留言板

尊敬的读者、作者、审稿人, 关于本刊的投稿、审稿、编辑和出版的任何问题, 您可以本页添加留言。我们将尽快给您答复。谢谢您的支持!

姓名
邮箱
手机号码
标题
留言内容
验证码

Echolocation calls of free-flying Himalayan swiftlets (Aerodramus brevirostris)

Bin WANG Jian-Zhang MA Yi CHEN Liang-Jing TAN Qi LIU Qi-Qi SHEN Qing-Yi LIAO Li-Biao ZHANG

Bin WANG, Jian-Zhang MA, Yi CHEN, Liang-Jing TAN, Qi LIU, Qi-Qi SHEN, Qing-Yi LIAO, Li-Biao ZHANG. Echolocation calls of free-flying Himalayan swiftlets (Aerodramus brevirostris). Zoological Research, 2013, 34(1): 8-13. doi: 10.3724/SP.J.1141.2013.01008
Citation: Bin WANG, Jian-Zhang MA, Yi CHEN, Liang-Jing TAN, Qi LIU, Qi-Qi SHEN, Qing-Yi LIAO, Li-Biao ZHANG. Echolocation calls of free-flying Himalayan swiftlets (Aerodramus brevirostris). Zoological Research, 2013, 34(1): 8-13. doi: 10.3724/SP.J.1141.2013.01008

短嘴金丝燕回声定位叫声特征

doi: 10.3724/SP.J.1141.2013.01008
基金项目: 广东省昆虫研究所优秀青年人才基金 (GDEI-yxqn201101); 广州市珠江科技新星专项 (2011J2200027)
详细信息
  • 中图分类号: Q959.7+35; Q958

Echolocation calls of free-flying Himalayan swiftlets (Aerodramus brevirostris)

  • 摘要: 2012年6月, 对湖南省石门县壶瓶山国家级自然保护区神景洞短嘴金丝燕的回声定位叫声进行研究, 在黑暗山洞内使用录音仪器录制其自由飞行状态的声音后使用声音软件进行分析。短嘴金丝燕捕食归巢时, 快速飞入洞口, 在洞内有光区域不发声, 到达洞内黑暗区域后开始发出回声定位叫声, 且飞行速度减慢。声音分析结果表明其回声定位叫声为双脉冲组的噪声脉冲串型(noise burst), 组内脉冲间隔很短[(6.6±0.42) ms], 组间脉冲间隔较长[(99.3±3.86) ms], 两者差异显著(P<0.01)。对比第一、第二脉冲声音参数发现, 主频和脉冲时程差异不显著, 第一、第二脉冲主频分别为(6.2±0.08) kHz和(6.2±0.10) kHz (P>0.05); 脉冲时程分别为(2.9±0.12) ms和(3.2±0.17) ms (P>0.05); 最高和最低频率差异显著, 第一、第二脉冲最高频率分别为(20.1±1.10) kHz和(15.4±0.98) kHz (P<0.01), 最低频率分别为(3.7±0.12) kHz和(4.0±0.09) kHz (P<0.05); 第一脉冲频宽((16.5±1.17) kHz)宽于第二脉冲((11.4±1.01) kHz) (P<0.01); 且第一脉冲能量[(?32.5±0.60) dB]高于第二脉冲[(?35.2±0.94) dB] (P<0.05)。另外, 短嘴金丝燕在黑暗山洞内的回声定位叫声还包含了部分超声波, 最高频率可达33.2 kHz。
  • [1] Brooke RK. 1972. Generic limits in Old World Apodidae and Hirundinidae. Bull Br Ornith Club, 92: 53-57.
    [2] Chantler P, Driessens G. 1995. Swifts: A Guide to the Swifts and Treeswifts of the World. Sussex, UK: Pica Press.
    [3] Chantler P, Wells DR, Schuchmann KL. 2000. Family Apodidae (Swifts)// del Hoyo J, Elliot A, Sargatal J. Handbook of the Birds of the World. Vol. 5. Barcelona, Spain: Lynx Edicions, 338-457.
    [4] Collins CT, Murphy R. 1994. Echolocation acuity of the Palawan swiftlet (Aerodramus palawanensis). Avocetta, 17: 157-162.
    [5] Cranbrook E, Medway L. 1965. Lack of ultrasonic frequencies in the calls of swiftlets (Collocalia spp.). Ibis, 107(2): 258.
    [6] Fenton MB. 1975. Acuity of echolocation in Collocalia hirundinacea (Aves: Apodidae), with comments on the distributions of echolocating swiftlets and molossid bats. Biotropica, 7(1): 1-7.
    [7] Fenton MB. 2001. Bats (Revised Edition). New York: Facts on File, Inc.
    [8] Fullard JH, Barclay RMR, Thomas DW. 1993. Echolocation in free-flying Atiu swiftlets (Aerodramus sawtelli). Biotropica, 25(3): 334-339.
    [9] Griffin DR. 1958. Listening in the Dark. New Haven: Yale University Press.
    [10] Griffin DR, Suthers RA. 1970. Sensitivity of echolocation in cave swiftlets. Biological Bulletin, 139(3): 495-501.
    [11] Griffin DR, Thompson D. 1982. Echolocation by cave swiftlets. Behavioral Ecology and Sociobiology, 10(2): 119-123.
    [12] Langham N. 1980. Breeding biology of the Edible-nest Swiftlet Aerodramus fuciphagus. Ibis, 122(4): 447-461.
    [13] Lee PLM, Clayton DH, Griffiths R, Page RDM. 1996. Does behavior reflect phylogeny in swiftlets (Aves: Apodidae)? A test using cytochrome b mitochondrial DNA sequences. Proceedings of the National Academy of Sciences USA, 93(14): 7091-7096.
    [14] Li P, Chen FJ, Huang SJ, Zong H. 2007. Himalayan swiftlet’s echolocation. Sichuan Journal of Zoology, 26(1): 38-40. [李鹏, 陈发军, 黄时杰, 宗浩. 2007. 短嘴金丝燕的回声定位机制与其归巢行为的探究. 四川动物, 26(1): 38-40.]
    [15] MacKinnon J, Phillipps K, He FQ. 2000. A Field Guide to the Birds of China (Chinese translation). Changsha: Hunan Education Press, 94. [约翰·马敬能, 卡伦·菲利普斯, 何芬奇. 2000. 中国鸟类野外手册 (中文翻译版). 长沙: 湖南教育出版社, 94.]
    [16] Medway L. 1962. The swiftlets (Collocalia) of Niah cave, Sarawak. Par 2. Ecology and the regulation of breeding. Ibis, 104(2): 228-245.
    [17] Medway L. 1967. The function of echonavigation among swiftlets. Animal Behavior, 15(4): 416-420.
    [18] Medway L. 1969. Studies on the biology of the Edible-nest swiftlets of South-East Asia. Mala Nat J, 22: 57-63.
    [19] Medway L, Pye JD. 1977. Echolocation and the systematics of swiftlets, Chap. 19 // Stonehouse B, Perrins CM. Evolutionary Ecology. Baltimore: University Park Press, 225-238.
    [20] Price JJ, Lanon SM. 2002. Reconstructing the evolution of complex bird song in the oropendolas. Evolution, 56(7): 1514-1529.
    [21] Price JJ, Johnson KP, Clayton DH. 2004. The evolution of echolocation in swiftlets. Journal of Avian Biology, 35(2): 135-143.
    [22] Suthers RA, Hector DH. 1982. Mechanism for the production of echolocating clicks by the grey swiftlet, Collocalia spodiopygia. J Journal of Comparative Physiology, 148(4): 457-470.
    [23] Smyth DM, Roberts JR. 1983. The sensitivity of echolocation by the grey swiftlet Aerodramus spodiopygius. Ibis, 125(3): 339-345.
    [24] Thomassen HA, Povel GDE. 2006. Comparative and phylogenetic analysis of the echo clicks and social vocalizations of swiftlets (Aves: Apodidae). Biological Journal of Linnean Society, 88(4): 631-643.
    [25] Zheng GM. 2011. A Checklist of the Classification and Distribution of the Birds of China. 2nd ed. Beijing: Science Press, 133-134. [郑光美. 2011. 中国鸟类分类与分布名录. 2版. 北京: 科学出版社, 133-134.]
  • [1] Da-Jian He, Lin Wang, Zhi-Bi Zhang, Kun Guo, Jing-Zheng Li, Xie-Chao He, Qing-Hua Cui, Ping Zheng.  Maternal gene Ooep may participate in homologous recombination-mediated DNA double-strand break repair in mouse oocytes, Zoological Research. doi: 10.24272/j.issn.2095-8137.2018.067
    [2] HU Kai-Liang, WEI Li, ZHU Teng-Teng, WANG Xu-Zhong, ZHANG Li-Biao.  Dietary composition, echolocation pulses and morphological measurements of the long-fingered bat Miniopterus fuliginosus (Chiroptera: Vespertilioninae), Zoological Research. doi: 10.3724/SP.J.1141.2011.02163
    [3] WANG Xu-Zhong, HU Kai-Liang, WEI Li, XU Dong, ZHANG Li-Biao.  Characterization and comparison of the doppler compensation acoustic wave in Hipposideros armiger, Zoological Research. doi: 10.3724/SP.J.1141.2010.06663
    [4] ZHU Guang-jian, Han Nai-jian, HONG Ti-yu, TAN Min, YU Dong-mei, ZHANG Li-bi.  Echolocation Call, Roost and ND 1 Sequence Analysis of New Record of Nyctalus plancyi(Chiroptera: Vespertilionidae)on Hainan Island, Zoological Research. doi: 10.3724/SP.J.1141.2008.04447
    [5] LIU Sen, JIANG Ting-lei, SHI Li-min, YE Gen-xian, FENG Jiang.  Characteristics and Analysis of Echolocation Calls by Coelops frithi, Zoological Research.
    [6] LUO Feng , LI An-an, WU Fei-jian, LIANG Bing, ZHANG Shu-yi , *, CHEN Qi-cai , *Basic Properties of Neuron Response to Sound Stimulation in the Inferior Colliculus of Rhinolophus pusillus, Zoological Research.
    [7] WEI Li, ZHOU Shan-yi, ZHANG Li-biao, LIANG Bing, HONG Ti-yu, ZHANG Shu-yi, *Characteristics of Echolocation Calls and Summer Diet of Three Sympatric Insectivorous Bats Species, Zoological Research.
    [8] CHEN Min, FENG Jiang, LIU Ying, ZHANG Xi-chen, LI Zhen-xin, ZHOU Jiang, ZHANG Shu-yi.  Relationship Between Echolocation Calls and Age in the Bat Species of Rhinolophus pearsoni, Zoological Research.
    [9] FANG Yong-qiang, WENG You-zhu, Liu Li-li, FANG Qi, DAI Yan-yu.  Mechanism of 5-HT and GnRH Physiological Action in the Ovary of Crassostrea gigas:Orientation of Double Staining and Immunocytochemistry, Zoological Research.
    [10] MA Jie, ZHANG Li-biao, LIANG Bing, SHEN Jun-xian, ZHANG Shu-yi, JONES Gareth.  Piscivorous Habit and Echolocation Sound of Myotis ricketti at Fangshan,Beijing, Zoological Research.
    [11] CHEN Dao-hai, LI Jie-ping, LIN Huan-fang, QIU Zhan-feng.  Sound Structure and Behavior Analysis of Velarifictorus asperses (Walker), Zoological Research.
    [12] ZHANG Li-biao, LU Li-ren, ZHOU Shan-yi, DAI Qiang, ZHAO Hui-hua, LOU Guo-hua, ZHANG Shu-yi.  Comparison of the Echolocation Signals in Two Species of Flat-headed Bats at Flying, Zoological Research.
    [13] ZHOU Jiang, XIE Jia-hua, DAI Qiang, ZENG Ya-jun, LIU Jian-xin, ZHANG Wen-gang, ZHANG Shu-yi.  Feeding Behavioral Strategy of Rhinolophus pearsoni in Summer, Zoological Research.
    [14] FENG Jiang, LI Zhen-Xin, ZHOU Jiang, ZHAO Hui-Hua, ZHANG Shu-Yi.  Echolocation Calls Analyzing of Great Evening Bat (Ia io), Zoological Research.
    [15] LI Jin-Gang, HE Jian-Ping, WANG Ting-Zheng, MIN Yi-Jian.  Analysis on The Sound Spectrum of Calls in The Gansu Zokor,Myospalax cansus, Zoological Research.
    [16] TAI Fa-dao, WANG Ting-zheng, MIN Yi-jian.  The Calling Behaviours and Sound Spectrograph of Microtus mandarinus, Zoological Research.
    [17] ZHOU Xiao-ming, SUN Xin-de.  The Influence on The Characteristics of Frequency Tuning of Bats'inferior Collicular Neurons by Early Sound Exposure, Zoological Research.
    [18] JIANG Shi-ren, DING Ping, LI Jian-hua, ZHU ge-Yang.  The Sound Spectrographic Analyses on The Call of Golden Pheasant Chrysolophus pictus, Zoological Research.
    [19] HAN Lian-xian, YANG Lan, ZHENG Bao-lai.  The Sound Spectrogrhic Analyses on the Calls of Lady Amherst's Pheasant (Chrysolophus amherstiae), Zoological Research.
    [20] LIU Lian-rui, WANG Hui-peng, FENG Shang, YAN Tao-lan, FENG Zhi-fan.  Study on Transformation of Double Minute Chromosome DNA of L615 Cells, Zoological Research.
  • 加载中
计量
  • 文章访问数:  957
  • HTML全文浏览量:  32
  • PDF下载量:  1860
  • 被引次数: 0
出版历程
  • 收稿日期:  2012-09-03
  • 修回日期:  2012-10-31
  • 刊出日期:  2013-02-08

Echolocation calls of free-flying Himalayan swiftlets (Aerodramus brevirostris)

doi: 10.3724/SP.J.1141.2013.01008
    基金项目:  广东省昆虫研究所优秀青年人才基金 (GDEI-yxqn201101); 广州市珠江科技新星专项 (2011J2200027)
  • 中图分类号: Q959.7+35; Q958

摘要: 2012年6月, 对湖南省石门县壶瓶山国家级自然保护区神景洞短嘴金丝燕的回声定位叫声进行研究, 在黑暗山洞内使用录音仪器录制其自由飞行状态的声音后使用声音软件进行分析。短嘴金丝燕捕食归巢时, 快速飞入洞口, 在洞内有光区域不发声, 到达洞内黑暗区域后开始发出回声定位叫声, 且飞行速度减慢。声音分析结果表明其回声定位叫声为双脉冲组的噪声脉冲串型(noise burst), 组内脉冲间隔很短[(6.6±0.42) ms], 组间脉冲间隔较长[(99.3±3.86) ms], 两者差异显著(P<0.01)。对比第一、第二脉冲声音参数发现, 主频和脉冲时程差异不显著, 第一、第二脉冲主频分别为(6.2±0.08) kHz和(6.2±0.10) kHz (P>0.05); 脉冲时程分别为(2.9±0.12) ms和(3.2±0.17) ms (P>0.05); 最高和最低频率差异显著, 第一、第二脉冲最高频率分别为(20.1±1.10) kHz和(15.4±0.98) kHz (P<0.01), 最低频率分别为(3.7±0.12) kHz和(4.0±0.09) kHz (P<0.05); 第一脉冲频宽((16.5±1.17) kHz)宽于第二脉冲((11.4±1.01) kHz) (P<0.01); 且第一脉冲能量[(?32.5±0.60) dB]高于第二脉冲[(?35.2±0.94) dB] (P<0.05)。另外, 短嘴金丝燕在黑暗山洞内的回声定位叫声还包含了部分超声波, 最高频率可达33.2 kHz。

English Abstract

王斌, 马建章, 陈毅, 谭梁静, 刘奇, 沈琪琦, 廖庆义, 张礼标. 短嘴金丝燕回声定位叫声特征[J]. 动物学研究, 2013, 34(1): 8-13. doi: 10.3724/SP.J.1141.2013.01008
引用本文: 王斌, 马建章, 陈毅, 谭梁静, 刘奇, 沈琪琦, 廖庆义, 张礼标. 短嘴金丝燕回声定位叫声特征[J]. 动物学研究, 2013, 34(1): 8-13. doi: 10.3724/SP.J.1141.2013.01008
Bin WANG, Jian-Zhang MA, Yi CHEN, Liang-Jing TAN, Qi LIU, Qi-Qi SHEN, Qing-Yi LIAO, Li-Biao ZHANG. Echolocation calls of free-flying Himalayan swiftlets (Aerodramus brevirostris). Zoological Research, 2013, 34(1): 8-13. doi: 10.3724/SP.J.1141.2013.01008
Citation: Bin WANG, Jian-Zhang MA, Yi CHEN, Liang-Jing TAN, Qi LIU, Qi-Qi SHEN, Qing-Yi LIAO, Li-Biao ZHANG. Echolocation calls of free-flying Himalayan swiftlets (Aerodramus brevirostris). Zoological Research, 2013, 34(1): 8-13. doi: 10.3724/SP.J.1141.2013.01008
参考文献 (25)

目录

    /

    返回文章
    返回