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| Prediction of spatial radiation characteristics of aerodynamic noise in centrifugal compressors based on transfer learning |
Shuaining LIU( ),Xu ZHAN,Chen LIU*(),Guixin WANG |
| College of Energy and Power Engineering, Harbin Engineering University, Harbin 150001, China |
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Abstract A transfer learning-driven aerodynamic noise spatial radiation characteristics prediction method was proposed to address the challenge of modeling the spatial radiation characteristics of compressor aerodynamic noise under small-sample conditions. A hybrid computational aeroacoustics (CAA) approach coupling Computational Fluid Dynamics (CFD) with the Boundary Element Method (BEM) was adopted to perform multi-condition aerodynamic noise numerical simulation for Compressor A. Simultaneously, multi-measurement-point experimental data were collected to complete accuracy verification of the numerical simulation model. Based on extensive simulation data of the target domain under a specific operating condition for Compressor B, a random forest-based pre-trained model was constructed and trained to extract common features of aerodynamic noise spatial radiation. Using a small amount of labeled data from the target domain under a specific operating condition of Compressor A, feature transfer and parameter fine-tuning were implemented on the pre-trained model to establish a transfer learning model adapted to Compressor A, enabling accurate prediction of aerodynamic noise radiation characteristics. Comparative verification indicated that the proposed transfer learning model exhibited significantly superior prediction accuracy and stability compared to traditional machine learning methods. The prediction error of the overall sound pressure level for most measurement points was controlled within 3 dB, and the model demonstrated excellent robustness and generalization ability under small-sample scenarios, thus providing reliable technical support for the rapid prediction of aerodynamic noise in different types of compressors.
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Received: 08 May 2025
Published: 19 March 2026
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| Fund: 国家自然科学基金资助项目(52201356). |
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Corresponding Authors:
Chen LIU
E-mail: 13654390343@163.com;liuchen_hrbeu@hrbeu.edu.cn
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基于迁移学习的离心压气机气动噪声空间辐射特性预测
针对小样本条件下压气机气动噪声空间辐射特性建模难题,提出基于迁移学习的气动噪声空间辐射特性预测方法. 采用计算流体力学(CFD)与声学边界元法(BEM)耦合的混合计算气动声学(CAA)方法,针对压气机A开展多工况气动噪声数值模拟,并采集试验数据对数值仿真模型精度进行验证. 依托压气机B某工况下目标域大量仿真数据,构建并训练基于随机森林的预训练模型,提取气动噪声空间辐射共性特征;在此基础上,借助压气机A某工况下目标域少量标注数据,对预训练模型实施特征迁移与参数微调,构建适配压气机A的迁移学习模型,实现目标域气动噪声辐射特性精准预测. 研究结果显示,所提迁移学习模型预测精度与稳定性显著优于传统机器学习方法,绝大多数测点总声压级预测误差控制小于3 dB,且在小样本场景下具备良好的鲁棒性与泛化性,能为不同型号压气机气动噪声快速预测提供可靠技术支撑.
关键词:
离心压气机,
气动噪声,
空间辐射特性,
迁移学习,
随机森林
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