鼻甲对调频蝙蝠的作用取决于它们感觉特化的程度。

What noseleaves do for FM bats depends on their degree of sensorial specialization.

机构信息

Active Perception Lab, University of Antwerp, Antwerp, Belgium.

出版信息

PLoS One. 2010 Aug 16;5(8):e11893. doi: 10.1371/journal.pone.0011893.

DOI:10.1371/journal.pone.0011893

PMID:20808438

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2922331/

Abstract

BACKGROUND

Many bats vocalizing through their nose carry a prominent noseleaf that is involved in shaping the emission beam of these animals. To our knowledge, the exact role of these appendages has not been thoroughly investigated as for no single species both the hearing and the emission spatial sensitivities have been obtained. In this paper, we set out to evaluate the complete spatial sensitivity of two species of New World leaf-nosed bats: Micronycteris microtis and Phyllostomus discolor. From an ecological point of view, these species are interesting as they belong to the same family (Phyllostomidae) and their noseleaves are morphologically similar. They differ vastly in the niche they occupy. Comparing these species allows us to relate differences in function of the noseleaf to the ecological background of bat species.

METHODOLOGY/PRINCIPAL FINDINGS: We simulate the spatial sensitivity of both the hearing and the emission subsystems of two species, M. microtis and P. discolor. This technique allows us to evaluate the respective roles played by the noseleaf in the echolocation system of these species. We find that the noseleaf of M. microtis focuses the radiated energy better and yields better control over the emission beam.

CONCLUSIONS

From the evidence presented we conclude that the noseleaves serve quantitatively different functions for different bats. The main function of the noseleaf is to serve as an energy focusing mechanism that increases the difference between the reflected energy from objects in the focal area and objects in the periphery. However, despite the gross morphological similarities between the noseleaves of the two Phyllostomid species they focus the energy to a different extent, a capability that can be linked to the different ecological niches occupied by the two species.

摘要

背景

许多通过鼻腔发声的蝙蝠都有一个突出的鼻甲，这个鼻甲参与了这些动物发射波束的形成。据我们所知，由于没有一种蝙蝠的听觉和发射空间敏感度同时得到测量，因此这些附属物的确切作用还没有被彻底研究过。在本文中，我们着手评估两种新世界叶鼻蝠的完整空间敏感度：Micronycteris microtis 和 Phyllostomus discolor。从生态学的角度来看，这些物种很有趣，因为它们属于同一个科（叶鼻蝠科），鼻甲在形态上相似，但它们在占据的生态位上却有很大的不同。比较这些物种可以使我们将鼻甲功能的差异与蝙蝠物种的生态背景联系起来。

方法/主要发现：我们模拟了两种蝙蝠（M. microtis 和 P. discolor）的听觉和发射子系统的空间敏感度。这种技术使我们能够评估鼻甲在这些物种的回声定位系统中的各自作用。我们发现，M. microtis 的鼻甲能更好地聚焦辐射能量，并能更好地控制发射波束。

结论

从提出的证据中，我们得出结论，鼻甲在不同的蝙蝠中起着不同的作用。鼻甲的主要功能是作为一种能量聚焦机制，增加焦点区域内物体和周围物体反射能量之间的差异。然而，尽管两种 Phyllostomid 物种的鼻甲在形态上有很大的相似性，但它们聚焦能量的程度不同，这种能力可以与两种物种所占据的不同生态位联系起来。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ec70/2922331/08acc26331e6/pone.0011893.g001.jpg

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鼻甲对调频蝙蝠的作用取决于它们感觉特化的程度。

What noseleaves do for FM bats depends on their degree of sensorial specialization.

机构信息

出版信息

BACKGROUND

CONCLUSIONS

背景

结论

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