Mammal population density estimation using camera traps based on a random encounter model: theoretical basis and practical recommendations

IF 1.2 Q3 BIODIVERSITY CONSERVATION Nature Conservation Research Pub Date : 2023-01-01 DOI:10.24189/ncr.2023.007
S. Ogurtsov
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Abstract

Estimating the population density of mammals has long been one of the problematic tasks of both fundamental population ecology and practical programmes for their conservation and management. The majority of methods for population density estimation using camera traps are focused on individually marked species. This review paper presents the theoretical and practical foundations of a method, Random Encounter Model (REM), used for estimating the population density of unmarked mammal species using camera traps. Based on an extensive analysis of the literature and our personal practical experience, we discussed the theory and practice for the application of this method, as well as its strengths and weaknesses. In this method, if we know parameters of the effective detection zone of a camera trap (radius and angle), and the length of the day range, it is possible to correct the trapping rate (i.e. the number of independent trap events per total number of camera traps-nights) in order to calculate the population density of species. The effective detection zone of a camera trap is determined through modelling using computer vision algorithms. The mammal day range is calculated based on its activity level and travel speed, taking into account behavioural patterns based on machine learning models. For REM, a random or systematic design for the camera trap placements should be used. If camera traps are installed against trails or roads, appropriate correction factors must be applied. The effectiveness and reliability of REM has been confirmed by many independent population density estimates, including capture-recapture analyses, visual transect counts, and scat counts. To date, the implementation of REM and its extensions is presented in the R programming environment. It has been established that the main difficulties in the use of the REM are technical imperfections of the camera traps themselves, the relatively large required number of their stations (at least 50 or more), as well as long calibration work. For all these difficulties, possible solutions are proposed. In conclusion, practical recommendations are provided for the use of REM in studies in Protected Areas.
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基于随机相遇模型的相机陷阱估计哺乳动物种群密度:理论基础和实践建议
长期以来,估计哺乳动物的种群密度一直是基本种群生态学和哺乳动物保护和管理的实际方案中有问题的任务之一。大多数用相机陷阱估计种群密度的方法都集中在单独标记的物种上。本文综述了随机相遇模型(Random Encounter Model, REM)在利用相机陷阱估计无标记哺乳动物种群密度中的理论和实践基础。在广泛的文献分析和个人实践经验的基础上,我们讨论了该方法应用的理论和实践,以及它的优点和缺点。在该方法中,如果我们知道相机陷阱的有效探测区域(半径和角度)的参数,以及白天范围的长度,就可以修正捕获率(即每总相机陷阱夜数的独立捕获事件数),从而计算出物种的种群密度。利用计算机视觉算法对摄像机陷阱的有效检测区域进行建模确定。哺乳动物的活动范围是根据其活动水平和移动速度计算的,同时考虑了基于机器学习模型的行为模式。对于快速眼动,应该使用随机或系统的相机陷阱放置设计。如果在小路或道路上安装了相机陷阱,必须采用适当的校正系数。REM的有效性和可靠性已经被许多独立的种群密度估计所证实,包括捕获-再捕获分析、视觉样带计数和粪便计数。迄今为止,REM及其扩展的实现都是在R编程环境中实现的。已经确定,使用REM的主要困难是相机陷阱本身的技术缺陷,它们所需的站点数量相对较多(至少50个或更多),以及长时间的校准工作。对于所有这些困难,提出了可能的解决办法。最后,提出了在保护区研究中使用快速眼动的实用建议。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Nature Conservation Research
Nature Conservation Research BIODIVERSITY CONSERVATION-
CiteScore
4.70
自引率
5.90%
发文量
34
审稿时长
13 weeks
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