拖网式食鱼蝠——大足鼠耳蝠的形态、回声定位声波及捕食策略

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。     

普氏蹄蝠(Hipposideros pratti)回声定位声波、形态及捕食策略

研究了普氏蹄蝠(Hipposideros pratti)不同状态(飞行、悬挂)下的回声定位声波特征、形态特征和生态特征(捕食策略、捕食地和食物类型).结果表明,普氏蹄蝠的回声定位声波为CFFM型,在不同状态下,主频率有一定的差异,飞行状态的主频率略低于悬挂状态,表明普氏蹄蝠是利用多谱勒补偿效应来适应飞行速度引起的主频率变化,以进行准确的定位和有效的捕食;同时飞行状态下声脉冲时间、声脉冲间隔时间及FM带宽略低于悬挂状态,而声脉冲重复率和能率环略高于悬挂状态,表明普氏蹄蝠在不同状态下利用不同特征的声波进行捕食.由回声定位声波推断和野外观察可知,普氏蹄蝠可能在树冠周围以盘旋方式(在昆虫高峰期)或以捕蝇器式(在昆虫高峰期之后)捕食中等偏大的振翅昆虫(如甲虫).     

形态和声波相似的中华菊头蝠与中菊头蝠的共存机制

研究了同域分布的中华菊头蝠(Rhinolophus sinicus)与中菊头蝠(Rhinolophus affinis)的食性、形态、回声定位声波及捕食时间.中华菊头蝠与中菊头蝠均属于中等体型的菊头蝠,前臂长分别为(51.25±0.22) mm和(52.40±0.37) mm;悬挂状态下的回声定位声波均为典型的调频-恒频-调频(FM-CM-FM)型叫声,峰频分别为(82.07±0.17) kHz和(84.41±0.48) kHz.粪便分析显示中华菊头蝠与中菊头蝠分别捕食9目和7目昆虫,均以鳞翅目(Lepidiptera)和鞘翅目(Coleoptera)昆虫为主要食物(体积百分比总和> 90%),捕食鳞翅目昆虫的体积百分比差异显著,对猎物大小(以鞘翅目昆虫体长衡量)的选择无显著差异.中华菊头蝠与中菊头蝠的营养生态位宽度分别为2.38和2.28,重叠度达0.91,营养生态位未发生明显分化,但充足的食物资源促进了二者的共存.另外,2种菊头蝠的感官生态位和时间生态位未发生明显分化.由2种菊头蝠的翼载和峰频的差异推测二者发生了空间生态位和捕食微生境的分化,这也可能促进了二者的共存.     

同地共栖四种蝙蝠食性和回声定位信号的差异及其生态位分化

本研究于 2 0 0 2年 5月初至 2 0 0 3年 9月中旬在北京房山区霞云岭四合村蝙蝠洞进行 ,分析了共栖同一山洞四种蝙蝠的形态特征、食性和回声定位信号。大足鼠耳蝠食谱中以宽鳍等三种鱼为主 (体积百分比为5 3% ) ,回声定位主频 4 1 87± 1 0 7kHz;马铁菊头蝠主要掠捕鳞翅目昆虫 (73% ) ,恒频叫声主频 74 70± 0 13kHz ;中华鼠耳蝠以近地面或在地表活动的鞘翅目昆虫步甲类和埋葬甲类为主要食物 (6 5 4 % ) ,声脉冲主频较低 35 73± 0 92kHz;白腹管鼻蝠捕食花萤总科和瓢虫科等鞘翅目昆虫 (90 % ) ,回声定位信号主频为 5 9 4 7±1 5 0kHz。结果证实同地共栖四种蝙蝠种属特异的回声定位叫声和形态结构的差异 ,以及不同的捕食生境和捕食策略 ,导致取食生态位分离是四种蝙蝠同地共栖的原因     

普通长翼蝠福建亚种不同行为状态下回声定位声波研究

普通长翼蝠福建亚种为中国的地方性亚种。采用超声波监听仪和Batsound3 10软件对其回声定位声波进行录制和分析,发现回声定位声波为中等长度的FM型,伴有1～2个谐波,声波主频率为49 35±4 24kHz,一次完整声波的声脉冲时间为3 46±1 63ms,两次声波间的声脉冲间隔为96 09±33 84ms。分析表明,普通长翼蝠福建亚种在飞行和手持状态下的回声定位声波声脉冲时间均小于其悬挂状态,飞行状态下声脉冲间隔时间是各种状态中较小的,而飞行状态下回声定位声波的主频率则为所有状态中最高的,说明蝙蝠在飞行中要面临复杂的环境,辨别较多的障碍物,因此利用高频率声波进行回声定位,才能实现灵活复杂的飞行。     

普氏蹄蝠(Hipposideros pratti)回声定位声波、形态及捕食策略

研究了普氏蹄蝠（Hipposideros pratti)不同状态（飞行,悬挂）下的回声定位声波特征,形态特征和生态特征（捕食策略,捕食地和食物类型）。结果表明,普氏蹄蝠的回声定位声波为CF－FM型,在不同状态下,主频率有一定的差异,飞行状态的主频率略低于悬挂状态,表明普氏蹄蝠是利用多谱勒补偿效应来适应飞行速度引起的主频率变化,以进行准确的定位和有效的捕食;同时飞行状态下声脉冲时间,声脉冲间隔时间及FM带宽略低于悬挂状态,而声脉冲重复率和能率环略主于悬挂状态,表明普氏蹄蝠在不同状态下利用不同特征的声波进行捕食,由回声定位声波推断和野外观察可知,普氏蹄蝠可能在树冠周围以盘旋方式（在昆虫高峰期）或以捕蝇器式（在昆虫高峰期这后）捕食中等偏大的振翅昆虫（如甲虫）。     

三种共栖蝙蝠的回声定位信号特征及其夏季食性的比较

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。     

同地共栖三种鼠耳蝠食性差异及其生态位分化

2005年9—11月在贵州省安龙县笃山乡暗河村,分析了共栖同一山洞3种鼠耳蝠的形态特征和食性。在体型上,华南水鼠耳蝠体重为(4.46±0.53)g,前臂长为(34.63±1.45)mm;毛腿鼠耳蝠体重为(5.15±1.76)g,前臂长为(35.20±1.07)mm;西南鼠耳蝠体重为(10.94±0.87)g,前臂长为(45.21±1.15)mm。3种鼠耳蝠的体重两两之间差异显著,西南鼠耳蝠与另外2种鼠耳蝠的前臂长相比两两之间差异显著。在食物组成上,华南水鼠耳蝠主要捕食近水面活动的双翅目及其幼虫,体积百分比和频次百分比分别为79.7%和100%;毛腿鼠耳蝠主要捕食双翅目和小型鞘翅目,体积百分比分别占59.6%和28.8%,频次百分比分别为91.3%和80.1%;西南鼠耳蝠的食物组成主要为近地面或在地表活动的鞘翅目步甲科和埋葬虫科昆虫,体积百分比和频次百分比分别为80.8%和100%;3种鼠耳蝠食物组成存在显著差异。结果表明,同地共栖3种鼠耳蝠除了形态结构上出现差异,食物组成也存在明显的差异。据此,推测3种鼠耳蝠可能采取不同的捕食生境和捕食策略,从而导致捕食生态位分离,避免出现激烈竞争,使得3种近缘鼠耳蝠能够同地共栖。     

两种鼠耳蝠回声定位叫声的比较

对鼠耳蝠属两种蝙蝠飞行状态下的声发射进行了比较研究.结果表明两种鼠耳蝠声发射信号的声谱图都呈调频(FM)型,但在波形及频率范围上有明显差异.大鼠耳蝠(四川亚种)的声脉冲宽度很小(1.6±0.3ms),能率环较低(4.0%),其主频率(DF=44.6±4.3kHz)也较低;而水鼠耳蝠的声脉冲宽度较大(4.2±1.6ms),能率环(9.6%)及主频率(DF=83.0±4.0kHz)也较高.文中结合两种蝙蝠的形态及食性分析了回声定位对捕食生境及捕食策略的适应性.     

皮氏菊头蝠夏季的捕食行为对策

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。     

日本伏翼的翼型、回声定位信号及出飞时间特征

对日本伏翼的翼型、回声定位信号及晚间出飞时间进行研究。结果表明,日本伏翼的翼型具有高翼载、低翼展比和中等偏高的翼型特征。日本伏翼发出具有1 - 2 个谐波结构的调频型(FM)回声定位信号叫声,其叫声时程、主频率的平均值分别为3.26 ms 和56. 27 kHz,所有叫声特征参数,个体间变异系数CVb 比个体内变 异系数CVw 大。日本伏翼的晚间出飞时间具有明显月变化,与当地日落时间、气温呈现显著相关。通过与文献比较,发现日本伏翼的回声定位信号特征与录音状态、飞行生境有关;此外,晚间出飞时间存在一定的地理差异。本研究结果将为蝙蝠回声定位信号特征的种属特异性及其生境选择的进一步研究提供有用的信息。     

大足鼠耳蝠的翼型和回声定位声波特征

大足鼠耳蝠(Myotis ricketti Thomas,1894)属翼手目(Chiroptera),蝙蝠科(Vespertilionidae),鼠耳蝠属(Myotis).     

大卫鼠耳蝠回声定位声波、翼型特征及夏季食性分析

2005 ～2009年,野外采集大卫鼠耳蝠(Myotis davidii)的回声定位声波、翼型数据及粪便样本,分析了其回声定位声波、翼型特征和夏季食性.结果表明,大卫鼠耳蝠回声定位声波主频为(60.4±10.0)kHz (Mean±SD),带宽为(54.7±8.5)kHz,能率环为7.4％±3.5％;翼展比为6.2±0...     

皮氏菊头蝠回声定位声波与年龄的关系

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。     

无尾蹄蝠的回声定位声波特征及分析

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Batsound3.0分析,其声波为高频(145.4±10.9kHz)、宽带(62.6±9.2kHz)、具两个谐波的短(1.67±0.4ms)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。     

Moth hearing in response to bat echolocation calls manipulated independently in time and frequency

We measured the auditory responses of the noctuid moth Noctua pronuba to bat echolocation calls which were manipulated independently in time and frequency. Such manipulations are important in understanding how insect hearing influences the evolution of echolocation call characteristics. We manipulated the calls of three bat species (Rhinolophus hipposideros, Myotis nattereri and Pipistrellus pipistrellus) that use different echolocation call features by doubling their duration or reducing their frequency, and measured the auditory thresholds from the A1 cells of the moths. Knowing the auditory responses of the moth we tested three predictions. (i) The ranking of the audibility of unmanipulated calls to the moths should be predictable from their temporal and/or frequency structure. This was supported. (ii) Doubling the duration of the calls should increase their audibility by ca. 3 dB for all species. Their audibility did indeed increase by 2.1-3.5 dB. (iii) Reducing the frequency of the calls would increase their audibility for all species. Reducing the frequency had small effects for the two bat species which used short duration (2.7-3.6 ms) calls. However, the relatively long-duration (50 ms), largely constant-frequency calls of R. hipposideros increased in audibility by 21.6 dB when their frequency was halved. Time and frequency changes influence the audibility of calls to tympanate moths in different ways according to call design. Large changes in frequency and time had relatively small changes on the audibility of calls for short, largely broadband calls. Channelling energy into the second harmonic of the call substantially decreased the audibility of calls for bats which use long-duration, constant-frequency components in echolocation calls. We discuss our findings in the contexts of the evolution of both bat echolocation call design and the potential responses of insects which hear ultrasound.     

Morphology, echolocation and foraging behaviour in two sympatric sibling species of bat (Tylonycteris pachypus and Tylonycteris robustula) (Chiroptera: Vespertilionidae)

We studied the wing morphology, echolocation calls, foraging behaviour and flight speed of Tylonycteris pachypus and Tylonycteris robustula in Longzhou County, South China during the summer (June–August) of 2005. The wingspan, wing loading and aspect ratio of the two species were relatively low, and those of T. pachypus were lower compared with T. robustula . The echolocation calls of T. pachypus and T. robustula consist of a broadband frequency modulated (FM) sweep followed by a short narrowband FM sweep. The dominant frequency of calls of T. pachypus was 65.1 kHz, whereas that of T. robustula was 57.7 kHz. The call frequencies (including highest frequency of the call, lowest frequency of the call and frequency of the call that contained most energy) of T. pachypus were higher than those of T. robustula , and the pulse duration of the former was longer than that of the latter. The inter-pulse interval and bandwidth of the calls were not significantly different between the two species. Tylonycteris pachypus foraged in more complex environments than T. robustula , although the two species were both netted in edge habitats (around trees or houses), along pathways and in the tops of trees. Tylonycteris pachypus flew slower (straight level flight speed, 4.3 m s⁻¹) than T. robustula (straight level flight speed, 4.8 m s⁻¹). We discuss the relationship between wing morphology, echolocation calls, foraging behaviour and flight speed, and demonstrate resource partitioning between these two species in terms of morphological and behavioural factors.     

Substrate-gleaning versus aerial-hawking: plasticity in the foraging and echolocation behaviour of the long-eared bat,Myotis evotis

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).     

Rediscovery of short-tailed bats (

Short-tailed bats (Mystacina sp.) were rediscovered in Nothofagus dominant rainforest in the Eglinton Valley in February 1997, representing the first records of these bats in Fiordland since 1871. Breeding females, adult males and juveniles were captured. This paper presents preliminary observations of taxonomy, echolocation calls, population size, habitat use, activity patterns, home range size, movements, roosting, and singing behaviour. Compared to lesser short- tailed bats (M. tuberculata) on Codfish and Little Barrier Islands, the Fiordland bats were heavier, had larger wings and smaller ears, and were sexually dimorphic. The Mystacina echolocation calls were of low intensity (quiet), making them difficult to detect. Call durations in free-flying bats were only 1.0-2.9 ms long. In a comparative trial the majority of calls that were detected at 25 kHz using the Batbox III bat detector were not recorded at 40 kHz, indicating that there was little overlap with the calls of long-tailed bats (Chalinolobus tuberculatus). In February, roosting groups numbered from 107 to 279 individuals and the bats ranged over 130 km(2) of the valley. Bats began emerging c. 20 minutes after sunset and were active at the roost sites throughout the night. Radio-tagged bats were active for an average of 372 minutes at a time. All roosts were in large diameter (67-146 cm dbh) red beech (N. fusca) trees.