Improving Urban Flood Prediction using LSTM-DeepLabv3+ and Bayesian
Optimization with Spatiotemporal feature fusion
- URL: http://arxiv.org/abs/2304.09994v1
- Date: Wed, 19 Apr 2023 22:00:04 GMT
- Title: Improving Urban Flood Prediction using LSTM-DeepLabv3+ and Bayesian
Optimization with Spatiotemporal feature fusion
- Authors: Zuxiang Situ, Qi Wang, Shuai Teng, Wanen Feng, Gongfa Chen, Qianqian
Zhou, Guangtao Fu
- Abstract summary: This study presented a CNN-RNN hybrid feature fusion modelling approach for urban flood prediction.
It integrated the strengths of CNNs in processing spatial features and RNNs in analyzing different dimensions of time sequences.
- Score: 7.790241122137617
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Deep learning models have become increasingly popular for flood prediction
due to their superior accuracy and efficiency compared to traditional methods.
However, current machine learning methods often rely on separate spatial or
temporal feature analysis and have limitations on the types, number, and
dimensions of input data. This study presented a CNN-RNN hybrid feature fusion
modelling approach for urban flood prediction, which integrated the strengths
of CNNs in processing spatial features and RNNs in analyzing different
dimensions of time sequences. This approach allowed for both static and dynamic
flood predictions. Bayesian optimization was applied to identify the seven most
influential flood-driven factors and determine the best combination strategy.
By combining four CNNs (FCN, UNet, SegNet, DeepLabv3+) and three RNNs (LSTM,
BiLSTM, GRU), the optimal hybrid model was identified as LSTM-DeepLabv3+. This
model achieved the highest prediction accuracy (MAE, RMSE, NSE, and KGE were
0.007, 0.025, 0.973 and 0.755, respectively) under various rainfall input
conditions. Additionally, the processing speed was significantly improved, with
an inference time of 1.158s (approximately 1/125 of the traditional computation
time) compared to the physically-based models.
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