Flight heights obtained from GPS versus altimeters influence estimates of collision risk with offshore wind turbines in Lesser Black-backed Gulls Larus fuscus.

IF 3.4 1区生物学 Q2 ECOLOGY

Movement Ecology Pub Date : 2023-10-21 DOI:10.1186/s40462-023-00431-z

Daniel T Johnston, Chris B Thaxter, Philipp H Boersch-Supan, Jacob G Davies, Gary D Clewley, Ros M W Green, Judy Shamoun-Baranes, Aonghais S C P Cook, Niall H K Burton, Elizabeth M Humphreys

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引用次数: 0

Abstract

The risk posed by offshore wind farms to seabirds through collisions with turbine blades is greatly influenced by species-specific flight behaviour. Bird-borne telemetry devices may provide improved measurement of aspects of bird behaviour, notably individual and behaviour specific flight heights. However, use of data from devices that use the GPS or barometric altimeters in the gathering of flight height data is nevertheless constrained by a current lack of understanding of the error and calibration of these methods. Uncertainty remains regarding the degree to which errors associated with these methods can affect recorded flight heights, which may in turn have a significant influence on estimates of collision risk produced by Collision Risk Models (CRMs), which incorporate flight height distribution as an input. Using GPS/barometric altimeter tagged Lesser Black-backed Gulls Larus fuscus from two breeding colonies in the UK, we examine comparative flight heights produced by these devices, and their associated errors. We present a novel method of calibrating barometric altimeters using behaviour characterised from GPS data and open-source modelled atmospheric pressure. We examine the magnitude of difference between offshore flight heights produced from GPS and altimeters, comparing these measurements across sampling schedules, colonies, and years. We found flight heights produced from altimeter data to be significantly, although not consistently, higher than those produced from GPS data. This relationship was sustained across differing sampling schedules of five minutes and of 10 s, and between study colonies. We found the magnitude of difference between GPS and altimeter derived flight heights to also vary between individuals, potentially related to the robustness of calibration factors used. Collision estimates for theoretical wind farms were consequently significantly higher when using flight height distributions generated from barometric altimeters. Improving confidence in telemetry-obtained flight height distributions, which may then be applied to CRMs, requires sources of errors in these measurements to be identified. Our study improves knowledge of the calibration processes for flight height measurements based on telemetry data, with the aim of increasing confidence in their use in future assessments of collision risk and reducing the uncertainty over predicted mortality associated with wind farms.

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从GPS和高度计获得的飞行高度影响了小黑背海鸥与海上风力涡轮机碰撞风险的估计。

海上风电场与涡轮机叶片碰撞给海鸟带来的风险在很大程度上受到特定物种飞行行为的影响。鸟载遥测设备可以提供对鸟类行为各方面的改进测量，特别是个体和特定行为的飞行高度。然而，由于目前对这些方法的误差和校准缺乏了解，在收集飞行高度数据时使用来自使用GPS或气压高度计的设备的数据仍然受到限制。与这些方法相关的误差对记录的飞行高度的影响程度仍然存在不确定性，这反过来可能对碰撞风险模型（CRM）产生的碰撞风险估计产生重大影响，该模型将飞行高度分布作为输入。使用来自英国两个繁殖地的带有GPS/气压高度计标签的小黑背海鸥，我们检查了这些设备产生的比较飞行高度及其相关误差。我们提出了一种新的方法来校准气压高度计，该方法使用GPS数据和开源模拟大气压力的特性。我们检查了GPS和高度计产生的海上飞行高度之间的差异程度，比较了采样时间表、群体和年份的这些测量结果。我们发现，高度计数据产生的飞行高度显著高于GPS数据产生的高度，尽管并不一致。这种关系在5分钟和10秒的不同采样计划中以及研究群体之间保持不变。我们发现，GPS和高度计导出的飞行高度之间的差异幅度也因个体而异，这可能与所使用的校准因子的稳健性有关。因此，当使用气压高度计产生的飞行高度分布时，理论风电场的碰撞估计值要高得多。为了提高遥测获得的飞行高度分布的可信度，需要识别这些测量中的误差源，然后将其应用于CRM。我们的研究提高了对基于遥测数据的飞行高度测量校准过程的了解，目的是提高人们对其在未来碰撞风险评估中使用的信心，并减少与风电场相关的预测死亡率的不确定性。

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

Movement Ecology Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics

CiteScore

6.60

自引率

4.90%

发文量

审稿时长

23 weeks

期刊介绍： Movement Ecology is an open-access interdisciplinary journal publishing novel insights from empirical and theoretical approaches into the ecology of movement of the whole organism - either animals, plants or microorganisms - as the central theme. We welcome manuscripts on any taxa and any movement phenomena (e.g. foraging, dispersal and seasonal migration) addressing important research questions on the patterns, mechanisms, causes and consequences of organismal movement. Manuscripts will be rigorously peer-reviewed to ensure novelty and high quality.