In a resonant vibration, two reactive elements, such as a mass and a spring
, interact: the resonant frequency depends on the magnitude of these two el
ements. The buildup and decay of the vibration depend on the way the resona
tor is driven and on the damping in the system.
The evidence for the existence of resonators in insect sound production is
assessed. The mechanics of different types of sound-producing system found
in insects is described. Mechanical frequency-multiplier mechanisms, which
convert the relatively slow contraction of muscles to the higher frequency
of the sound, are commonly used to convert the comparatively slow muscle co
ntraction rate to the higher frequency of the sound. The phasing and rate o
f mechanical excitation may also affect the frequency and duration of the s
ound that is produced.
Although in many insects the song may appear to be produced by the excitati
on of a simple resonator, the song frequency may not be constant, suggestin
g that other factors, such as the mechanism of excitation, or variation of
the effective mass or elasticity of the system during sound production, may
be additional determinants of the song frequency.
Loud, and hence efficient, transduction of the energy of a mechanical reson
ator into sound may involve a second stage of transduction which, by dampin
g the resonator, may compromise tonal purity. Some insect singers resolve t
his problem by tuning both stages of transduction to the same frequency, th
ereby maintaining tonal purity.