Multi-task learning for aspect level semantic classification combining complex aspect target semantic enhancement and adaptive local focus

Quan Zhu; Xiaoyin Wang; Xuan Liu; Wanru Du; Xingxing Ding; Quan Zhu; Xiaoyin Wang; Xuan Liu; Wanru Du; Xingxing Ding

doi:10.3934/mbe.2023824

Mathematical Biosciences and Engineering

2023, Volume 20, Issue 10: 18566-18591. doi: 10.3934/mbe.2023824

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Research article

Multi-task learning for aspect level semantic classification combining complex aspect target semantic enhancement and adaptive local focus

1.
China Aerospace Academy of Systems Science and Engineering, Beijing 100048, China
2.
Aerospace Hongka Intelligent Technology (Beijing) CO., LTD., Beijing 100048, China

Academic Editor: Yang Kuang

Received: 20 May 2023 Revised: 28 August 2023 Accepted: 28 August 2023 Published: 27 September 2023

Aspect-based sentiment analysis (ABSA) is a fine-grained and diverse task in natural language processing. Existing deep learning models for ABSA face the challenge of balancing the demand for finer granularity in sentiment analysis with the scarcity of training corpora for such granularity. To address this issue, we propose an enhanced BERT-based model for multi-dimensional aspect target semantic learning. Our model leverages BERT's pre-training and fine-tuning mechanisms, enabling it to capture rich semantic feature parameters. In addition, we propose a complex semantic enhancement mechanism for aspect targets to enrich and optimize fine-grained training corpora. Third, we combine the aspect recognition enhancement mechanism with a CRF model to achieve more robust and accurate entity recognition for aspect targets. Furthermore, we propose an adaptive local attention mechanism learning model to focus on sentiment elements around rich aspect target semantics. Finally, to address the varying contributions of each task in the joint training mechanism, we carefully optimize this training approach, allowing for a mutually beneficial training of multiple tasks. Experimental results on four Chinese and five English datasets demonstrate that our proposed mechanisms and methods effectively improve ABSA models, surpassing some of the latest models in multi-task and single-task scenarios.
- aspect-based sentiment classification,
- BERT language model,
- adaptive local attention mechanism,
- multiple-task learning
Citation: Quan Zhu, Xiaoyin Wang, Xuan Liu, Wanru Du, Xingxing Ding. Multi-task learning for aspect level semantic classification combining complex aspect target semantic enhancement and adaptive local focus[J]. Mathematical Biosciences and Engineering, 2023, 20(10): 18566-18591. doi: 10.3934/mbe.2023824

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Abstract

Aspect-based sentiment analysis (ABSA) is a fine-grained and diverse task in natural language processing. Existing deep learning models for ABSA face the challenge of balancing the demand for finer granularity in sentiment analysis with the scarcity of training corpora for such granularity. To address this issue, we propose an enhanced BERT-based model for multi-dimensional aspect target semantic learning. Our model leverages BERT's pre-training and fine-tuning mechanisms, enabling it to capture rich semantic feature parameters. In addition, we propose a complex semantic enhancement mechanism for aspect targets to enrich and optimize fine-grained training corpora. Third, we combine the aspect recognition enhancement mechanism with a CRF model to achieve more robust and accurate entity recognition for aspect targets. Furthermore, we propose an adaptive local attention mechanism learning model to focus on sentiment elements around rich aspect target semantics. Finally, to address the varying contributions of each task in the joint training mechanism, we carefully optimize this training approach, allowing for a mutually beneficial training of multiple tasks. Experimental results on four Chinese and five English datasets demonstrate that our proposed mechanisms and methods effectively improve ABSA models, surpassing some of the latest models in multi-task and single-task scenarios.

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