympanal deflections), and green indicates negative
displacements (or inward tympanal deflections).
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Fig. 5. Area scan and deflection shapes of the tympanic membrane (TM) in X.
triangulum. Area scans of tympanal deflections for three different
frequencies. The deflections are shown each time for four different phases
along the oscillation cycle. Deflections are additionally shown as profiles,
as if looking at the tympanum from its side. Red indicates positive
displacement (or outward tympanal deflections), and green indicates negative
displacement (or inward tympanal deflections).
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Fig. 6. Envelopes of mechanical deflections (nm Pa–1) across the
tympanic membrane (TM) of N. pronuba along transect lines for
different driving frequencies. (A) The position along the transect lines is
given with a calibrated scale. This scale constitutes the x-axis in
B–F. Scale bar, 0.25 mm. (B–F) The deflection envelopes are
constructed by displaying the instantaneous deflection velocities along the
transect for a series of phases (in 90° increments) along the full
oscillation cycle. Driving frequencies: (B) 20 kHz; (C) 45 kHz; (D) 70 kHz;
(E) 20 kHz; (F) 45 kHz; (G) 70 kHz; (H) 58.76 kHz (resonance). SA, sensory
attachment; Ep, epaulette.
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Fig. 7. Mechanical deflection across the membrane of a Brüel & Kjaer type
4138 pressure-field microphone. (A) Envelopes of deflection (gain) for driving
frequencies of 25 and 70 kHz. (B) Area scans of microphone membrane
deflections for driving frequencies of 25 and 70 kHz. The deflections are
shown each time for four different phases along the oscillation cycle.
Deflections are additionally shown as profiles, looking at the membrane from
its side. Red indicates positive gain (or outward membrane deflections), and
green indicates negative gain (or inward membrane deflections).
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Fig. 8. Comparison between moth and microphone membrane tension. (A) Normalised
maximum positive deflection (displacement) of the N. pronuba tympanic
membrane (TM) and the B&K 4138 microphone membrane at 70 kHz. Each
displacement is shown with its corresponding `fit', a Lorentzian for the moth
and a sinusoid for the microphone. (B) Tension across a B&K microphone,
fitted to a sinusoidal model, and across the N. pronuba TM, and
fitted to a Lorentzian, when both are driven at 70 kHz.
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© The Company of Biologists Ltd 2007
