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Data supporting Lung-to-ear sound transmission does not improve directional hearing in green treefrogs (Hyla cinerea)

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2016-01-05
2016-01-12

Date completed

2020-07-01

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Data supporting Lung-to-ear sound transmission does not improve directional hearing in green treefrogs (Hyla cinerea)

Published Date

2020-09-04

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Author Contact

Bee, Mark A
mbee@umn.edu

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Dataset
Experimental Data

Abstract

Amphibians are unique among extant vertebrates in having middle ear cavities that are internally coupled to each other and to the lungs. In frogs, the lung-to-ear sound transmission pathway can influence the tympanum’s inherent directionality, but what role such effects might play in directional hearing remain unclear. In this study of the American green treefrog (Hyla cinerea), we tested the hypothesis that the lung-to-ear sound transmission pathway functions to improve directional hearing, particularly in the context of intraspecific sexual communication. Using laser vibrometry, we measured the tympanum’s vibration amplitude in females in response to a frequency modulated sweep presented from 12 sound incidence angles in azimuth. Tympanum directionality was determined across three states of lung inflation (inflated, deflated, reinflated) both for a single tympanum in the form of the vibration amplitude difference (VAD) and for binaural comparisons in the form of the interaural vibration amplitude difference (IVAD). The state of lung inflation had negligible effects (typically less than 0.5 dB) on both VADs and IVADs at frequencies emphasized in the advertisement calls produced by conspecific males (834 Hz and 2730 Hz). Directionality at the peak resonance frequency of the lungs (1558 Hz) was improved by ≅ 3 dB for a single tympanum when the lungs were inflated versus deflated, but IVADs were not impacted by the state of lung inflation. Based on these results, we reject the hypothesis that the lung-to-ear sound transmission pathway functions to improve directional hearing in frogs.

Description

The 11 data files in this archive accompany the publication: Christensen-Dalsgaard J, Lee N, Bee MA (in press) Lung-to-ear sound transmission does not improve directional hearing in green treefrogs (Hyla cinerea). Journal of Experimental Biology.

Referenced by

doi: https://doi.org/10.1101/2020.06.30.171074
Christensen-Dalsgaard J, Lee N, Bee MA (2020) Lung-to-ear sound transmission does not improve directional hearing in green treefrogs (Hyla cinerea). Journal of Experimental Biology
https://doi.org/10.1242/jeb.232421

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National Science Foundation

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Suggested citation

Christensen-Dalsgaard, Jakob; Lee, Norman; Bee, Mark A. (2020). Data supporting Lung-to-ear sound transmission does not improve directional hearing in green treefrogs (Hyla cinerea). Retrieved from the Data Repository for the University of Minnesota (DRUM), https://doi.org/10.13020/rj08-sc66.

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Figure1_Inflated.xlsx
Figure1_Inflated.xlsx This figure contains the transfer functions of the tympanum's vibration amplitude at intervals of 1 Hz across 12 angles of sound incidence with the lungs in the INFLATED condition. These data are depicted in Row 1 of Figure 1. There are 21 sheets, one for each subject.
(28.18 MB)

Figure1_Deflated.xlsx
Figure1_Deflated.xlsx This figure contains the transfer functions of the tympanum's vibration amplitude at intervals of 1 Hz across 12 angles of sound incidence with the lungs in the DEFLATED condition. These data are depicted in Row 2 of Figure 1. There are 21 sheets, one for each subject.
(28.04 MB)

Figure1_Reinflated.xlsx
Figure1_Reinflated.xlsx This figure contains the transfer functions of the tympanum's vibration amplitude at intervals of 1 Hz across 12 angles of sound incidence with the lungs in the REINFLATED condition. These data are depicted in Row 3 of Figure 1. There are 21 sheets, one for each subject.
(28.03 MB)

Figure2_VADs_3Lung*3Frequency.csv
Figure2_VADs_3Lung*3Frequency.csv This .csv file contains the vibration amplitude differences (VADs) in the three states of lung inflation at the frequencies of 834 Hz, 1558 Hz, and 2730 Hz. Also included are the two angles between which the VAD was computed. These VAD data are depicted in Figure 2 based on computing the marginal means from a repeated measures analysis of variance. There are 21 rows, one for each subject.
(4.35 KB)

Figure3a_IVADs_Inflated.xlsx
Figure3a_IVADs_Inflated.xlsx This .xlsx file contains the interpolated interaural vibration amplitude differences (IVADs) shown in panel A of Figure 3. There are 21 sheets in each file, one for each subject.
(757.48 MB)

Figure3b_IVADs_Deflated.xlsx
Figure3b_IVADs_Deflated.xlsx This .xlsx file contains the interpolated interaural vibration amplitude differences (IVADs) shown in panel B of Figure 3. There are 21 sheets in each file, one for each subject.
(756.83 MB)

Figure3c_IVADs_Reinflated.xlsx
Figure3c_IVADs_Reinflated.xlsx This .xlsx file contains the interpolated interaural vibration amplitude differences (IVADs) shown in panel C of Figure 3. There are 21 sheets in each file, one for each subject.
(757.71 MB)

Figure4and5_IVADs_3Lung*5Angle*3Frequency.csv
Figure4and5_IVADs_3Lung*5Angle*3Frequency.csv This .csv file contains the interaural vibration amplitude differences (IVADs) in the three states of lung inflation at angles of 30, 60, 90, 120, and 150 degrees, and at the frequencies of 834 Hz, 1558 Hz, and 2730 Hz. These IVAD data are depicted in Figures 4 and 5 based on computing the marginal means from a repeated measures analysis of variance. There are 21 rows, one for each subject.
(12.13 KB)

Figure5_IVAD_PolarPlot_Values.csv
Figure5_IVAD_PolarPlot_Values.csv This .csv file contains the data on interaural vibration amplitude differences (IVADs) as functions of frequency and angle plotted in the polar plots of Figure 5. There are 21 rows, one for each subject.
(3.9 KB)

Figure6_IVAD_Differences.xlsx
Figure6_IVAD_Differences.xlsx This .xlsx file contains the data on differences in interaural vibration amplitude differences (IVADs) between the inflated and deflated states of lung inflation as functions of frequency (200 to 7500 Hz) and sound incidence angle (30 degree steps). These data are plotted in in the heatmap of Fig. 6A. There are 21 sheets, one for each subject.
(26.7 MB)

Figure6_IVAD_PolarPlot_Values.xlsx
Figure6_IVAD_PolarPlot_Values.xlsx This .xlsx file contains the data on differences in interaural vibration amplitude differences (IVADs) between the inflated and deflated states of lung inflation for the frequencies of 834 Hz, 1558 Hz, and 2730 Hz. Differences are shown in 1-degree steps from 0 degrees to 180 degrees. These data are plotted in the form of polar plots in Fig. 6B. There are 3 sheets, one for each frequency, and within each sheet there are 21 rows, one for each subject.
(172.98 KB)

File Descriptions.txt
README
(3.35 KB)

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