年份港口预测和气候变化设想方案

IF 2.2 3区 农林科学 Q3 FOOD SCIENCE & TECHNOLOGY
H. Fraga, Nathalie Guimarães, João A. Santos
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引用次数: 0

摘要

杜罗地区以其优质葡萄酒而闻名,尤其是著名的波特酒。葡萄年份,每十年大约宣布2-3次,标志着卓越的品质与最佳的气候条件有关。气候变化带来了挑战,气温上升和极端天气事件影响了葡萄栽培。这项研究使用机器学习算法来评估气候对年份的影响以及未来几十年气候变化的影响。历史年份数据采集时间为1850年至2014年。获得了同期的月度气候数据,包括温度、降水、湿度、太阳辐射和风分量。选择各种机器学习算法进行分类,并通过统计分析帮助确定相关的气候变量进行区分。交叉验证用于模型训练和评估,以命中和未命中(混淆矩阵)作为性能度量。表现最好的模型进行了超参数调优。在此基础上,获得了IPCC SSP2、SSP3和SSP5 4个区域气候模式在不同社会经济情景下2030 - 2099年的未来气候预估。分位数映射偏差调整用于校正未来气候数据和减少模式偏差。过去的数据显示,年份中有23.6%出现了年份,平均每十年有两个年份,趋势略有上升。3月降水、4、5月气温、3、4月湿度、3月太阳辐射、6月经向风等气候变量是影响vintage年发生的重要因素。使用机器学习模型基于气候变量预测年份,XGBClassifier在年份/非年份类别中分别达到76% / 88%的命中率,ROC得分为0.86,显示出强大的预测能力。对不同社会经济路径下的未来气候变化情景进行了评估,结果表明,到2099年,SSP2、SSP3和SSP5的发生年份将分别减少10.3%、9.1%和5.8%。这项研究为气候变量和葡萄酒年份之间的关系提供了有价值的见解,使酿酒师能够在葡萄园管理和葡萄种植方面做出明智的决定。这些预测表明,气候变化可能会挑战葡萄酒行业,强调了适应战略的必要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Vintage Port prediction and climate change scenarios
The Douro region is renowned for its quality wines, particularly for the famous Port Wine. Vintage years, declared approximately 2–3 times per decade, signify exceptional quality linked to optimum climatic conditions driving grape quality attributes. Climate change poses challenges, as rising temperatures and extreme weather events impact viticulture. This study uses machine learning algorithms to assess the climatic influence on vintage years and climate change impacts for the next decades. Historical vintage data were collected from 1850 to 2014. Monthly climatic data for the same period were obtained, including temperature, precipitation, humidity, solar radiation, and wind components. Various machine-learning algorithms were selected for classification, and a statistical analysis helped identify relevant climate variables for differentiation. Cross-validation was used for model training and evaluation, with the hits and misses (confusion matrix) as the performance metric. The best-performing model underwent hyperparameter tuning. Subsequently, future climate projections were acquired for four regional climate models from 2030 until 2099 under different socio-economic scenarios (IPCC SSP2, SSP3, and SSP5). Quantile mapping bias adjustment was applied to correct future climate data and reduce model biases. Past data revealed that vintages occurred 23.6 % of the years, with an average of two vintage years per decade, with a slightly positive trend. Climate variables such as precipitation in March, air temperatures in April and May, humidity in March and April, solar radiation in March, and meridional wind in June were identified as important factors influencing vintage year occurrence. Machine-learning models were employed to predict vintage years based on the climate variables, with the XGBClassifier achieving the highest performance with 76 %/88 % hits for the vintage/non-vintage classes, respectively, and an ROC score of 0.86, demonstrating strong predictive capabilities. Future climate change scenarios under different socio-economic pathways were assessed, and the results indicated a decrease in the occurrence vintage years until 2099 (10.3 % for SSP2, 9.1 % for SSP3, and 5.8 % for SSP5). The study provides valuable insights into the relationship between climate variables and wine vintage years, enabling winemakers to make informed decisions about vineyard management and grape cultivation. The predictions suggest that climate change may challenge the wine industry, emphasising the need for adaptation strategies.
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来源期刊
OENO One
OENO One Agricultural and Biological Sciences-Food Science
CiteScore
4.40
自引率
13.80%
发文量
85
审稿时长
13 weeks
期刊介绍: OENO One is a peer-reviewed journal that publishes original research, reviews, mini-reviews, short communications, perspectives and spotlights in the areas of viticulture, grapevine physiology, genomics and genetics, oenology, winemaking technology and processes, wine chemistry and quality, analytical chemistry, microbiology, sensory and consumer sciences, safety and health. OENO One belongs to the International Viticulture and Enology Society - IVES, an academic association dedicated to viticulture and enology.
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