# High-resolution climate prediction in mountainous terrain using a ConvLSTM-XGBoost hybrid model with dynamic bayesian weighting

**Authors:** Dai Yanting, Wu Boxian, Yang Qiwei, Ren Shuaitao, Yang Fen, Song Lei

PMC · DOI: 10.1038/s41598-025-20882-1 · 2025-10-22

## TL;DR

A new hybrid model combining ConvLSTM and XGBoost improves climate predictions in mountainous regions by capturing spatiotemporal patterns and topographic effects.

## Contribution

The model introduces dynamic Bayesian weighting to adaptively calibrate ConvLSTM and XGBoost components for improved climate prediction in complex terrain.

## Key findings

- The hybrid model reduced precipitation prediction MAE by 30.5% compared to CMIP6.
- It improved the F1-score for extreme precipitation identification by 20%.
- The model achieved 96.53% accuracy in maximum temperature predictions with low error.

## Abstract

To address the challenge where the interplay between spatiotemporal dynamics and topographic effects complicates climate modeling over complex terrain, we propose a hybrid ConvLSTM-XGBoost model incorporating dynamic Bayesian weighting, and demonstrate its capacity for high-precision climate prediction through a case study in the Hongyuan Mountain region of Yunnan, China (22.5°–23.5°N, 102.5°–103.5°E); specifically, the ConvLSTM network captures spatiotemporal evolution patterns (e.g., propagation of the southwest monsoon front) from the 0.25° resolution CN05.1 climate dataset, while XGBoost quantifies the nonlinear modulation effects of 90-m SRTM DEM-derived topographic features (elevation, aspect) on precipitation phases, with an innovatively integrated Bayesian Model Averaging (BMA) framework dynamically calibrating model weights—XGBoost at 0.68 ± 0.05 during dry seasons and ConvLSTM at 0.72 ± 0.07 during monsoons—to enhance responsiveness to extreme events. Validation using 1961–2022 climate data shows the hybrid model reduces precipitation prediction mean absolute error (MAE) by 30.5% compared to CMIP6 (achieving an MAE of 0.0089 [specify units, e.g., mm/day]), improves the F1-score for identifying extreme precipitation (> 50 mm/day) by 20%, achieves 96.53% accuracy in maximum temperature (Tmax) predictions (errors ≤ 3%), and reduces high-temperature dispersion by 52%, thereby serving as a 1-km resolution decision-support tool for mountain climate risk management, supporting drought warning and hydropower scheduling in Yunnan’s Climate Adaptation Plan 2035, and offering a scalable framework for global mountain climate modeling.

## Full-text entities

- **Diseases:** drought (MESH:C536747), flood (MESH:C565009)
- **Chemicals:** Tmin (-)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12546732/full.md

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Source: https://tomesphere.com/paper/PMC12546732