虎豹及有蹄类猎物种群数量监测方法概述

doi:10.17520/biods.2021551

摘要/Abstract

摘要：

虎(Panthera tigris)和豹(P. pardus)及有蹄类猎物的种群数量监测是虎豹保护的核心任务, 也是制定有效管理、保护和恢复措施的基础。近年来, 国内外用于虎豹种群数量监测的方法主要有: 信息网络收集法、基于标志重捕模型的红外相机调查法和非损伤采样粪便DNA分析技术; 有蹄类猎物的监测方法主要有: 样线法、样带法、大样方法、红外相机调查技术和非损伤性遗传标志重捕法。每种监测方法基于的假设前提和生态学原理不同, 监测结果的准确度也不同。由于监测物种的生物学特征、种群分布状况、监测目标和空间尺度或环境因素各异, 每种方法的适用性也不同。本文从野外调查设计、数据收集、处理分析等方面对虎豹及其有蹄类猎物数量监测方法的应用过程和统计原理进行了介绍, 分析了各种监测方法的优缺点, 并针对在虎豹监测中相机布设密度过大可能造成的伪重复抽样, 以及应用虎豹监测设计的自动相机监测替代猎物种群监测数量的评估等不科学的方面进行了探讨和建议。

关键词: 虎豹, 有蹄类猎物, 种群数量, 监测方法

Abstract

Background & Aim: Species conservation efforts require an understanding of population sizes. For predators such as tigers and leopards, it is also vital to monitor populations of their ungulate prey. In recent years, monitoring methods for tigers and leopards mainly entailed derivations from capture-recapture models based on data from noninvasive sampling and camera traps. Meanwhile, ungulate prey populations were monitored using line transects, belt transects, sample plots, camera trapping, and also using the capture-recapture model based on data from noninvasive genetic methods. Each monitoring technique has different assumptions and is based on varying ecological principles, and, as a consequence, accuracy also varies. Thus the applicability of each method depends on the biological characteristics and population distribution of study species, monitoring targets, and spatial scales of interest. We present details about common monitoring methods, including specific procedures and statistical principles. We also analyze advantages and disadvantages of these methods to provide reference for selecting the appropriate one for monitoring projects going forth.
Review Results: While monitoring population of tiger, leopard, and ungulate populations, it is necessary to select appropriate methods based on the population status of the target species in the focal area (i.e., considering distribution law and dynamic characteristics) and monitoring targets. For monitoring of tigers and leopards, for instance, excessive intensity in the study area may result in pseudoreplication, which may lead to habitat disturbance and waste of resources. Meanwhile, using automated-camera traps set for monitoring tigers and leopards to assess ungulate population size may be inappropriate.
Perspectives: Population surveys on tigers, leopards and ungulates can benefit from combining monitoring methods to achieve more accurate population estimations in the future. Recent advances in artificial intelligence technologies, in particular, are helpful for increasing monitoring accuracy by automatically identificating individual tigers and leopards and prevent repeated counts. Not only can this save labor costs, but it is also much higher in accuracy compared to traditional methods.

Key words: Panthera tigris, Panthera pardus, ungulate, population size, monitoring method

韦怡, 姜广顺 (2022) 虎豹及有蹄类猎物种群数量监测方法概述. 生物多样性, 30, 21551. DOI: 10.17520/biods.2021551.

Yi Wei, Guangshun Jiang (2022) Overview of monitoring methods for tigers, leopards and ungulate prey. Biodiversity Science, 30, 21551. DOI: 10.17520/biods.2021551.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2021551

https://www.biodiversity-science.net/CN/Y2022/V30/I9/21551

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方法 Method	取样 Sampling	取样难度 Difficulty in sampling	可获种群信息 Available population information	数量评估准确率 Accuracy of estimated quantity	时间资金成本 The cost of time and money	最佳应用 The best application situation
信息网络收集法 Information network method	足迹 Footprint	简单 Easy	(1)数量 Quantity (2)性别 Sex (3)年龄 Age	低 Low	低 Low	大空间尺度下, 虎豹个体处于游荡状态 At large spatial scales, tiger and leopard are in a wandering state
基于标志重捕模型的红外相机调查法 Camera trap based on capture-recapture model	影像数据 Image data	较难 Medium difficult	(1)数量 Quantity (2)性别 Sex (3)活动节律 Activity rhythm	中 Medium	中 Medium	虎豹种群稳定存在 Tiger and leopard populations are stable in the study area
非损伤采样粪便DNA分析法 Noninvasive sampling	粪便 Scat	难 Diffcult	(1)数量 Quantity (2)性别 Sex (3)年龄 Age (4)遗传信息 Genetic information	高 High	高 High	小空间尺度下, 虎豹种群数量小 At small spatial scales, tiger and leopard populations are small

方法 Method	取样 Sampling	取样难度 Difficulty in sampling	可获种群信息 Available population information	数量评估准确率 Accuracy of estimated quantity	时间资金成本 The cost of time and money	最佳应用 The best application situation
信息网络收集法 Information network method	足迹 Footprint	简单 Easy	(1)数量 Quantity (2)性别 Sex (3)年龄 Age	低 Low	低 Low	大空间尺度下, 虎豹个体处于游荡状态 At large spatial scales, tiger and leopard are in a wandering state
基于标志重捕模型的红外相机调查法 Camera trap based on capture-recapture model	影像数据 Image data	较难 Medium difficult	(1)数量 Quantity (2)性别 Sex (3)活动节律 Activity rhythm	中 Medium	中 Medium	虎豹种群稳定存在 Tiger and leopard populations are stable in the study area
非损伤采样粪便DNA分析法 Noninvasive sampling	粪便 Scat	难 Diffcult	(1)数量 Quantity (2)性别 Sex (3)年龄 Age (4)遗传信息 Genetic information	高 High	高 High	小空间尺度下, 虎豹种群数量小 At small spatial scales, tiger and leopard populations are small

方法 Method	数据类型 The type of data	关键技术或参数 Key technology/parameter	主要误差 Dominant error	相关花费 Cost	最佳应用 The best application situation
样线法 Line transect method	足迹 Footprint	足迹链数量 The number of footprint chains	(1)日活动距离 The distance of daily activities (2)足迹的辨别 The discrimination of footprints	低 Low	短时间内衡量北方调查区域内有蹄类种群的资源状况 To measure the resource status of ungulates in the northern survey area in a short time
样带法 Belt transect method	活动痕迹 Trace	痕迹数量 The number of trace	(1)样带宽度 The width of sample belt (2)换算系数 The conversion factor	低 Low	无雪地区的有蹄类种群数量调查 A survey of ungulate populations in snow-free areas
样方法 Sample plot	足迹 Footprint	足迹数量和方向 The number and direction of footprint chains	足迹的辨别 The discrimination of footprints	低 Low	北方有蹄类数量调查 The survey on the number of ungulates in the north
红外相机调查法 Camera trap	影像 Image	(1)相对多度指数 Relative abundance index (2)随机相遇模型 Random encounter model	(1) RAI与密度的相关性 The correlation between RAI and density (2)布设密度 The layout density of infrared camera (3)动物移动速率 The moving rate of animals	中 Medium	(1)生物本地资源调查 To investigation of biological local resources (2)快速评估调查 The rapid assessment survey
非损伤性遗传标志重捕法 Noninvasive genetic method based on the capture-recapture model	粪便 Scat	(1)微卫星技术 Micro satellite (2)标志重捕模型Capture-recapture model	(1) DNA降解 DNA degradation (2)基因分型错误 Genotyping errors	高 High	小空间尺度下, 有蹄类种群规模小 On a small spatial scale, ungulates have a small population size

方法 Method	数据类型 The type of data	关键技术或参数 Key technology/parameter	主要误差 Dominant error	相关花费 Cost	最佳应用 The best application situation
样线法 Line transect method	足迹 Footprint	足迹链数量 The number of footprint chains	(1)日活动距离 The distance of daily activities (2)足迹的辨别 The discrimination of footprints	低 Low	短时间内衡量北方调查区域内有蹄类种群的资源状况 To measure the resource status of ungulates in the northern survey area in a short time
样带法 Belt transect method	活动痕迹 Trace	痕迹数量 The number of trace	(1)样带宽度 The width of sample belt (2)换算系数 The conversion factor	低 Low	无雪地区的有蹄类种群数量调查 A survey of ungulate populations in snow-free areas
样方法 Sample plot	足迹 Footprint	足迹数量和方向 The number and direction of footprint chains	足迹的辨别 The discrimination of footprints	低 Low	北方有蹄类数量调查 The survey on the number of ungulates in the north
红外相机调查法 Camera trap	影像 Image	(1)相对多度指数 Relative abundance index (2)随机相遇模型 Random encounter model	(1) RAI与密度的相关性 The correlation between RAI and density (2)布设密度 The layout density of infrared camera (3)动物移动速率 The moving rate of animals	中 Medium	(1)生物本地资源调查 To investigation of biological local resources (2)快速评估调查 The rapid assessment survey
非损伤性遗传标志重捕法 Noninvasive genetic method based on the capture-recapture model	粪便 Scat	(1)微卫星技术 Micro satellite (2)标志重捕模型Capture-recapture model	(1) DNA降解 DNA degradation (2)基因分型错误 Genotyping errors	高 High	小空间尺度下, 有蹄类种群规模小 On a small spatial scale, ungulates have a small population size