Zhuang Qiao scite author profile

Zhuang Qiao

4Publications

132Citation Statements Received

16Citation Statements Given

How they've been cited

176

124

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Affiliations

Zhejiang University of Technology, Institute of Information Engineering, Chinese Academy of Sciences

Publications

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Noseleaf Furrows in a Horseshoe Bat Act as Resonance Cavities Shaping the Biosonar Beam

Qiao

Müller

2006

Phys. Rev. Lett.

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Horseshoe bats emit their ultrasonic biosonar pulses through nostrils surrounded by intricately shaped protuberances (noseleaves). While these noseleaves have been hypothesized to affect the sonar beam, their physical function has never been analyzed. Using numerical methods, we show that conspicuous furrows in the noseleaf act as resonance cavities shaping the sonar beam. This demonstrates that (a) animals can use resonances in external, half-open cavities to direct sound emissions, (b) structural detail in the faces of bats can have acoustic effects even if it is not adjacent to the emission sites, and (c) specializations in the biosonar system of horseshoe bats allow for differential processing of subbands of the pulse in the acoustic domain.

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Numerical study of the effect of the noseleaf on biosonar beamforming in a horseshoe bat

Qiao

Müller

2007

Phys. Rev. E

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Around 300 bat species are known to emit their ultrasonic biosonar pulses through the nostrils. This nasal emission coincides with the presence of intricately shaped baffle structures surrounding the nostrils. Some prior experimental evidence indicates that these "noseleaves" have an effect on the shape of the animals' radiation patterns. Here, we present a numerical acoustical analysis of the noseleaf of a horseshoe bat species. We show that all three distinctive parts of its noseleaf ("lancet," "sella," "anterior leaf") have an effect on the acoustic near field as well as on the directivity pattern. Furthermore, we show that furrows in one of the parts (the lancet) also exert such an influence. The underlying physical mechanisms suggested by the properties of the estimated near field are cavity resonance, as well as reflection and shadowing of the sound waves emitted by the nostrils. In their effects on the near field, the noseleaf parts showed a tendency toward spatial partitioning with the effects due to each part dominating a certain region. However, interactions between the acoustic effects of the parts were also evident, most notably, a synergism between two frequency-dependent effects (cavity resonance and shadowing) to produce an even stronger frequency selectivity.

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An inverse problem of parameter estimation for time-fractional heat conduction in a composite medium using carbon–carbon experimental data

Qiao

Jiang

2015

Physica B: Condensed Matter

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Identify What You are Doing: Smartphone Apps Fingerprinting on Cellular Network Traffic

Zhai

Qiao

Wang

et al. 2021

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Zhuang Qiao

Noseleaf Furrows in a Horseshoe Bat Act as Resonance Cavities Shaping the Biosonar Beam

Numerical study of the effect of the noseleaf on biosonar beamforming in a horseshoe bat

An inverse problem of parameter estimation for time-fractional heat conduction in a composite medium using carbon–carbon experimental data

Identify What You are Doing: Smartphone Apps Fingerprinting on Cellular Network Traffic

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