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| Main Authors: | , , , , , , , , , , , |
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| Format: | Preprint |
| Published: |
2026
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2602.03767 |
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| _version_ | 1866918321661673472 |
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| author | Masiwal, Rajat Aitken, Colin Marchakitus, Adam Gupta, Mayank Kowal, Katherine Pahlavan, Hamid A. Yang, Tyler Sun, Y. Qiang Kremer, Michael Jina, Amir Boos, William R. Hassanzadeh, Pedram |
| author_facet | Masiwal, Rajat Aitken, Colin Marchakitus, Adam Gupta, Mayank Kowal, Katherine Pahlavan, Hamid A. Yang, Tyler Sun, Y. Qiang Kremer, Michael Jina, Amir Boos, William R. Hassanzadeh, Pedram |
| contents | Artificial intelligence weather prediction (AIWP) models now often outperform traditional physics-based models on common metrics while requiring orders-of-magnitude less computing resources and time. Open-access AIWP models thus hold promise as transformational tools for helping low- and middle-income populations make decisions in the face of high-impact weather shocks. Yet, current approaches to evaluating AIWP models focus mainly on aggregated meteorological metrics without considering local stakeholders' needs in decision-oriented, operational frameworks. Here, we introduce such a framework that connects meteorology, AI, and social sciences. As an example, we apply it to the 150-year-old problem of Indian monsoon forecasting, focusing on benefits to rain-fed agriculture, which is highly susceptible to climate change. AIWP models skillfully predict an agriculturally relevant onset index at regional scales weeks in advance when evaluated out-of-sample using deterministic and probabilistic metrics. This framework informed a government-led effort in 2025 to send 38 million Indian farmers AI-based monsoon onset forecasts, which captured an unusual weeks-long pause in monsoon progression. This decision-oriented benchmarking framework provides a key component of a blueprint for harnessing the power of AIWP models to help large vulnerable populations adapt to weather shocks in the face of climate variability and change. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2602_03767 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Decision-oriented benchmarking to transform AI weather forecast access: Application to the Indian monsoon Masiwal, Rajat Aitken, Colin Marchakitus, Adam Gupta, Mayank Kowal, Katherine Pahlavan, Hamid A. Yang, Tyler Sun, Y. Qiang Kremer, Michael Jina, Amir Boos, William R. Hassanzadeh, Pedram Machine Learning Artificial Intelligence General Economics Economics Atmospheric and Oceanic Physics Artificial intelligence weather prediction (AIWP) models now often outperform traditional physics-based models on common metrics while requiring orders-of-magnitude less computing resources and time. Open-access AIWP models thus hold promise as transformational tools for helping low- and middle-income populations make decisions in the face of high-impact weather shocks. Yet, current approaches to evaluating AIWP models focus mainly on aggregated meteorological metrics without considering local stakeholders' needs in decision-oriented, operational frameworks. Here, we introduce such a framework that connects meteorology, AI, and social sciences. As an example, we apply it to the 150-year-old problem of Indian monsoon forecasting, focusing on benefits to rain-fed agriculture, which is highly susceptible to climate change. AIWP models skillfully predict an agriculturally relevant onset index at regional scales weeks in advance when evaluated out-of-sample using deterministic and probabilistic metrics. This framework informed a government-led effort in 2025 to send 38 million Indian farmers AI-based monsoon onset forecasts, which captured an unusual weeks-long pause in monsoon progression. This decision-oriented benchmarking framework provides a key component of a blueprint for harnessing the power of AIWP models to help large vulnerable populations adapt to weather shocks in the face of climate variability and change. |
| title | Decision-oriented benchmarking to transform AI weather forecast access: Application to the Indian monsoon |
| topic | Machine Learning Artificial Intelligence General Economics Economics Atmospheric and Oceanic Physics |
| url | https://arxiv.org/abs/2602.03767 |