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1.
刘森  江廷磊  施利民  叶根先  冯江  &#   《动物学研究》2008,29(1):95-98
采用超声波监听仪U30录制无尾蹄蝠自由飞行状态的回声定位声波,经Batsound 3.0分析,其声波为高频 (145.4±10.9 kHz)、宽带(62.6±9.2 kHz)、具两个谐波的短(1.67±0.4 ms)FM型,不同于蹄蝠科其他蝙蝠的CF型,表明该科内物种声波类型存在多态性。头骨的形态测定分析支持其通过鼻腔发射声波,与蹄蝠科其他蝙蝠一致,表明该科内声波发射方式的单一性。适应环境的选择压力及翼型和声波的适应性可能是其选择FM型叫声的重要原因。  相似文献   

2.
本研究于2006年5-8月在桂林市七星公园七星岩洞进行,比较分析了共栖2科(蹄蝠科和蝙蝠科)6种共75只蝙蝠的同声定位信号和翼型特征.普氏蹄蝠的回声定位叫声为短而多谐波的CF/FM型,主频率为61.2±0.8 kHz,具有高翼载、低翼展比和中等翼尖指数;大蹄蝠的回声定位叫声为单CF/FM型,主频率为68.6±0.7 kHz,具有高翼载、低翼展比和中等翼尖指数;中蹄蝠的回声定位叫声为单CF/FM型,主频率为85.2±0.5 kHz,具有中等翼载、低翼展比和中等翼尖指数;高颅鼠耳蝠的回声定位叫声为长带宽的FM型,主频率为50.7±3.8 kHz,具有低翼载、中等翼展比和低翼尖指数;大足鼠耳蝠回声定位叫声为FM型,主频率为39.9±3.2 kHz,具有中等翼载、低翼展比和高翼尖指数;绒山蝠回声定位叫声为短而多谐波的FM型,主频率为49.0±0.4 kHz,具有高翼载、中等翼展比和低翼尖指数.经单因素方差分析表明,6种蝙蝠之间绝大部分的形态和声音参数差异显著(One-way ANOVA,P<0.05).以上结果说明,6种同地共栖蝙蝠种属特异的回声定位叫声和形态结构体现出了相互之间的生态位分离,从而降低了种间竞争压力,使得6种蝙蝠能够同地共存.  相似文献   

3.
吉林省发现绯鼠耳蝠   总被引:6,自引:0,他引:6  
在吉林省集安市采到绯鼠耳蝠 (Myotisformosus)样本 5只 ,为吉林省蝙蝠科新记录。对其体型与头骨进行了测量。对回声定位声波进行了录制和分析 ,发现其回声定位声波为FM型 ,一次完整声波包括1~ 2个谐波 ,主频率 (5 4 5 4± 6 3 9)kHz,通过回声定位声波特征推测 ,绯鼠耳蝠在较简单的环境中捕食中等大小的昆虫。  相似文献   

4.
2009年9月在广东省南岭采集到5只森林型蝙蝠,其鼻孔突出成短管状,背部毛棕褐色,前臂长34.3~36.8mm;核型为2n=44,FN=50.经鉴定为蝙蝠科管鼻蝠亚科的中管鼻蝠(Murina huttonii),为广东省翼手类分布新纪录.用蝙蝠超声波接收器(Anabat Ⅱ)录制并分析其回声定位声波,为FM型.中管鼻蝠...  相似文献   

5.
皮氏菊头蝠回声定位声波与年龄的关系   总被引:2,自引:0,他引:2  
皮氏菊头蝠 (Rhinolophuspearsoni)雌性成体 5只和幼体 2只采自贵州省贞丰县珉谷镇。采用超声波探测仪 (D980 ,ULTRASOUNDDETECTOR)接收皮氏菊头蝠的回声定位声波 ,转换到原频率的 1 / 1 0后导入计算机 ,然后用专业声谱分析软件 (Batsound 3 1 0 )进行分析。成蝠在飞行和悬挂状态下的声波结构相似 ,只是声波各项参数值略有不同 :它们发射FM CF FM型声波 ,具有 2~ 3个谐波 ,主频率在飞行时为 5 6 80± 0 6 2kHz ,悬挂时为 5 8 0 5± 0 2 4kHz ;声脉冲时间和间隔在飞行时分别为 3 4 6 2± 5 2 9ms和 86 5 0± 1 9 72ms ,悬挂时分别为 4 1 0 8± 5 87ms和 1 1 7 2 9± 6 6 4 4ms ;能率环飞行时为 ( 4 4 0 6± 1 2 5 8) % ,悬挂时为 ( 4 6 0 0±2 4 2 5 ) %。幼蝠声波为CF FM型 ,谐波数为 5~ 8个 ,主频率明显低于成体 ,FM带宽窄于成体 ,声脉冲时间和间隔短于成体 ,能率环低于成体。皮氏菊头蝠回声定位声波与年龄有关 ,这可能因成体的声波主要是探测食物和周围环境的详细信息 ,而幼体主要是与母蝠进行交流。  相似文献   

6.
五种蝙蝠形态与回声定位叫声的性别差异   总被引:5,自引:0,他引:5  
为研究角菊头蝠(Rhinolophus cornutus)、三叶蹄蝠(Aselliscus uheeleri)、大蹄蝠(Hipposideros armiger)、大鼠耳蝠(Myotis myotis)和大足鼠耳蝠(M.riketti)的形态和回声定位叫声的性别差异性,明确同种蝙蝠雌雄个体对食物、栖息地等资源利用的细微差异,我们利用超声波探测仪、Batsound分析软件及SPSS11.0统计软件对5种95只蝙蝠进行了录音、声波分析和统计分析。5种蝙蝠形态性别差异性不显著,角菊头蝠、三叶蹄蝠、大蹄蝠和大足鼠耳蝠叫声频率性别差异性显著,大鼠耳蝠叫声频率性别差异性不显著。角菊头蝠雌性叫声的基频、分音、主频率高于雄性,声脉冲时间、间隔时间大于雄性,调频(FM)带宽小于雄性;三叶蹄蝠、大蹄蝠叫声的基频、主频率雄性高于雌性,调频带宽雌性小于雄性;大足鼠耳蝠叫声的主频率雄性高于雌性,FM带宽雌性大于雄性[动物学报49(6):742~747,2003]。  相似文献   

7.
皮氏菊头蝠夏季的捕食行为对策   总被引:9,自引:1,他引:8       下载免费PDF全文
利用蝙蝠超声波探测器和CoolEditor 2 0 0 0声波分析软件研究了皮氏菊头蝠 (Rhinolophuspearsoni)的超声波信号 ,同时在野外研究了其捕食行为。研究结果显示皮氏菊头蝠是FM/CF/FM型的食虫蝙蝠。其回声定位信号的CF声波两端均附有短暂的FM信号 ,每次声波脉冲包含 2段信号 ,第 1段信号的CF频率为 (6 1 0 8±0 0 19)kHz ,持续时间为 (4 6 85± 3 72 )ms ;第 2段信号的CF频率为 (6 0 97± 0 0 3)kHz ,持续时间为 (35 12± 2 6 7)ms。在对皮氏菊头蝠的捕食行为研究中 ,通过运用生物多样性指数分析和Spearman相关性分析 ,结果表明皮氏菊头蝠在常绿阔叶落叶混交林中主要以式捕食鳞翅目 (Lepidoptera)、鞘翅目 (Coleoptera)等中型个体的昆虫 ,对食物种类及其体型具有选择性。此外 ,其形态与回声定位功能之间还表现出相关性。  相似文献   

8.
冯江  李振新  陈敏  刘颖  张喜臣  周江  张树义 《生态学报》2003,23(9):1712-1718
大足鼠耳蝠(Myotisricketti)是中国特有蝙蝠,其回声定位声波和捕食策略国内外均无报道,对大足鼠耳蝠该方面的研究报导是国内首次。大足鼠耳蝠体型较大,具有强大的后足,足上有强而有力的弯曲的爪,尾膜和距很长。大足鼠耳蝠回声定位声波为FM(调频)型,一般具有1~2个谐波,主频率较低(37.78±1.04kHz),调频带较宽(第一谐波频带宽为42.02±6.98kHz,第二谐波频带宽为25.79±7.89kHz),声脉冲时间较长(2.91±0.54ms),声脉冲间隔时间变化较大(32.30±15.10ms),能率环较高(11.27±5.84%);野外观察发现,大足鼠耳蝠主要在低水面上空飞行,利用大足从水面捕食猎物(拖网式捕食),猎物主要由鱼类组成。即分析和讨论了大足鼠耳蝠形态特征、回声定位特征和捕食策略的相互适应性。  相似文献   

9.
蝙蝠回声定位声波的可塑性对其适应不同状态、生境以及捕食和社会交流具有重要的作用。为进一步研究大蹄蝠的回声定位声波在不同状态和生境下的可塑性,通过室内行为实验,对大蹄蝠在4种不同状态(室内飞行、静息、布袋内和手持)和4种不同生境复杂度(室外、室内0棵树、室内1棵树、室内5棵树)条件下飞行的回声定位声波特征进行研究。结果表明:大蹄蝠的回声定位声波为CF-FM型,通常连续发出2-4个脉冲组成一个脉冲组。对比大蹄蝠在4种不同状态下的回声定位叫声发现,主频按静息、布袋内、手持、飞行的顺序依次降低,后端FM频宽则按手持、布袋内、飞行和静息的顺序依次变短;而脉冲间隔和脉冲时程则均按静息、飞行、布袋内、手持的顺序依次增加。对比大蹄蝠在4种不同生境复杂度中飞行的回声定位叫声发现,主频按室外、室内0棵树、室内1棵树、室内5棵树依次提高,而脉冲时程及脉冲间隔则依次缩短;室外放飞条件下的后端FM频宽比室内飞行的短。研究结果说明,大蹄蝠在不同状态、不同生境复杂度条件下的回声定位叫声具有明显的可塑性和生境适应性。  相似文献   

10.
澳门翼手类物种多样性调查   总被引:2,自引:0,他引:2  
2009~2012年,对澳门翼手目(蝙蝠)物种多样性进行了调查.结果共捕捉到10个物种,属5科8属,其中包括澳门原来记载的2个物种,即蹄蝠科的大蹄蝠(Hipposideros armiger)和蝙蝠科的东亚伏翼(Pipistrellus abramus);本研究新增加8个物种,即狐蝠科的犬蝠(Cynopterus sphinx)和棕果蝠(Rousettus leschenaulti),鞘尾蝠科的黑髯墓蝠(Taphozous melanopogon),菊头蝠科的菲菊头蝠(Rhinolophus pusillus),以及蝙蝠科的大足鼠耳蝠(Myotis ricketti、普通伏翼(P.pipistrellus)、普通长翼蝠(Miniopterus schreibersi)和南长翼蝠(M.pusillus).另外,通过野外录音和分析,并与已发表物种声音特征比较核对,发现菊头蝠科和蹄蝠科各一种,前者可能是泰国菊头蝠(R.siamensis)或者中菊头蝠(R.affinis),后者可能是果树蹄蝠(H pomona)或者三叶蹄蝠(Aselliscus stoliczkanus).本文对已捕捉10种蝙蝠的分布、形态特征和回声定位叫声特征进行报道,同时对其种群数量和保护现状进行了讨论.保护蝙蝠栖息生境(洞穴、古老建筑和蒲葵树等)对保护澳门蝙蝠物种多样性至关重要.  相似文献   

11.
三种共栖蝙蝠的回声定位信号特征及其夏季食性的比较   总被引:3,自引:2,他引:1  
2005年6至9月,对桂林市郊区两个山洞中高颅鼠耳蝠(Myotissiligorensis)、菲菊头蝠(Rhinolo-phuspusillus)和黑髯墓蝠(Taphozousmelanopogon)的回声定位叫声特征和食性进行分析,并结合其形态特征与野外观察,推断其捕食生境和捕食策略。研究结果发现:黑髯墓蝠体型最大,声音特征属短调频型多谐波,一般为4个谐波,能量主要集中在第二谐波上,主频率为(32·84±1·17)kHz,选择鞘翅目和双翅目昆虫为主要食物;高颅鼠耳蝠(长调频型)和菲菊头蝠(长恒频-调频型),体型都较小,主频率分别是(84·44±8·13)kHz和(110·78±1·65)kHz,以双翅目昆虫为主要食物;而菲菊头蝠则以鞘翅目和双翅目昆虫为主要食物。上述结果证明,高颅鼠耳蝠、菲菊头蝠和黑髯墓蝠在声音和食物组成等方面出现了明显分化。  相似文献   

12.
朱旭  王静  孙克萍  江廷磊  姜云垒  冯江 《生态学报》2008,28(11):5248-5258
2007年在吉林省罗通山自然保护区,利用超声波探测仪(Avisoft-SASLAB PRO)录制并分析不同生境中马铁菊头蝠的回声定位声波。结果显示马铁菊头蝠在不同类型生境中活动;各生境中回声定位声波参数存在显著差异(one-way ANOVA,P〈0.05)。从环境因子中通过主成分分析筛选出与其回声定位声波相关的植被、气候和地形因子,探讨回声定位声波与这些因子的相关性。结果显示FM1和FM2带宽与乔木高(r=-0.948,-0.825;P〈0.05)、FM1起始频率和FM2终止频率与林冠面积(r=-0.967,-0.958;P〈0.05)、FM1起始频率、FM2终止频率和峰频与湿度(r=-0.776、-0.875和-0.794,P〈0.05)、脉冲持续时间和脉冲间隔与平均灌木高均呈显著负相关(r=-0.911,-0.990;P〈0.05),峰频与植被株数(r=0.756,P〈0.05)、脉冲持续时间与冠下高呈显著正相关(r=0.870,P〈0.05)。表明各种环境因子(植被因子、气候因子和地形因子)都在一定程度上影响回声定位声波,回声定位声波具有表型可塑性和生境适应性,这些特性决定了马铁菊头蝠生境利用的程度和可利用的资源。  相似文献   

13.
Zhu X  Wang J  Sun K P  Jiang T L  Jiang Y H  Feng J 《农业工程》2008,28(11):5248-5258
The present experiment was carried out in Luotong Mountain Natural Reserve in Jilin Province of China in 2007. We recorded and analyzed the echolocation calls of Rhinolophus ferrumequinum in different habitats by using Avisoft Bioacoustics USG 116 and Avisoft-SASLAB PRO (Avisoft Bioacoustics, Berlin, Germany). Our results showed that R. ferrumequinum foraged in diverse habitats in the study area, and their echolocation calls were significantly variable in different habitats (One-Way ANOVA, P < 0.05). Vegetative, climatic and topographical factors were selected by using the principal component analysis and the correlations between the parameters of echolocation calls and these environmental factors were analyzed. The results indicated that although R. ferrumequinum always emitted FM/CF/FM echolocation calls in different habitats, the parameters of echolocation calls varied with variable environmental factors. Significant negative correlation existed between FM1 bandwidth and arbor height (r = ?0.948, P < 0.05), FM2 bandwidth and arbor height (r = ?0.825; P < 0.05), FM1 starting frequency and canopy area (r = ?0.967, P < 0.05), FM2 ending frequency and canopy area (r = ?0.958, P < 0.05), FM1 starting frequency and air relative humidity (r = ?0.776, P < 0.05), FM2 ending frequency and air relative humidity (r = ?0.875, P < 0.05), peak frequency and air relative humidity (r = ?0.794, P < 0.05), pulse duration and average shrub height (r = ?0.911, P < 0.05), and inter-pulse interval and average shrub height (r = ?0.990, P < 0.05). Significant positive correlation existed between peak frequency and number of plants (r = 0.756, P < 0.05), and pulse duration and height below the canopy (r = 0.870, P < 0.05). Our results suggested that many kinds of ecological factors (such as vegetation factor, climatic factor and topographical factor) affected the structure of echolocation calls and made them diverse in different habitats, i.e., echolocation calls of bats had phenotypic flexibility and eco-adaptability. These characteristics determined the degree of available habitats and natural resources for R. ferrumequinum.  相似文献   

14.
ABSTRACT

The peculiar acoustic structure of ultrasonic bouts of blind climbing rodents Typhlomys might provide insight on their potential function. We examined 1481 bouts consisting of 1-6 pulses; 49.7% of them were single-pulse bouts. Bout duration and inter-bout interval depended on the number of pulses per bout, whereas period from start of a previous bout to start of the next bout was constant (80.0±2.9 ms). Ultrasonic pulses (540 pulses measured in a subset of 234 bouts) were short (0.68±0.15 ms) sweeps with fundamental frequency slopes from 127.3±6.3 kHz to 64.1±4.6 kHz and peak frequency at 93.3±7.4 kHz, emitted within bouts with inter-pulse periods of 13.03±3.01 ms. Single pulses and start pulses of multi-pulse bouts were lower in frequency than other pulses of the bouts. In contrast, pulse duration was independent on pulse position within bout. Pulses of Typhlomys were reminiscent of echolocation calls of Murina and Myotis bats, but higher in frequency, much shorter, fainter, displayed a convex contour of frequency modulation and only the fundamental frequency band without harmonics and were organized in bouts, that is not characteristic for bat echolocation. Most probably, Typhlomys uses their ultrasonic pulses for call-based orientation during locomotion, including climbing and jumping among bush branches.  相似文献   

15.
回声定位声波地理差异及其形成原因是蝙蝠生态学研究领域一个基本而关键的问题,对于探索物种生存机制、物种形成及其保护具有重要科学意义。本研究从较大地理尺度上(9个地理种群)研究了菲菊头蝠(Rhinolophus pusillus)回声定位声波结构的地理差异,并进一步探讨了影响回声定位声波地理种群差异的因素。结果表明,菲菊头蝠雌性的体型较雄性略大,其主频较高。不同地理种群之间回声定位声波差异明显,包括脉冲持续时间、脉冲间隔、主频以及带宽在不同的地理种群之间均表现出一定程度的差异。进一步分析发现,不同地理种群之间的雌性菲菊头蝠前臂长和体重均与主频呈较弱的负相关,降雨量与雌性的主频呈较强的正相关;而不同地理种群之间的雄性前臂长、体重和降雨量与回声定位声波参数均无相关性;此外,地理距离、温度、湿度均与雌雄回声定位声波参数无相关性。本研究结果表明,菲菊头蝠不同地理种群间的回声定位声波出现明显差异,其中,体型和降雨量为主要影响因子,说明蝙蝠回声定位叫声的进化主要受到了当地生境的影响,表现出动物对不同生境的适应性进化。  相似文献   

16.
2017年5月分别在贵州省兴义市和安龙县用雾网采集到1只大体型雌性管鼻蝠和2只小体型雄性菊头蝠,经鉴定为毛翼管鼻蝠(Harpiocephalus harpia)和华南菊头蝠(Rhinolophus huananus),属贵州省翼手目新分布记录。所采集的毛翼管鼻蝠雌性个体可能为怀孕个体,故测量相关数据并鉴定后原地放归野外。华南菊头蝠标本保存于东北师范大学环境学院。毛翼管鼻蝠(1♀):鼻部呈短管状,全身被毛厚密而柔软,后足、翼膜和尾膜均被覆黄褐色绒毛;体重14.01 g,前臂长48.23 mm;回声定位声波为调频(FM)型,静止状态下声波峰频为(56.04±4.52)k Hz。华南菊头蝠(2♂):耳大,对耳屏相对较小;鼻叶之蹄状叶宽大,完全覆盖吻部;鞍状叶小,其高略超过其宽,近乎矩形;体毛烟褐色;2只样本体重分别为4.52 g、4.12 g,前臂长40.70 mm、40.00 mm;头骨狭长,颅全长16.35 mm、16.46 mm,颅宽8.11 mm、8.14 mm;回声定位声波属调频-恒频-调频(FM-CF-FM)型,静止状态下峰频分别为(68.48±0.08)k Hz、(67.18±0.06)k Hz。2种蝙蝠物种在贵州省为首次发现,扩大了其在国内的分布范围,丰富了生态资料,为进一步的研究和保护提供了基础资料。  相似文献   

17.
The foraging and echolocation behaviour of Myotis evotis was investigated during substrate-gleaning and aerial-hawking attacks. Bats gleaned moths from both the ground and a bark-covered trellis, however, they were equally adept at capturing flying moths. The calls emitted by M. evotis during substrate-gleaning sequences were short, broadband, and frequency-modulated (FM). Three behavioural phases were identified: search, hover, and attack. Gleaning search calls were significantly longer in duration, lower in highest frequency, and larger in bandwidth than hover/attack calls. Calls were detected in only 68% of gleaning sequences, and when they were emitted, bats ceased calling 200 ms before attacking. Terminal feeding buzzes, the rapid increase in pulse repetition rate associated with an attempted prey capture, were never recorded during gleaning attacks. The echolocation calls uttered by M. evotis during aerial-hawking foraging sequences were also short duration, high frequency, FM calls. Two distinct acoustic phases were identified: approach and terminal. Approach calls were significantly different from terminal calls in all variables measured. Calls were detected in 100% of aerial-hawking attacks and terminal feeding buzzes were invariably produced. Gleaning hover/attack calls were spectrally similar to aerial approach calls, but were shorter in duration and emitted at a significantly lower (but constant) repetition rate than aerial signals. Although the foraging environment (flight cage contents) remained unchanged between tasks (substrate-gleaning vs. aerial-hawking), bats emitted significantly lower amplitude calls while gleaning. We conclude that M. evotis adjusts its echolocation behaviour to meet the perceptual demands (acoustical constraints) imposed by each foraging situations.Abbreviations BW bandwidth - CF constant frequency - dB SPL decibels sound pressure level - FM frequency modulated - HF highest frequency - LF lowest frequency - PF peak frequency Presented at the meeting Acoustic Images in Bat Sonar, a conference on FM echolocation honoring Donald R. Griffin's contributions to experimental biology (June 14–16, Brown University, Providence RI).  相似文献   

18.
1.  Most studies examining interactions between insectivorous bats and tympanate prey use the echolocation calls of aerially-feeding bats in their analyses. We examined the auditory responses of noctuid (Eurois astricta) and notodontid (Pheosia rimosa) moth to the echolocation call characteristics of a gleaning insectivorous bat, Myotis evotis.
2.  While gleaning, M. Evotis used short duration (mean ± SD = 0.66 ± 0.28 ms, Table 2), high frequency, FM calls (FM sweep = 80 – 37 kHz) of relatively low intensity (77.3 + 2.9, –4.2 dB SPL). Call peak frequency was 52.2 kHz with most of the energy above 50 kHz (Fig. 1).
3.  Echolocation was not required for prey detection or capture as calls were emitted during only 50% of hovers and 59% of attacks. When echolocation was used, bats ceased calling 324.7 (±200.4) ms before attacking (Fig. 2), probably using prey-generated sounds to locate fluttering moths. Mean call repetition rate during gleaning attacks was 21.7 (±15.5) calls/s and feeding buzzes were never recorded.
4.  Eurois astricta and P. rimosa are typical of most tympanate moths having ears with BFs between 20 and 40 kHz (Fig. 3); apparently tuned to the echolocation calls of aerially-feeding bats. The ears of both species respond poorly to the high frequency, short duration, faint stimuli representing the echolocation calls of gleaning M. evotis (Figs. 4–6).
5.  Our results demonstrate that tympanate moths, and potentially other nocturnal insects, are unable to detect the echolocation calls typical of gleaning bats and thus are particularly susceptible to predation.
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19.
Summary Bats of the speciesNoctilio albiventris emit short-constant frequency/frequency modulated (short-CF/FM) pulses with a CF component frequency at about 75 kHz. Bats sitting on a stationary platform were trained to discriminate target distance by means of echolocation. Loud, free-running artificial pulses, simulating the bat's natural CF/FM echolocation sounds or with systematic modifications in the frequency of the sounds, were presented to the bats during the discrimination trials. When the CF component of the artificial CF/FM sound was between 72 and 77 kHz, the bats shifted the frequency of the CF component of their own echolocation sounds toward that of the artificial pulse, tracking the frequency of the artificial CF component.Bats flying within a large laboratory flight cage were also presented with artificial pulses. Bats in flight lower the frequency of their emitted pulses to compensate for Doppler shifts caused by their own flight speed and systematically shift the frequency of their emitted CF component so that the echo CF frequency returns close to that of the CF component of the artificial CF/FM pulse, over the frequency range where tracking occurs.Abbreviations CF constant frequency - FM frequency modulation  相似文献   

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