全球定位系统测量误差会在动物运动数据中产生虚假的180度转向角和强烈的方向偏差。

GPS measurement error gives rise to spurious 180 degree turning angles and strong directional biases in animal movement data.

作者信息

Hurford Amy

机构信息

Centre for Mathematical Biology, Department of Biological Sciences, University of Alberta, Kingston, Ontario, Canada.

出版信息

PLoS One. 2009 May 20;4(5):e5632. doi: 10.1371/journal.pone.0005632.

DOI:10.1371/journal.pone.0005632

PMID:19479067

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2682572/

Abstract

BACKGROUND

Movement data are frequently collected using Global Positioning System (GPS) receivers, but recorded GPS locations are subject to errors. While past studies have suggested methods to improve location accuracy, mechanistic movement models utilize distributions of turning angles and directional biases and these data present a new challenge in recognizing and reducing the effect of measurement error.

METHODS

I collected locations from a stationary GPS collar, analyzed a probabilistic model and used Monte Carlo simulations to understand how measurement error affects measured turning angles and directional biases.

RESULTS

Results from each of the three methods were in complete agreement: measurement error gives rise to a systematic bias where a stationary animal is most likely to be measured as turning 180 degrees or moving towards a fixed point in space. These spurious effects occur in GPS data when the measured distance between locations is <20 meters.

CONCLUSIONS

Measurement error must be considered as a possible cause of 180 degree turning angles in GPS data. Consequences of failing to account for measurement error are predicting overly tortuous movement, numerous returns to previously visited locations, inaccurately predicting species range, core areas, and the frequency of crossing linear features. By understanding the effect of GPS measurement error, ecologists are able to disregard false signals to more accurately design conservation plans for endangered wildlife.

摘要

背景

运动数据通常使用全球定位系统（GPS）接收器收集，但记录的GPS位置存在误差。虽然过去的研究提出了提高定位精度的方法，但机械运动模型利用转向角和方向偏差的分布，这些数据在识别和减少测量误差的影响方面带来了新的挑战。

方法

我从一个固定的GPS项圈收集位置数据，分析了一个概率模型，并使用蒙特卡洛模拟来了解测量误差如何影响测量的转向角和方向偏差。

结果

三种方法的结果完全一致：测量误差会导致系统偏差，即静止的动物最有可能被测量为转向180度或朝着空间中的一个固定点移动。当位置之间的测量距离<20米时，这些虚假效应会出现在GPS数据中。

结论

测量误差必须被视为GPS数据中180度转向角的一个可能原因。未考虑测量误差的后果是预测过度曲折的运动、多次返回先前访问的位置、不准确地预测物种范围、核心区域以及穿越线性特征的频率。通过了解GPS测量误差的影响，生态学家能够忽略虚假信号，从而更准确地为濒危野生动物设计保护计划。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/47da/2682572/80067835a474/pone.0005632.g001.jpg

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全球定位系统测量误差会在动物运动数据中产生虚假的180度转向角和强烈的方向偏差。

GPS measurement error gives rise to spurious 180 degree turning angles and strong directional biases in animal movement data.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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