Modelling the functional dependency between root and shoot compartments to predict the impact of the environment on the architecture of the whole plant. Methodology for model fitting on simulated data using Deep Learning techniques

IF 2.6 Q1 AGRONOMY
A. Masson, Y. Caraglio, E. Nicolini, P. Borianne, J. Barczi
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引用次数: 0

Abstract

Tree structural and biomass growth studies mainly focus on the shoot compartment. Tree roots usually have to be taken apart due to the difficulties involved in measuring and observing this compartment, particularly root growth. In the context of climate change, the study of tree structural plasticity has become crucial and both shoot and root systems need to be considered simultaneously as they play a joint role in adapting traits to climate change (water availability for roots and light or carbon availability for shoots). We developed a botanically accurate whole-plant model and its simulator (RoCoCau) with a linkable external module (TOY) to represent shoot and root compartment dependencies and hence tree structural plasticity in different air and soil environments. This paper describes a new deep neural network calibration trained on simulated datasets computed from a set of more than 360 000 random TOY parameter values and random climate values. These datasets were used for training and for validation. For this purpose, we chose Voxnet, a convolutional neural network designed to classify 3D objects represented as a voxelized scene. We recommend further improvements for Voxnet inputs, outputs, and training. We were able to teach the network to predict the value of environment data well (mean error < 2%), and to predict the value of TOY parameters for plants under water stress conditions (mean error < 5% for all parameters), and for any environmental growing conditions (mean error < 20%).
对根室和地上部室之间的功能依赖性进行建模,以预测环境对整个植物结构的影响。使用深度学习技术对模拟数据进行模型拟合的方法
树木结构和生物量生长的研究主要集中在枝条隔室。由于难以测量和观察这个区域,特别是根系生长,因此通常必须将树根拆开。在气候变化的背景下,对树木结构可塑性的研究变得至关重要,需要同时考虑地上部和根系,因为它们在使性状适应气候变化方面发挥着共同作用(根系的水分可利用性和地上部的光或碳可利用性)。我们开发了一个具有可链接外部模块(TOY)的植物精确全植物模型及其模拟器(RoCoCau),以表示不同空气和土壤环境中的地上部和根部室依赖性,从而表示树木的结构可塑性。本文描述了一种新的深度神经网络校准,该校准是在模拟数据集上训练的,该数据集是由一组超过36万个随机TOY参数值和随机气候值计算而成的。这些数据集用于训练和验证。为此,我们选择了Voxnet,这是一种卷积神经网络,旨在对表示为体素化场景的3D对象进行分类。我们建议进一步改进Voxnet的输入、输出和培训。我们能够教网络很好地预测环境数据的值(平均误差<2%),并预测植物在水分胁迫条件下(所有参数的平均误差<5%)和任何环境生长条件下(平均误差+20%)的TOY参数值。
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
in silico Plants
in silico Plants Agricultural and Biological Sciences-Agronomy and Crop Science
CiteScore
4.70
自引率
9.70%
发文量
21
审稿时长
10 weeks
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