面对气候和可持续性挑战的小麦耕作贝叶斯模型。

IF 3 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Frontiers in Artificial Intelligence Pub Date : 2024-08-27 eCollection Date: 2024-01-01 DOI:10.3389/frai.2024.1402098
Qaisar Ali
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引用次数: 0

摘要

传统耕作对可持续农业构成了威胁,因为粮食需求不断增长,洪水风险也在增加。本研究引入贝叶斯信念网络(BBN)来解决这些问题。该模型探讨了冬小麦生产中不同有机碳(OC)含量土壤的耕作对洪水管理的适应性。从英国伯克郡庞集水区的 NETMAP 土壤图谱中选取了三种真实土壤,强调其质地和土壤水分特性。这些土壤的 OC 含量分为四个等级(1%、3%、5%、7%),并与相关变量一起在 BBN 中建模。农业技术转让决策支持系统(DSSAT)模拟了 48 个耕种季节的数据集,以确定 BBN 的参数。研究比较了耕作对小麦产量、地表径流和温室气体-二氧化碳排放的影响,并根据统计数据分布对模型参数进行了分类(从低到高)。结果显示,在最高参数类别中,NT 的表现优于 CT,比较概率估计值,温室气体-CO2 排放量从 "7.34% 降至 7.31%",累积径流从 "8.52% 降至 8.50%",而产量从 "7.46% 增至 7.56%"。相反,CT 显示排放量从 "7.34% 增加到 7.36%",累积径流从 "8.52% 增加到 8.55%",产量从 "7.46% 减少到 7.35%"。BBN 模型有效地捕捉了不确定性,提供了反映变量间条件关系的后验概率分布,并提供了有利于冬小麦土壤碳储量(在 "NT.OC-7%PDPG8 "土壤中最高,如 286,634 千克/公顷)而非 CT(在 "CT.OC-3.9%PDPG8 "土壤中最低,如 5,894 千克/公顷)的新界决策选择。平均而言,新界的温室气体二氧化碳排放量最低,为 "3,985 千克二氧化碳当量/公顷",而 CT 的排放量为 "7,415 千克二氧化碳当量/公顷"。相反,NT 的最大排放量为 "8,747 千克 CO2eqv/公顷",而 CT 的排放量为 "15,356 千克 CO2eqv/公顷"。与 CT 相比,NT 在所有土壤中的地表径流量都较低,并限制了径流的自然生成,从而缓解了洪水,并有可能进行定制改进。研究建议使用该模型对各种时空条件进行广泛评估。研究结果符合可持续发展目标,如联合国农业和粮食组织分别为负责任的生产和气候行动制定的 SDG12 和 SDG13。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Bayesian model of tilling wheat confronting climatic and sustainability challenges.

Conventional farming poses threats to sustainable agriculture in growing food demands and increasing flooding risks. This research introduces a Bayesian Belief Network (BBN) to address these concerns. The model explores tillage adaptation for flood management in soils with varying organic carbon (OC) contents for winter wheat production. Three real soils, emphasizing texture and soil water properties, were sourced from the NETMAP soilscape of the Pang catchment area in Berkshire, United Kingdom. Modified with OC content at four levels (1, 3, 5, 7%), they were modeled alongside relevant variables in a BBN. The Decision Support System for Agrotechnology Transfer (DSSAT) simulated datasets across 48 cropping seasons to parameterize the BBN. The study compared tillage effects on wheat yield, surface runoff, and GHG-CO2 emissions, categorizing model parameters (from lower to higher bands) based on statistical data distribution. Results revealed that NT outperformed CT in the highest parametric category, comparing probabilistic estimates with reduced GHG-CO2 emissions from "7.34 to 7.31%" and cumulative runoff from "8.52 to 8.50%," while yield increased from "7.46 to 7.56%." Conversely, CT exhibited increased emissions from "7.34 to 7.36%" and cumulative runoff from "8.52 to 8.55%," along with reduced yield from "7.46 to 7.35%." The BBN model effectively captured uncertainties, offering posterior probability distributions reflecting conditional relationships across variables and offered decision choice for NT favoring soil carbon stocks in winter wheat (highest among soils "NT.OC-7%PDPG8," e.g., 286,634 kg/ha) over CT (lowest in "CT.OC-3.9%PDPG8," e.g., 5,894 kg/ha). On average, NT released minimum GHG- CO2 emissions to "3,985 kgCO2eqv/ha," while CT emitted "7,415 kgCO2eqv/ha." Conversely, NT emitted "8,747 kgCO2eqv/ha" for maximum emissions, while CT emitted "15,356 kgCO2eqv/ha." NT resulted in lower surface runoff against CT in all soils and limits runoff generations naturally for flood alleviation with the potential for customized improvement. The study recommends the model for extensive assessments of various spatiotemporal conditions. The research findings align with sustainable development goals, e.g., SDG12 and SDG13 for responsible production and climate actions, respectively, as defined by the Agriculture and Food Organization of the United Nations.

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来源期刊
CiteScore
6.10
自引率
2.50%
发文量
272
审稿时长
13 weeks
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