Policht Richard, Kowalczyk Artur, Łukaszewicz Ewa, Hart Vlastimil
Department of Game Management and Wildlife Biology, Faculty of Forestry and Wood Sciences, Czech University of Life Sciences Prague, Praha, Czech Republic.
Division of Poultry Breeding, Institute of Animal Breeding, Wrocław University of Environmental and Life Sciences, Wroclaw, Poland.
PeerJ. 2020 Nov 24;8:e10197. doi: 10.7717/peerj.10197. eCollection 2020.
Non-vocal, or unvoiced, signals surprisingly have received very little attention until recently especially when compared to other acoustic signals. Some sounds made by terrestrial vertebrates are produced not only by the larynx but also by the syrinx. Furthermore, some birds are known to produce several types of non-syrinx sounds. Besides mechanical sounds produced by feathers, bills and/or wings, sounds can be also produced by constriction, anywhere along the pathway from the lungs to the lips or nostrils (in mammals), or to the bill (in birds), resulting in turbulent, aerodynamic sounds. These noises often emulate whispering, snorting or hissing. Even though hissing sounds have been studied in mammals and reptiles, only a few studies have analyzed hissing sounds in birds. Presently, only the hissing of small, nesting passerines as a defense against their respective predators have been studied. We studied hissing in domestic goose. This bird represents a ground nesting non-passerine bird which frequently produces hissing out of the nest in comparison to passerines producing hissing during nesting in holes e.g., parids. Compared to vocally produced alarm calls, almost nothing is known about how non-vocal hissing sounds potentially encode information about a caller's identity. Therefore, we aimed to test whether non-vocal air expirations can encode an individual's identity similar to those sounds generated by the syrinx or the larynx. We analyzed 217 hissing sounds from 22 individual geese. We calculated the Potential for Individual Coding (PIC) comparing the coefficient of variation both within and among individuals. In addition, we conducted a series of 15 a stepwise discriminant function analysis (DFA) models. All 16 acoustic variables showed a higher coefficient of variation among individuals. Twelve DFA models revealed 51.2-54.4% classification result (cross-validated output) and all 15 models showed 60.8-68.2% classification output based on conventional DFA in comparison to a 4.5% success rate when classification by chance. This indicates the stability of the DFA results even when using different combinations of variables. Our findings showed that an individual's identity could be encoded with respect to the energy distribution at the beginning of a signal and the lowest frequencies. Body weight did not influence an individual's sound expression. Recognition of hissing mates in dangerous situations could increase the probability of their surviving via a more efficient anti-predator response.
非发声信号,即无声信号,直到最近才受到极少的关注,尤其是与其他声学信号相比时。陆生脊椎动物发出的一些声音不仅由喉部产生,也由鸣管产生。此外,已知一些鸟类会发出几种非鸣管声音。除了由羽毛、喙和/或翅膀产生的机械声音外,在从肺部到嘴唇或鼻孔(在哺乳动物中)或到喙(在鸟类中)的任何部位,通过收缩也能产生声音,从而产生湍流、空气动力学声音。这些声音常模仿低语、喷气或嘶嘶声。尽管在哺乳动物和爬行动物中对嘶嘶声进行过研究,但只有少数研究分析过鸟类的嘶嘶声。目前,仅对小型筑巢雀形目鸟类作为防御其各自捕食者的嘶嘶声进行过研究。我们研究了家鹅的嘶嘶声。这种鸟是一种地面筑巢的非雀形目鸟类,与在洞穴中筑巢时发出嘶嘶声的雀形目鸟类(如雀科鸟类)相比,它经常在巢外发出嘶嘶声。与通过发声产生的警报叫声相比,对于非发声嘶嘶声如何潜在地编码有关发声者身份的信息,人们几乎一无所知。因此,我们旨在测试非发声呼气是否能像鸣管或喉部产生的声音那样编码个体身份。我们分析了来自22只个体家鹅的217个嘶嘶声。我们计算个体编码潜力(PIC),比较个体内部和个体之间的变异系数。此外,我们进行了一系列15个逐步判别函数分析(DFA)模型。所有16个声学变量在个体之间均显示出较高的变异系数。12个DFA模型显示出51.2 - 54.4%的分类结果(交叉验证输出),与随机分类时4.5%的成功率相比,所有15个模型基于传统DFA显示出60.8 - 68.2%的分类输出。这表明即使使用不同的变量组合,DFA结果仍具有稳定性。我们的研究结果表明,个体身份可以根据信号开始时的能量分布和最低频率进行编码。体重并不影响个体的声音表达。在危险情况下识别嘶嘶声的同伴可以通过更有效的反捕食反应提高它们存活的概率。
