BioCro II: a Software Package for Modular Crop Growth Simulations

IF 2.6 Q1 AGRONOMY

in silico Plants Pub Date : 2022-02-12 DOI:10.1093/insilicoplants/diac003

E. Lochocki, Scott Rohde, D. Jaiswal, Megan L Matthews, F. Miguez, S. Long, J. McGrath

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引用次数: 4

Abstract

The central motivation for mechanistic crop growth simulation has remained the same for decades: to reliably predict changes in crop yields and water usage in response to previously unexperienced increases in air temperature and CO2 concentration across different environments, species, and genotypes. Over the years, individual process-based model components have become more complex and specialized, increasing their fidelity but posing a challenge for integrating them into powerful multiscale models. Combining models is further complicated by the common strategy of hard-coding intertwined parameter values, equations, solution algorithms, and user interfaces, rather than treating these each as separate components. It is clear that a more flexible approach is now required. Here we describe a modular crop growth simulator, BioCro II. At its core, BioCro II is a cross-platform representation of models as sets of equations. This facilitates modularity in model building and allows it to harness modern techniques for numerical integration and data visualization. Several crop models have been implemented using the BioCro II framework, but it is a general purpose tool and can be used to model a wide variety of processes.

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BioCro II：模块化作物生长模拟软件包

几十年来，机械作物生长模拟的核心动机一直保持不变：可靠地预测作物产量和用水量的变化，以应对不同环境、物种和基因型的气温和二氧化碳浓度的前所未有的上升。多年来，基于过程的单个模型组件变得更加复杂和专业化，提高了它们的保真度，但对将它们集成到强大的多尺度模型中提出了挑战。由于对交织在一起的参数值、方程、求解算法和用户界面进行硬编码的共同策略，而不是将这些单独的组件视为单独的组件，因此组合模型变得更加复杂。显然，现在需要采取更灵活的办法。在这里，我们描述了一个模块化作物生长模拟器，BioCro II。BioCro II的核心是将模型表示为方程组的跨平台表示。这有助于模型构建的模块化，并使其能够利用现代技术进行数值集成和数据可视化。使用BioCro II框架已经实现了几种作物模型，但它是一种通用工具，可用于对各种过程进行建模。

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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