Choice of predictors and complexity for ecosystem distribution models: effects on performance and transferability

IF 5.4 1区环境科学与生态学 Q1 BIODIVERSITY CONSERVATION

Ecography Pub Date : 2024-06-10 DOI:10.1111/ecog.07269

Adam Eindride Naas, Lasse Torben Keetz, Rune Halvorsen, Peter Horvath, Ida Marielle Mienna, Trond Simensen, Anders Bryn

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Abstract

There is an increasing need for ecosystem-level distribution models (EDMs) and a better understanding of which factors affect their quality. We investigated how the performance and transferability of EDMs are influenced by 1) the choice of predictors and 2) model complexity. We modelled the distribution of 15 pre-classified ecosystem types in Norway using 252 predictors gridded to 100 × 100 m resolution. The ecosystem types are major types in the ‘Nature in Norway' system mainly defined by rule-based criteria such as whether soil or specific functional groups (e.g. trees) are present. The predictors were categorised into four groups, of which three represented proxies for natural, anthropogenic, or terrain processes (‘ecological predictors') and one represented spectral and structural characteristics of the surface observable from above (‘surface predictors'). Models were generated for five levels of model complexity. Model performance and transferability were evaluated with data collected independently of the training data. We found that 1) models trained with surface predictors only performed considerably better and were more transferable than models trained with ecological predictors, and 2) model performance increased with model complexity, levelling off from approximately 10 parameters and reaching a peak at approximately 20 parameters, while model transferability decreased with model complexity. Our findings suggest that surface predictors enhance EDM performance and transferability, most likely because they represent discernible surface characteristics of the ecosystem types. A poor match between the rule-based criteria that define the ecosystem types and the ecological predictors, which represent ecological processes, is a plausible explanation for why surface predictors better predict the distribution of ecosystem types. Our results indicate that, in most cases, the same models are not well suited for contrasting purposes, such as predicting where ecosystems are and explaining why they are there.

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生态系统分布模型预测因子和复杂性的选择：对性能和可移植性的影响

人们对生态系统级分布模型（EDM）的需求越来越大，也越来越需要更好地了解哪些因素会影响模型的质量。我们研究了 EDM 的性能和可转移性如何受到以下因素的影响：1）预测因子的选择；2）模型的复杂性。我们使用 252 个网格分辨率为 100 × 100 米的预测因子，模拟了挪威 15 种预先分类的生态系统类型的分布情况。这些生态系统类型是 "挪威自然 "系统中的主要类型，主要由基于规则的标准（如是否存在土壤或特定功能群（如树木））来定义。预测因子分为四组，其中三组代表自然、人为或地形过程的代用指标（"生态预测因子"），一组代表从高空观测到的地表光谱和结构特征（"地表预测因子"）。模型的复杂程度分为五个等级。利用独立于训练数据收集的数据对模型的性能和可移植性进行了评估。我们发现：1）与使用生态预测因子训练的模型相比，仅使用表面预测因子训练的模型性能更好，可移植性更高；2）模型性能随模型复杂度的增加而增加，从大约 10 个参数开始趋于平稳，在大约 20 个参数时达到顶峰，而模型可移植性随模型复杂度的增加而降低。我们的研究结果表明，表面预测因子可提高 EDM 性能和可转移性，这很可能是因为它们代表了生态系统类型的可识别表面特征。定义生态系统类型的基于规则的标准与代表生态过程的生态预测因子之间的不匹配，是表面预测因子能更好地预测生态系统类型分布的一个合理解释。我们的研究结果表明，在大多数情况下，相同的模型并不能很好地用于不同的目的，例如预测生态系统的位置和解释其存在的原因。

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来源期刊

Ecography 环境科学-生态学

CiteScore

11.60

自引率

3.40%

发文量

122

审稿时长

8-16 weeks

期刊介绍： ECOGRAPHY publishes exciting, novel, and important articles that significantly advance understanding of ecological or biodiversity patterns in space or time. Papers focusing on conservation or restoration are welcomed, provided they are anchored in ecological theory and convey a general message that goes beyond a single case study. We encourage papers that seek advancing the field through the development and testing of theory or methodology, or by proposing new tools for analysis or interpretation of ecological phenomena. Manuscripts are expected to address general principles in ecology, though they may do so using a specific model system if they adequately frame the problem relative to a generalized ecological question or problem. Purely descriptive papers are considered only if breaking new ground and/or describing patterns seldom explored. Studies focused on a single species or single location are generally discouraged unless they make a significant contribution to advancing general theory or understanding of biodiversity patterns and processes. Manuscripts merely confirming or marginally extending results of previous work are unlikely to be considered in Ecography. Papers are judged by virtue of their originality, appeal to general interest, and their contribution to new developments in studies of spatial and temporal ecological patterns. There are no biases with regard to taxon, biome, or biogeographical area.