An Attention-Based Algorithm for Gravity Adaptation Zone Calibration

TL;DR

This paper introduces an attention-based algorithm for calibrating gravity adaptation zones, enhancing feature fusion and weighting to improve accuracy and robustness in complex gravity field data analysis.

Contribution

It proposes a novel attention mechanism to adaptively fuse multidimensional features, addressing multicollinearity and redundancy in gravity zone calibration.

Findings

Significant improvement in calibration accuracy across multiple machine learning models.

Enhanced robustness and generalization ability demonstrated in experiments.

Constructed a large-scale gravity dataset with over 10,000 points for model training.

Abstract

Accurate calibration of gravity adaptation zones is of great significance in fields such as underwater navigation, geophysical exploration, and marine engineering. With the increasing application of gravity field data in these areas, traditional calibration methods based on single features are becoming inadequate for capturing the complex characteristics of gravity fields and addressing the intricate interrelationships among multidimensional data. This paper proposes an attention-enhanced algorithm for gravity adaptation zone calibration. By introducing an attention mechanism, the algorithm adaptively fuses multidimensional gravity field features and dynamically assigns feature weights, effectively solving the problems of multicollinearity and redundancy inherent in traditional feature selection methods, significantly improving calibration accuracy and robustness.In addition, a large-scale gravity field dataset with over 10,000 sampling points was constructed, and Kriging interpolation was used to enhance the spatial resolution of the data, providing a reliable data foundation for model training and evaluation. We conducted both qualitative and quantitative experiments on several classical machine learning models (such as SVM, GBDT, and RF), and the results demonstrate that the proposed algorithm significantly improves performance across these models, outperforming other traditional feature selection methods. The method proposed in this paper provides a new solution for gravity adaptation zone calibration, showing strong generalization ability and potential for application in complex environments. The code is available at \href{this link} {https://github.com/hulnifox/RF-ATTN}.