Abstract
Horseshoe (Rhinolphidae) and Old World leaf-nosed (Hipposideridae) bats are high duty cycle (HDC) echolocators sharing a suite of adaptations including long duration signals relative to their signal periods, peak energy concentrated in a narrow spectral band dominated by a constant frequency (CF) component, ‘auditory fovea’ (over-representation and sharp tuning of neurons responsible for frequencies at or around the CF) and ability to compensate for Doppler shifts in echoes. HDC bats separate signals from returning echoes in the frequency domain. Rhinolophids are more specialised neurobiologically than hipposiderids, producing longer duration signals at higher duty cycles, and have narrowly tuned auditory fovea and almost full Doppler shift compensation. Here, I examine whether these differences have produced ecological divergence between the families by testing predictions of differences in prey perception, prey capture behaviour, foraging habitat and diet. I found no discernible differences in these variables between the two families. Rhinolophids and hipposiderids both forage close to vegetation, capture prey by aerial hawking and gleaning from surfaces, and consume mostly flying insects with spiders and terrestrial, flightless arthropods taken occasionally. The data presented here show that the two families are similar in foraging ecology despite differences in echolocation and audition.
Highlights
Echolocation is a sensory system involving the tight coupling of signal production and echo reception that is used by species in four orders of mammals and two orders of birds
Long duration pure tone signals produced at high duty cycles and a very narrowly tuned auditory fovea facilitated by Doppler shift compensation (DSC) allow these bats to capture fluttering insects while overcoming environmental clutter
An important premise in interpretations of the evolutionary ecology of insectivorous bats is that both their echolocation signals and auditory capacities are adapted to the acoustical constraints of their foraging environment (Neuweiler 2000)
Summary
Echolocation is a sensory system involving the tight coupling of signal production and echo reception that is used by species in four orders of mammals and two orders of birds. Most echolocating bats avoid forward masking, the process by which louder outgoing signals mask or reduce the sensitivity of the animal to the weaker returning echoes, by separating pulse and echo in the time domain (Fenton et al 1995). An alternative strategy is found in high duty cycle (HDC) echolocators that separate pulse and echo in the frequency domain (Schuller 1974). Fenton et al (2012) state that HDC echolocators share a unique combination of four adaptations. They emit echolocation signals with long durations relative to their signal periods. Journal compilation Ó CSIRO 2021 Open Access CC BY www.publish.csiro.au/journals/ajz
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