1. Radiation patterns of the 55, 75 and 95 kHz components in frequency-modulated sounds emitted by the grey bat (Myotis grisescens) were studied. FM sounds similar to species-specific orientation sounds were elicited by electrical stimuli applied to the midbrain while the head of the animal was immobilized by a nail cemented to its skull. The main beam was emitted 5-10° downward from the eye-nostril line. The radiation angle at one half of maximum amplitude was 38° lateral, 18° up and 50° down at 55 kHz, 34° lateral, 8° up and 32° down at 75 kHz, and 30° lateral, 5° up and 25° down at 95 kHz. At 95 kHz, two prominent side lobes were present.udud2. The directional sensitivity of the auditory system (DSA) measured in terms of the potential evoked in the lateral lemniscus was studied with the grey bat (M. grisescens) and the little brown bat (M. lucifugus). The maximally sensitive direction moved toward the median plane with the increase in frequency from 35-95 kHz. The slope of the DSA curve increased from 0.3-0.6 dB/degree with frequency.udud3. The directional sensitivity of the echolocation system (DSE) was calculated using both the DSA curve and the radiation pattern of the emitted sound. The maximally sensitive direction of the echolocation system was 15° lateral to the median plane at 55kHz and 2.5° lateral at 95 kHz. The slope of the DSE curve increased from o.6 to 1.0 dB/degree with frequency. Thus, the higher the frequency of sound, the sharper was the directional sensitivity of the echolocation system.udud4. The interaural pressure difference (IPD), which appeared to be the essential cue for echolocation in Myotis, changed linearly with the azimuth angle from 0-30° lateral regardless of the frequency of sound, at respective rates of 0.4, 0.7, 0.3 and 0.4 dB/degree for 35, 55, 75 and 95 kHz sounds. Beyond 30°, the change in IPD was quite different depending on frequency. For 75 and 95 kHz sounds, the IPD stayed nearly the same between 30° and 90°. Thus, the 75-95 kHz components in FM orientation sounds were not superior to the 35 and 55 kHz components in terms of the IPD cue for echolocation.udud5. Assuming the just-detectable IPD and ITD to be 0.5 dB and 5µsec respectively, as in man, the just-detectable azimuth difference of Myotis around the median plane would be 0.7-1.7° with the IPD cue and 11° with the ITD cue.
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机译:1.研究了灰蝙蝠(Myotis grisescens)发出的调频声音中55、75和95 kHz分量的辐射模式。 FM声音类似于对特定物种的定向声音,是通过对中脑施加电刺激而引起的,而用胶粘在其头骨上的指甲固定了动物的头部。主光束从鼻孔线向下发射5-10°。最大振幅的一半处的辐射角为:横向38°,55 kHz时向上18°和向下50°,横向75°,75 kHz时向上8°和向下32°,横向30°,向上5°和25 °下降至95 kHz。在95 kHz处,存在两个突出的旁瓣。用灰蝙蝠(M. grisescens)和小棕蝙蝠(M. lucifugus)研究了听觉系统(DSA)的定向灵敏度,该方向灵敏度是根据在侧缘红膜菌中诱发的电位来测量的。随着频率从35-95 kHz的增加,最大敏感方向移向中间平面。 DSA曲线的斜率随频率从0.3-0.6 dB /度增加。 ud ud3。使用DSA曲线和发出的声音的辐射方向图计算回声定位系统(DSE)的方向灵敏度。回声定位系统的最大敏感方向是在55kHz处相对于中间平面横向15°,在95kHz处横向2.5°。 DSE曲线的斜率随频率从o.6增加到1.0 dB /度。因此,声音的频率越高,回声定位系统的方向灵敏度就越强。耳间压差(IPD)似乎是Myotis中回声定位的基本提示,无论声音频率如何,其倾角随侧倾角从0-30°线性变化,而频率分别为0.4、0.7、0.3和0.4 35、55、75和95 kHz声音的dB /度。超过30°,IPD的变化取决于频率而有很大不同。对于75和95 kHz的声音,IPD在30°和90°之间几乎保持不变。因此,就回声定位的IPD提示而言,FM定向声音中的75-95 kHz分量并不优于35和55 kHz分量。假设像人一样,恰好可检测到的IPD和ITD分别为0.5 dB和5µsec,在IPD提示下,Myotis在中心平面周围的刚刚可测方位角差将为0.7-1.7°,而ITD提示为11°。
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