Data-driven crop growth simulation on time-varying generated images using multi-conditional generative adversarial networks.

IF 4.7 2区 生物学 Q1 BIOCHEMICAL RESEARCH METHODS
Lukas Drees, Dereje T Demie, Madhuri R Paul, Johannes Leonhardt, Sabine J Seidel, Thomas F Döring, Ribana Roscher
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引用次数: 0

Abstract

Background: Image-based crop growth modeling can substantially contribute to precision agriculture by revealing spatial crop development over time, which allows an early and location-specific estimation of relevant future plant traits, such as leaf area or biomass. A prerequisite for realistic and sharp crop image generation is the integration of multiple growth-influencing conditions in a model, such as an image of an initial growth stage, the associated growth time, and further information about the field treatment. While image-based models provide more flexibility for crop growth modeling than process-based models, there is still a significant research gap in the comprehensive integration of various growth-influencing conditions. Further exploration and investigation are needed to address this gap.

Methods: We present a two-stage framework consisting first of an image generation model and second of a growth estimation model, independently trained. The image generation model is a conditional Wasserstein generative adversarial network (CWGAN). In the generator of this model, conditional batch normalization (CBN) is used to integrate conditions of different types along with the input image. This allows the model to generate time-varying artificial images dependent on multiple influencing factors. These images are used by the second part of the framework for plant phenotyping by deriving plant-specific traits and comparing them with those of non-artificial (real) reference images. In addition, image quality is evaluated using multi-scale structural similarity (MS-SSIM), learned perceptual image patch similarity (LPIPS), and Fréchet inception distance (FID). During inference, the framework allows image generation for any combination of conditions used in training; we call this generation data-driven crop growth simulation.

Results: Experiments are performed on three datasets of different complexity. These datasets include the laboratory plant Arabidopsis thaliana (Arabidopsis) and crops grown under real field conditions, namely cauliflower (GrowliFlower) and crop mixtures consisting of faba bean and spring wheat (MixedCrop). In all cases, the framework allows realistic, sharp image generations with a slight loss of quality from short-term to long-term predictions. For MixedCrop grown under varying treatments (different cultivars, sowing densities), the results show that adding these treatment information increases the generation quality and phenotyping accuracy measured by the estimated biomass. Simulations of varying growth-influencing conditions performed with the trained framework provide valuable insights into how such factors relate to crop appearances, which is particularly useful in complex, less explored crop mixture systems. Further results show that adding process-based simulated biomass as a condition increases the accuracy of the derived phenotypic traits from the predicted images. This demonstrates the potential of our framework to serve as an interface between a data-driven and a process-based crop growth model.

Conclusion: The realistic generation and simulation  of future plant appearances is adequately feasible by multi-conditional CWGAN. The presented framework complements process-based models and overcomes their limitations, such as the reliance on assumptions and the low exact field-localization specificity, by realistic visualizations of the spatial crop development that directly lead to a high explainability of the model predictions.

利用多条件生成式对抗网络,在时变生成图像上进行数据驱动的作物生长模拟。
背景:基于图像的作物生长建模可以揭示作物随时间变化的空间发展情况,从而及早根据具体位置估算相关的未来植物性状,如叶面积或生物量,从而为精准农业做出重大贡献。生成逼真、清晰的作物图像的前提条件是在模型中整合多种影响生长的条件,如初始生长阶段的图像、相关的生长时间以及有关田间处理的进一步信息。与基于过程的模型相比,基于图像的模型为作物生长建模提供了更大的灵活性,但在综合集成各种生长影响条件方面仍存在很大的研究差距。要填补这一空白,还需要进一步的探索和研究:我们提出了一个两阶段框架,首先是一个图像生成模型,其次是一个生长估计模型,这两个模型都是经过独立训练的。图像生成模型是一个条件瓦瑟斯坦生成对抗网络(CWGAN)。在该模型的生成器中,使用了条件批量归一化(CBN)来整合输入图像中不同类型的条件。这样,该模型就能生成依赖于多种影响因素的时变人工图像。该框架的第二部分使用这些图像进行植物表型,得出植物的特定性状,并与非人工(真实)参考图像进行比较。此外,还使用多尺度结构相似性(MS-SSIM)、学习感知图像斑块相似性(LPIPS)和弗雷谢特截距(FID)对图像质量进行评估。在推理过程中,该框架允许为训练中使用的任何条件组合生成图像;我们称这种生成为数据驱动的作物生长模拟:我们在三个不同复杂度的数据集上进行了实验。这些数据集包括实验室植物拟南芥(Arabidopsis)和在真实田间条件下生长的作物,即花椰菜(GrowliFlower)和由蚕豆和春小麦组成的作物混合物(MixedCrop)。在所有情况下,该框架都能生成逼真、清晰的图像,但从短期到长期预测,图像质量略有下降。对于在不同处理(不同栽培品种、播种密度)下种植的混合作物,结果表明,添加这些处理信息可提高生成质量和表型准确性(以估计生物量衡量)。利用训练有素的框架对不同的生长影响条件进行模拟,可以深入了解这些因素与作物表型的关系,这对于复杂的、探索较少的作物混交系统尤为有用。进一步的结果表明,添加基于过程的模拟生物量作为条件,可提高从预测图像中推导出表型特征的准确性。这表明我们的框架有潜力成为数据驱动和基于过程的作物生长模型之间的接口:结论:通过多条件 CWGAN,未来植物外观的真实生成和模拟是完全可行的。所提出的框架是对基于过程的模型的补充,并克服了其局限性,如对假设的依赖性和准确的田间定位特异性较低,通过对作物空间发展的逼真可视化,直接提高了模型预测的可解释性。
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
Plant Methods
Plant Methods 生物-植物科学
CiteScore
9.20
自引率
3.90%
发文量
121
审稿时长
2 months
期刊介绍: Plant Methods is an open access, peer-reviewed, online journal for the plant research community that encompasses all aspects of technological innovation in the plant sciences. There is no doubt that we have entered an exciting new era in plant biology. The completion of the Arabidopsis genome sequence, and the rapid progress being made in other plant genomics projects are providing unparalleled opportunities for progress in all areas of plant science. Nevertheless, enormous challenges lie ahead if we are to understand the function of every gene in the genome, and how the individual parts work together to make the whole organism. Achieving these goals will require an unprecedented collaborative effort, combining high-throughput, system-wide technologies with more focused approaches that integrate traditional disciplines such as cell biology, biochemistry and molecular genetics. Technological innovation is probably the most important catalyst for progress in any scientific discipline. Plant Methods’ goal is to stimulate the development and adoption of new and improved techniques and research tools and, where appropriate, to promote consistency of methodologies for better integration of data from different laboratories.
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