PS-MTL-LUCAS：用于同时预测多种土壤特性的部分共享多任务学习模型

IF 5.8 2区环境科学与生态学 Q1 ECOLOGY

Ecological Informatics Pub Date : 2024-08-20 DOI:10.1016/j.ecoinf.2024.102784

Zhaoyu Zhai, Fuji Chen, Hongfeng Yu, Jun Hu, Xinfei Zhou, Huanliang Xu

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引用次数: 0

摘要

土壤是人类生存和社会发展的基础，土壤质量对农产品的生长有很大影响。可见光/近红外光谱仪已被公认为一种快速、无损的土壤性质预测方法，而多任务学习是分析光谱数据与土壤性质之间相关性的一种可取方法。然而，目前采用软参数共享结构的多任务学习模型极其依赖任务相关性。针对这一局限性，我们在本研究中提出了具有部分共享结构的多任务学习模型 PS-MTL-LUCAS。我们利用额外的共享层来学习一般信息表征，并与每个特定任务层进行交互。部分共享结构确保了层与层之间的最大信息流，从而提高了预测性能。此外，还采用了 SHapley Addictive exPlanations（SHAP）算法来提取每种土壤特性的特征波长。实验结果表明，PS-MTL-LUCAS 的 pH、N、P、K、CEC、OC 和 CaCO 测定系数分别为 0.945、0.936、0.413、0.624、0.837、0.952 和 0.956，在最先进的模型中处于领先地位。总之，本研究强调了土壤光谱和多任务学习技术在土壤性质预测任务中的应用，为土壤研究提供了一种非常有前途的方法。

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PS-MTL-LUCAS: A partially shared multi-task learning model for simultaneously predicting multiple soil properties

Soil acts as a foundation for human survival and social development and soil quality has a great effect on the growth of agricultural products. Visible/near-infrared spectroscopy has been acknowledged as a rapid and non-destructive method for predicting soil properties, and multi-task learning is a preferable approach to analyze the correlation between the spectroscopy data and soil properties. However, current multi-task learning models with the soft parameter sharing structure extremely rely on the task relatedness. To tackle this limitation, we proposed PS-MTL-LUCAS, a multi-task learning with a partially shared structure in this study. An additional shared layer was utilized to learn the general informative representations and interact with each task-specific layer. The partially shared structure ensured the maximum information flow between layers, thereby boosting the prediction performance. Also, the SHapley Addictive exPlanations (SHAP) algorithm was adopted to extract the feature wavelengths of each soil property. PS-MTL-LUCAS was validated on the LUCAS topsoil dataset (2009), and the experimental result suggested that PS-MTL-LUCAS dominated state-of-the-art models by achieving the determination of coefficient at 0.945, 0.936, 0.413, 0.624, 0.837, 0.952, and 0.956 for pH, N, P, K, CEC, OC, and CaCO, respectively. In summary, this study highlighted the use of the soil spectroscopy and multi-task learning techniques in the soil property prediction task and provided a very promising approach for soil studies.

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来源期刊

Ecological Informatics 环境科学-生态学

CiteScore

8.30

自引率

11.80%

发文量

346

审稿时长

46 days

期刊介绍： The journal Ecological Informatics is devoted to the publication of high quality, peer-reviewed articles on all aspects of computational ecology, data science and biogeography. The scope of the journal takes into account the data-intensive nature of ecology, the growing capacity of information technology to access, harness and leverage complex data as well as the critical need for informing sustainable management in view of global environmental and climate change. The nature of the journal is interdisciplinary at the crossover between ecology and informatics. It focuses on novel concepts and techniques for image- and genome-based monitoring and interpretation, sensor- and multimedia-based data acquisition, internet-based data archiving and sharing, data assimilation, modelling and prediction of ecological data.