Colorado Mesa University, Grand Junction, Colorado, USA.
Great Lakes Research Center, Michigan Technological University, Houghton, Michigan, USA.
J Anim Ecol. 2024 Mar;93(3):267-280. doi: 10.1111/1365-2656.14044. Epub 2024 Jan 2.
Individual body size distributions (ISD) within communities are remarkably consistent across habitats and spatiotemporal scales and can be represented by size spectra, which are described by a power law. The focus of size spectra analysis is to estimate the exponent ( ) of the power law. A common application of size spectra studies is to detect anthropogenic pressures. Many methods have been proposed for estimating most of which involve binning the data, counting the abundance within bins, and then fitting an ordinary least squares regression in log-log space. However, recent work has shown that binning procedures return biased estimates of compared to procedures that directly estimate using maximum likelihood estimation (MLE). While it is clear that MLE produces less biased estimates of site-specific λ's, it is less clear how this bias affects the ability to test for changes in λ across space and time, a common question in the ecological literature. Here, we used simulation to compare the ability of two normalised binning methods (equal logarithmic and log bins) and MLE to (1) recapture known values of , and (2) recapture parameters in a linear regression measuring the change in across a hypothetical environmental gradient. We also compared the methods using two previously published body size datasets across a natural temperature gradient and an anthropogenic pollution gradient. Maximum likelihood methods always performed better than common binning methods, which demonstrated consistent bias depending on the simulated values of . This bias carried over to the regressions, which were more accurate when was estimated using MLE compared to the binning procedures. Additionally, the variance in estimates using MLE methods is markedly reduced when compared to binning methods. The error induced by binning methods can be of similar magnitudes as the variation previously published in experimental and observational studies, bringing into question the effect sizes of previously published results. However, while the methods produced different regression slope estimates, they were in qualitative agreement on the sign of those slopes (i.e. all negative or all positive). Our results provide further support for the direct estimation of and its relative variation across environmental gradients using MLE over the more common methods of binning.
个体在群落中的体型分布(ISD)在生境和时空尺度上都非常一致,可以通过体型谱来表示,体型谱由幂律描述。体型谱分析的重点是估计幂律的指数( )。体型谱研究的一个常见应用是检测人为压力。已经提出了许多估计 的方法,其中大多数涉及对数据进行分组,在组内计数丰度,然后在对数-对数空间中拟合普通最小二乘回归。然而,最近的研究表明,与直接使用最大似然估计(MLE)估计 相比,分组程序返回的 估计值存在偏差。虽然很明显,MLE 产生的站点特定 λ 的偏差估计较小,但对于测试 λ 在空间和时间上的变化的能力的影响程度,即生态文献中常见的问题,还不太清楚。在这里,我们使用模拟来比较两种归一化分组方法(等对数和对数分组)和 MLE 的能力:(1)重新捕获已知的 值,(2)重新捕获在沿假设环境梯度变化的线性回归中测量的 λ 的参数。我们还使用两个以前发表的体型数据集在自然温度梯度和人为污染梯度上比较了这些方法。最大似然方法始终比常见的分组方法表现更好,而常见的分组方法表现出一致的偏差,具体取决于模拟的 值。这种偏差也会传递到回归中,与分组过程相比,使用 MLE 估计 时回归更准确。此外,与分组方法相比,使用 MLE 方法估计的方差明显降低。分组方法引起的误差可以与以前发表的实验和观察研究中的变异性相媲美,从而对以前发表的结果的效应大小提出质疑。然而,尽管这些方法产生了不同的回归斜率估计值,但它们在斜率的符号上是一致的(即全部为负或全部为正)。我们的结果进一步支持了使用 MLE 直接估计 和其在环境梯度上的相对变化,而不是使用更常见的分组方法。
