生物多样性 >

2023 , Vol. 31 >Issue 1: 22359

DOI: https://doi.org/10.17520/biods.2022359

中国野生脊椎动物鸣声监测与生物声学研究专题

城市绿地动物声景的时空特征及其驱动因素

  • 岑渝华 ,
  • 王鹏 ,
  • 陈庆春 ,
  • 张承云 ,
  • 余上 ,
  • 胡珂 ,
  • 刘阳 ,
  • 肖荣波
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  • 1.广东工业大学环境科学与工程学院, 广州 510006
    2.广州大学电子与通信工程学院, 广州 510006
    3.广州灵感生态科技有限公司, 广州 510630
    4.中山大学生态学院, 广州 510006

收稿日期: 2022-06-29

  录用日期: 2022-10-14

  网络出版日期: 2022-11-10

基金资助

国家重点研发计划(2022YFF1303104);广东省重点领域研发计划(2020B1111370001)

收起

Spatiotemporal characteristics and influencing factors of animal soundscape in urban green spaces

  • Yuhua Cen ,
  • Peng Wang ,
  • Qingchun Chen ,
  • Chengyun Zhang ,
  • Shang Yu ,
  • Ke Hu ,
  • Yang Liu ,
  • Rongbo Xiao
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  • 1. School of Environmental Science and Engineering, Guangdong University of Technology, Guangzhou 510006
    2. School of Electronics and Communication Engineering, Guangzhou University, Guangzhou 510006
    3. Guangzhou Naturesense Ecological Technology Co., Guangzhou 510630
    4. School of Ecology, Sun Yat-sen University, Guangzhou 510006

Received date: 2022-06-29

  Accepted date: 2022-10-14

  Online published: 2022-11-10

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摘要

动物群落是构成城市绿地生态系统的关键要素, 声景作为野生动物重要的生态信息, 掌握其时空变化及其影响因素, 对于指导城市绿地景观设计与生物多样性保护具有重要意义。本文以Web of Science数据库的核心合集2005-2022年收录的67篇研究文献为对象, 综合梳理与分析了城市绿地动物声景的时空模式及其驱动因素。城市绿地动物声景在空间上表现出环境空间梯度和植被空间结构的差异, 动物声音多样性随海拔、纬度、城市化程度的降低以及植被类型和高度的增加呈现升高趋势。时间尺度呈现出昼夜、季节和年度变化差异, 表现为鸟类在黎明和黄昏合唱、昆虫和两栖动物在夜间鸣叫以及季节性和年度性发声规律等。影响城市动物声景模式的因素主要包括植被、环境、人为干扰和动物自身驱动等。动物声景作为当前声景生态学研究的热点之一, 面临大时空尺度演变规律研究不足、动物声景分析有限等挑战, 建议未来着重开展多时空尺度变化规律研究、创新动物声景分析方法、定量解析影响因素及其响应机制、建立全球动物声景数据库等。

关键词: 声景生态学; 城市绿地; 动物声景; 时空特征; 影响因素

本文引用格式

岑渝华 , 王鹏 , 陈庆春 , 张承云 , 余上 , 胡珂 , 刘阳 , 肖荣波 . 城市绿地动物声景的时空特征及其驱动因素[J]. 生物多样性, 2023 , 31(1) : 22359 . DOI: 10.17520/biods.2022359

Abstract

Background & Aims: The animal community is a key element constituting the urban green-space ecosystem. As an important ecological component of wild animal communities, the soundscape is of great significance in guiding urban green-space landscape design and biodiversity conservation measures. This paper examined 67 articles from the core collection of Web of Science published between 2005 and 2022 to comprehensively analyze the spatiotemporal patterns of and influences on animal soundscapes in urban green spaces.

Findings: The animal soundscape of urban green space was influenced by environmental-spatial gradients and vegetation spatial structure. Animal sound diversity was inversely correlated with altitude, latitude, urbanization degree, and was also related to vegetation type and height. Phenology of the urban soundscape also showed diurnal, seasonal, and annual variation, including characteristics such as dawn and dusk avian choruses, insect and amphibians nocturnal choruses, and other aspects of animals’ seasonal and annual vocalization patterns. The factors that affect the urban animal soundscape thus include mainly vegetation, environment, anthropogenic interference, and self-driving of animals.

Prospects: Despite being one of the hotspots of current soundscape ecology research, animal soundscape research faces challenges such as insufficient investigation of large spatiotemporal scales. Promising directions for future research include the quantitative analysis of influential factors and their response mechanisms as well as the establishment of a global animal soundscape database.

Key words: soundscape ecology; urban green space; animal soundscape; spatiotemporal characteristics; influencing factor

参考文献

[1] Alquezar RD, Macedo RH, Sierro J, Gil D (2020) Lack of consistent responses to aircraft noise in dawn song timing of bird populations near tropical airports. Behavioral Ecology and Sociobiology, 74, 88.
[2] Amrhein V, Erne N (2006) Dawn singing reflects past territorial challenges in the winter wren. Animal Behaviour, 71, 1075-1080.
[3] Barber JR, Crooks KR, Fristrup KM (2010) The costs of chronic noise exposure for terrestrial organisms. Trends in Ecology & Evolution, 25, 180-189.
[4] Benocci R, Roman HE, Bisceglie A, Angelini F, Brambilla G, Zambon G (2021) Eco-acoustic assessment of an urban park by statistical analysis. Sustainability, 13, 7857.
[5] Benocci R, Roman HE, Bisceglie A, Angelini F, Brambilla G, Zambon G (2022) Auto-correlations and long time memory of environment sound: The case of an urban park in the city of Milan (Italy). Ecological Indicators, 134, 108492.
[6] Berg KS, Brumfield RT, Apanius V (2006) Phylogenetic and ecological determinants of the neotropical dawn chorus. Proceedings of the Royal Society B: Biological Sciences, 273, 999-1005.
[7] Bian Q, Wang C, Hao ZZ (2021) Application of ecoacoustic monitoring in the field of biodiversity science. Chinese Journal of Applied Ecology, 32, 1119-1128. (in Chinese with English abstract)
[7] [边琦, 王成, 郝泽周 (2021) 生物声音监测研究在生物多样性领域的应用. 应用生态学报, 32, 1119-1128.]
[8] Bradfer-Lawrence T, Bunnefeld N, Gardner N, Willis SG, Dent DH (2020) Rapid assessment of avian species richness and abundance using acoustic indices. Ecological Indicators, 115, 106400.
[9] Buckley EMB, Gottesman BL, Caven AJ, Harner MJ, Pijanowski BC (2021) Assessing ecological and environmental influences on boreal chorus frog (Pseudacris maculata) spring calling phenology using multimodal passive monitoring technologies. Ecological Indicators, 121, 107171.
[10] Budka M, Skierczyńska A, Antczak M, Osiejuk TS (2021) Nocturnal singing by diurnal birds in Afrotropical highlands. Journal of Ornithology, 162, 435-445.
[11] Burivalova Z, Purnomo, Wahyudi B, Boucher TM, Ellis P, Truskinger A, Towsey M, Roe P, Marthinus D, Griscom B, Game ET (2019) Using soundscapes to investigate homogenization of tropical forest diversity in selectively logged forests. Journal of Applied Ecology, 56, 2493-2504.
[12] Burivalova Z, Towsey M, Boucher T, Truskinger A, Apelis C, Roe P, Game ET (2018) Using soundscapes to detect variable degrees of human influence on tropical forests in Papua New Guinea. Conservation Biology, 32, 205-215.
[13] Buxton RT, Brown E, Sharman L, Gabriele CM, McKenna MF (2016) Using bioacoustics to examine shifts in songbird phenology. Ecology and Evolution, 6, 4697-4710.
[14] Chen YF, Luo YH, Mammides C, Cao KF, Zhu SD, Goodale E (2021) The relationship between acoustic indices, elevation, and vegetation, in a forest plot network of southern China. Ecological Indicators, 129, 107942.
[15] Colino-Rabanal VJ, Mendes S, Peris SJ, Pescador M (2016) Does the song of the Wren Troglodytes troglodytes change with different environmental sounds? Acta Ornithologica, 51, 13-22.
[16] Da Silva A, Samplonius JM, Schlicht E, Valcu M, Kempenaers B (2014) Artificial night lighting rather than traffic noise affects the daily timing of dawn and dusk singing in common European songbirds. Behavioral Ecology, 25, 1037-1047.
[17] de Andrade AC, Medeiros S, Chiarello AG (2020) City sloths and marmosets in Atlantic forest fragments with contrasting levels of anthropogenic disturbance. Mammal Research, 65, 481-491.
[18] de Camargo U, Roslin T, Ovaskainen O (2019) Spatio-temporal scaling of biodiversity in acoustic tropical bird communities. Ecography, 42, 1936-1947.
[19] Deoniziak K, Osiejuk TS (2021) Seasonality and social factors, but not noise pollution, influence the song characteristics of two leaf warbler species. PLoS ONE, 16, e0257074.
[20] Derryberry EP, Danner RM, Danner JE, Derryberry GE, Phillips JN, Lipshutz SE, Gentry K, Luther DA (2016) Patterns of song across natural and anthropogenic soundscapes suggest that white-crowned sparrows minimize acoustic masking and maximize signal content. PLoS ONE, 11, e0154456.
[21] Diepstraten J, Willie J (2021) Assessing the structure and drivers of biological sounds along a disturbance gradient. Global Ecology and Conservation, 31, e01819.
[22] Dominoni DM (2015) The effects of light pollution on biological rhythms of birds: An integrated, mechanistic perspective. Journal of Ornithology, 156, 409-418.
[23] Doser JW, Finley AO, Kasten EP, Gage SH (2020) Assessing soundscape disturbance through hierarchical models and acoustic indices: A case study on a shelterwood logged northern Michigan forest. Ecological Indicators, 113, 106244.
[24] Dr?ge S, Martin DA, Andriafanomezantsoa R, Burivalova Z, Fulgence TR, Osen K, Rakotomalala E, Schwab D, Wurz A, Richter T, Kreft H (2021) Listening to a changing landscape: Acoustic indices reflect bird species richness and plot-scale vegetation structure across different land-use types in north-eastern Madagascar. Ecological Indicators, 120, 106929.
[25] Duarte MHL, Sousa-Lima RS, Young RJ, Farina A, Vasconcelos M, Rodrigues M, Pieretti N (2015) The impact of noise from open-cast mining on Atlantic forest biophony. Biological Conservation, 191, 623-631.
[26] Duarte MHL, Sousa-Lima RS, Young RJ, Vasconcelos MF, Bittencourt E, Scarpelli MDA, Farina A, Pieretti N (2021) Changes on soundscapes reveal impacts of wildfires in the fauna of a Brazilian savanna. Science of the Total Environment, 769, 144988.
[27] Eldridge A, Guyot P, Moscoso P, Johnston A, Eyre-Walker Y, Peck M (2018) Sounding out ecoacoustic metrics: Avian species richness is predicted by acoustic indices in temperate but not tropical habitats. Ecological Indicators, 95, 939-952.
[28] Farina A, Lattanzi E, Malavasi R, Pieretti N, Piccioli L (2011) Avian soundscapes and cognitive landscapes: Theory, application and ecological perspectives. Landscape Ecology, 26, 1257-1267.
[29] Farina A, Pieretti N (2014) Sonic environment and vegetation structure: A methodological approach for a soundscape analysis of a Mediterranean maqui. Ecological Informatics, 21, 120-132.
[30] Francomano D, Valenzuela AEJ, Gottesman BL, González- Calderón A, Anderson CB, Hardiman BS, Pijanowski BC (2021) Acoustic monitoring shows invasive beavers Castor canadensis increase patch-level avian diversity in Tierra del Fuego. Journal of Applied Ecology, 58, 2987-2998.
[31] Gage SH, Axel AC (2014) Visualization of temporal change in soundscape power of a Michigan lake habitat over a 4-year period. Ecological Informatics, 21, 100-109.
[32] Gage SH, Wimmer J, Tarrant T, Grace PR (2017) Acoustic patterns at the Samford ecological research facility in South East Queensland, Australia: The Peri-Urban SuperSite of the Terrestrial Ecosystem Research Network. Ecological Informatics, 38, 62-75.
[33] Gallo T, Fidino M, Lehrer EW, Magle SB (2017) Mammal diversity and metacommunity dynamics in urban green spaces: Implications for urban wildlife conservation. Ecological Applications, 27, 2330-2341.
[34] Gasc A, Anso J, Sueur J, Jourdan H, Desutter-Grandcolas L (2018) Cricket calling communities as an indicator of the invasive ant Wasmannia auropunctata in an insular biodiversity hotspot. Biological Invasions, 20, 1099-1111.
[35] Gibson M, Maron M, Taws N, Simmonds JS, Walsh JC (2021) Use of citizen science datasets to test effects of grazing exclusion and replanting on Australian woodland birds. Restoration Ecology, 30, e13610.
[36] Gottesman BL, Olson JC, Yang S, Acevedo-Charry O, Francomano D, Martinez FA, Appeldoorn RS, Mason DM, Weil E, Pijanowski BC (2021) What does resilience sound like? Coral reef and dry forest acoustic communities respond differently to Hurricane Maria. Ecological Indicators, 126, 107635.
[37] Grabarczyk EE, Gill SA (2019) Anthropogenic noise affects male house wren response to but not detection of territorial intruders. PLoS ONE, 14, e0220576.
[38] Grabarczyk EE, Gill SA (2020) Anthropogenic noise masking diminishes house wren (Troglodytes aedon) song transmission in urban natural areas. Bioacoustics, 29, 518-532.
[39] Grinfeder E, Haupert S, Ducrettet M, Barlet J, Reynet MP, Sèbe F, Sueur J (2022) Soundscape dynamics of a cold protected forest: Dominance of aircraft noise. Landscape Ecology, 37, 567-582.
[40] Guo FY, Bonebrake TC, Dingle C (2016) Low frequency dove coos vary across noise gradients in an urbanized environment. Behavioural Processes, 129, 86-93.
[41] Hao YY, Kang J, Krijnders JD (2015) Integrated effects of urban morphology on birdsong loudness and visibility of green areas. Landscape and Urban Planning, 137, 149-162.
[42] Hao ZZ, Wang C, Sun ZK, Zhao DX, Sun BQ, Wang HJ, van den Bosch CK (2021) Vegetation structure and temporality influence the dominance, diversity, and composition of forest acoustic communities. Forest Ecology and Management, 482, 118871.
[43] Haq SMA (2011) Urban green spaces and an integrative approach to sustainable environment. Journal of Environmental Protection, 2, 601-608.
[44] Hedblom M, Knez I, Sang ?O, Gunnarsson B (2017) Evaluation of natural sounds in urban greenery: Potential impact for urban nature preservation. Royal Society Open Science, 4, 170037.
[45] Hensley CB, Trisos CH, Warren PS, MacFarland J, Blumenshine S, Reece J, Katti M (2019) Effects of urbanization on native bird species in three southwestern US cities. Frontiers in Ecology and Evolution, 7, 71.
[46] Herrera-Montes MI (2018) Protected area zoning as a strategy to preserve natural soundscapes, reduce anthropogenic noise intrusion, and conserve biodiversity. Tropical Conservation Science, 11, 194008291880434.
[47] Hopson A, de Szalay F (2021) Alteration of above and below-water soundscapes by roads. Wetlands, 41, 2.
[48] Izaguirre MR, Barrantes-Madrigal J, Sequeira DS, Spínola-Parallada M, Ramírez-Alán O (2021) It is not just about birds: What do acoustic indices reveal about a Costa Rican tropical rainforest? Neotropical Biodiverity, 7, 431-442.
[49] Jahani A, Kalantary S, Alitavoli A, Li SN (2022) An application of artificial intelligence techniques in prediction of bird soundscape impact on tourists’ mental restoration in natural urban areas. Urban Planning Forum, (1), 126. (in Chinese)
[49] [ Jahani A, Kalantary S, Alitavoli A, 李胜男 (2022) 人工智能技术在预测城市自然地区鸟类声景对游客心理恢复的影响中的应用. 城市规划学刊, (1), 126.]
[50] Jahn O, Ganchev TD, Marques MI, Schuchmann KL (2017) Automated sound recognition provides insights into the behavioral ecology of a tropical bird. PLoS ONE, 12, e0169041.
[51] Jord?o JM, Fonseca PJ, Amorim MCP (2012) Chorusing behaviour in the lusitanian toadfish: Should I match my neighbours’ calling rate? Ethology, 118, 885-895.
[52] Khanaposhtani MG, Gasc A, Francomano D, Villanueva-Rivera LJ, Jung JH, Mossman MJ, Pijanowski BC (2019) Effects of highways on bird distribution and soundscape diversity around Aldo Leopold’s shack in Baraboo, Wisconsin, USA. Landscape and Urban Planning, 192, 103666.
[53] Kight CR, Swaddle JP (2015) Eastern bluebirds alter their song in response to anthropogenic changes in the acoustic environment. Integrative and Comparative Biology, 55, 418-431.
[54] Kirschel ANG, Blumstein DT, Cohen RE, Buermann W, Smith TB, Slabbekoorn H (2009) Birdsong tuned to the environment: Green hylia song varies with elevation, tree cover, and noise. Behavioral Ecology, 20, 1089-1095.
[55] Kong F, Nakagoshi N (2006) Spatial-temporal gradient analysis of urban green spaces in Jinan, China. Landscape and Urban Planning, 78, 147-164.
[56] Krause B, Farina A (2016) Using ecoacoustic methods to survey the impacts of climate change on biodiversity. Biological Conservation, 195, 245-254.
[57] Ku?aga K, Budka M (2020) Nocturnal singing by diurnal birds in a temperate region of central Europe. Journal of Ornithology, 161, 1143-1152.
[58] Laverne RJ, Kellogg WA (2019) Loss of urban forest canopy and the effects on neighborhood soundscapes. Urban Ecosystems, 22, 249-270.
[59] LaZerte SE, Otter KA, Slabbekoorn H (2015) Relative effects of ambient noise and habitat openness on signal transfer for chickadee vocalizations in rural and urban green-spaces. Bioacoustics, 24, 233-252.
[60] Li H, Xie H, Woodward G (2021) Soundscape components, perceptions, and EEG reactions in typical mountainous urban parks. Urban Forestry & Urban Greening, 64, 127269.
[61] Lin TH, Tsao Y, Wang YH, Yen HW, Lu SS (2017) Computing biodiversity change via a soundscape monitoring network. In:Proceedings of the 2017 Pacific Neighborhood Consortium Annual Conference and Joint Meetings (PNG), pp. 128-133. IEEE, Taipei, China.
[62] Liu J, Kang J, Luo T, Behm H, Coppack T (2013) Spatiotemporal variability of soundscapes in a multiple functional urban area. Landscape and Urban Planning, 115, 1-9.
[63] Liu J, Wang YJ, Zimmer C, Kang J, Yu TH (2019) Factors associated with soundscape experiences in urban green spaces: A case study in Rostock, Germany. Urban Forestry & Urban Greening, 37, 135-146.
[64] Marín-Gómez OH, MacGregor-Fors I (2019) How early do birds start chirping? Dawn chorus onset and peak time in a neotropical city. Ardeola, 66, 327-341.
[65] Marín-Gómez OH, MacGregor-Fors I (2021) A global synthesis of the impacts of urbanization on bird dawn choruses. Ibis, 163, 1133-1154.
[66] Morrison CA, Auni?? A, Benk? Z, Brotons L, Chodkiewicz T, Chylarecki P, Escandell V, Eskildsen DP, Gamero A, Herrando S, Jiguet F, K?l?s JA, Kamp J, Klvaňová A, Kmecl P, Lehikoinen A, Lindstr?m ?, Mosh?j C, Noble DG, ?ien IJ, Paquet JY, Reif J, Sattler T, Seaman BS, Teufelbauer N, Trautmann S, Vo?i?ek P, Butler SJ (2021) Bird population declines and species turnover are changing the acoustic properties of spring soundscapes. Nature Communications, 12, 6217.
[67] Müller S, Mitesser O, Oschwald L, Scherer-Lorenzen M, Potvin C (2022) Temporal soundscape patterns in a Panamanian tree diversity experiment: Polycultures show an increase in high frequency cover. Frontiers in Ecology and Evolution, 10, 808589.
[68] Mullet TC, Gage SH, Morton JM, Huettmann F (2016) Temporal and spatial variation of a winter soundscape in south-central Alaska. Landscape Ecology, 31, 1117-1137.
[69] Nava-Díaz R, Pineda-López R, Dorantes-Euan A (2020) Drivers of functional composition of bird assemblages in green spaces of a neotropical city: A case study from Merida, Mexico. Tropical Conservation Science, 13, 1940082920923896.
[70] Nawar N, Sorker R, Chowdhury FJ, Mostafizur Rahman M (2022) Present status and historical changes of urban green space in Dhaka City, Bangladesh: A remote sensing driven approach. Environmental Challenges, 6, 100425.
[71] Oliveira EG, Ribeiro MC, Roe P, Sousa-Lima RS (2021) The Caatinga Orchestra: Acoustic indices track temporal changes in a seasonally dry tropical forest. Ecological Indicators, 129, 107897.
[72] Parsons MJG, Lin TH, Mooney TA, Erbe C, Juanes F, Lammers M, Li SH, Linke S, Looby A, Nedelec SL, Van Opzeeland I, Radford C, Rice AN, Sayigh L, Stanley J, Urban E, Di Iorio L (2022) Sounding the call for a global Llibrary of underwater biological sounds. Frontiers in Ecology and Evolution, 10, 810156.
[73] Pieretti N, Duarte MHL, Sousa-Lima RS, Rodrigues M, Young RJ, Farina A (2015) Determining temporal sampling schemes for passive acoustic studies in different tropical ecosystems. Tropical Conservation Science, 8, 215-234.
[74] Pijanowski BC, Farina A, Gage SH, Dumyahn SL, Krause BL (2011a) What is soundscape ecology? An introduction and overview of an emerging new science. Landscape Ecology, 26, 1213-1232.
[75] Pijanowski BC, Villanueva-Rivera LJ, Dumyahn SL, Farina A, Krause BL, Napoletano BM, Gage SH, Pieretti N (2011b) Soundscape ecology: The science of sound in the landscape. BioScience, 61, 203-216.
[76] Proppe DS, Sturdy CB, St Clair CC (2013) Anthropogenic noise decreases urban songbird diversity and may contribute to homogenization. Global Change Biology, 19, 1075-1084.
[77] Puswal SM, Mei JJ, Liu FL (2021) Effects of temperature and season on birds’ dawn singing behavior in a forest of eastern China. Journal of Ornithology, 162, 447-459.
[78] Quiroz-Oliva M, Sosa-López JR (2022) Vocal behaviour of Sclater’s wrens, a duetting Neotropical songbird: Repertoires, dawn chorus variation, and song sharing. Journal of Ornithology, 163, 121-136.
[79] Retamosa Izaguirre MI, Segura Sequeira D, Barrantes Madrigal J, Spínola Parallada M, Ramírez Alán O (2021) Vegetation, bird and soundscape characterization: A case study in Braulio Carrillo National Park, Costa Rica. Biota Colombiana, 22, 57-73.
[80] Robert A, Lengagne T, Melo M, Gardette V, Julien S, Covas R, Gomez D, Doutrelant C (2019) The theory of island biogeography and soundscapes: Species diversity and the organization of acoustic communities. Journal of Biogeography, 46, 1901-1911.
[81] Rodriguez A, Gasc A, Pavoine S, Grandcolas P, Gaucher P, Sueur J (2014) Temporal and spatial variability of animal sound within a neotropical forest. Ecological Informatics, 21, 133-143.
[82] Ross S, Friedman NR, Dudley KL, Yoshimura M, Yoshida T, Economo EP (2018) Listening to ecosystems: Data-rich acoustic monitoring through landscape-scale sensor networks. Ecological Research, 33, 135-147.
[83] Scarpelli MDA, Ribeiro MC, Teixeira CP (2021) What does Atlantic forest soundscapes can tell us about landscape? Ecological Indicators, 121, 107050.
[84] Schafer RM (1993) The Soundscape: Our Sonic Environment and the Tuning of the World. Destiny Books, Rochester.
[85] Schlicht L, Kempenaers B (2020) The effects of season, sex, age and weather on population-level variation in the timing of activity in Eurasian Blue Tits Cyanistes caeruleus. Ibis, 162, 1146-1162.
[86] Sikuzani YU, Kouagou RS, Maréchal J, Ilunga EIW, Malaisse F, Bogaert J, Kankumbi FM (2018) Changes in the spatial pattern and ecological functionalities of green spaces in Lubumbashi (the Democratic Republic of Congo) in relation with the degree of urbanization. Tropical Conservation Science, 11, 1940082918771325.
[87] Straka TM, Wolf M, Gras P, Buchholz S, Voigt CC (2019) Tree cover mediates the effect of artificial light on urban bats. Frontiers in Ecology and Evolution, 7, 91.
[88] Suarez-Rubio M, Ille C, Bruckner A (2018) Insectivorous bats respond to vegetation complexity in urban green spaces. Ecology and Evolution, 8, 3240-3253.
[89] Suhonen J, Jokim?ki J (2019) Temporally stable species occupancy frequency distribution and abundance-occupancy relationship patterns in urban wintering bird assemblages. Frontiers in Ecology and Evolution, 7, 129.
[90] Tan MK (2021) Soundscape of urban-tolerant crickets (Orthoptera: Gryllidae, Trigonidiidae) in a tropical Southeast Asia city, Singapore. Bioacoustics, 30, 469-486.
[91] Tennessen JB, Parks SE, Langkilde T (2014) Traffic noise causes physiological stress and impairs breeding migration behaviour in frogs. Conservation Physiology, 2, cou032.
[92] To AWY, Dingle C, Collins SA (2021) Multiple constraints on urban bird communication: Both abiotic and biotic noise shape songs in cities. Behavioral Ecology, 32, 1042-1053.
[93] Turner A, Fischer M, Tzanopoulos J (2018) Sound-mapping a coniferous forest—Perspectives for biodiversity monitoring and noise mitigation. PLoS ONE, 13, e0189843.
[94] Ulloa JS, Gasc A, Gaucher P, Aubin T, Rejou-Mechain M, Sueur J (2016) Screening large audio datasets to determine the time and space distribution of screaming piha birds in a tropical forest. Ecological Informatics, 31, 91-99.
[95] Van Duyse E, Pinxten R, Snoeijs T, Eens M (2005) Simultaneous treatment with an aromatase inhibitor and an anti-androgen decreases the likelihood of dawn song in free-living male great tits, Parus major. Hormones and Behavior, 48, 243-251.
[96] van Niekerk JH, Forcina G (2020) Purpose of crested Francolin Ortygornis sephaena male collective calls at dusk based on livestream audio censusing. Ostrich, 91, 326-337.
[97] Vieira J, Matos P, Mexia T, Silva P, Lopes N, Freitas C, Correia O, Santos-Reis M, Branquinho C, Pinho P (2018) Green spaces are not all the same for the provision of air purification and climate regulation services: The case of urban parks. Environmental Research, 160, 306-313.
[98] Villanueva-Rivera LJ, Pijanowski BC, Doucette J, Pekin B (2011) A primer of acoustic analysis for landscape ecologists. Landscape Ecology, 26, 1233-1246.
[99] Xie J, Towsey M, Zhang J, Roe P (2016) Acoustic classification of Australian frogs based on enhanced features and machine learning algorithms. Applied Acoustics, 113, 193-201.
[100] Xie S, Marzluff JM, Su Y, Wang Y, Meng N, Wu T, Gong C, Lu F, Xian C, Zhang Y, Ouyang Z (2022) The role of urban waterbodies in maintaining bird species diversity within built area of Beijing. Science of the Total Environment, 806, 150430.
[101] Zhan X, Liang D, Lin X, Li LG, Wei CT, Dingle C, Liu Y (2021) Background noise but not urbanization level impacted song frequencies in an urban songbird in the Pearl River Delta, Southern China. Global Ecology and Conservation, 28, e01695.
[102] Zhang Y, Huang TT, Hu Q, Zhu JN (2022) Analysis on the habitat design strategy of community park based on the improvement of bird diversity. Chinese Landscape Architecture, 38(3), 106-111. (in Chinese with English abstract)
[102] [张颖, 黄婷婷, 胡骞, 朱建宁 (2022) 基于鸟类多样性提升的社区公园生境营造策略探析. 中国园林, 38(3), 106-111.]
[103] Zhang YJ, Murray AT, Turner BL (2017) Optimizing green space locations to reduce daytime and nighttime urban heat island effects in Phoenix, Arizona. Landscape and Urban Planning, 165, 162-171.
[104] Zhao Y, Shen XL, Li S, Zhang YY, Peng RH, Ma KP (2020) Progress and outlook for soundscape ecology. Biodiversity Science, 28, 806-820. (in Chinese with English abstract)
[104] [赵莹, 申小莉, 李晟, 张雁云, 彭任华, 马克平 (2020) 声景生态学研究进展和展望. 生物多样性, 28, 806-820.]
[105] Znidersic E, Towsey M, Roy WK, Darling SE, Truskinger A, Roe P, Watson DM (2020) Using visualization and machine learning methods to monitor low detectability species—The least bittern as a case study. Ecological Informatics, 55, 101014.
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