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基于融合深度学习的核事故源项反演方法研究OA

Performance evaluation of fusion deep learning models for source term inversion in complex nuclear accident scenarios

中文摘要英文摘要

摘 要:在核事故中,放射性源项的准确估算是事故后果评估与应急响应的关键环节.然而,在事故的瞬态阶段,监测数据往往受高温、强辐射及设备损坏等因素影响而难以及时获取.为此,本研究提出两类基于深度学习的融合源项反演模型,以提升反演精度与鲁棒性.其一为 LSTM-Transformer 模型,利用长短期记忆网络(LSTM)在处理时间序列长期依赖、非平稳性及梯度稳定性方面的优势,捕捉放射性核素扩散的动态演化特征,并引入Transformer 结构,通过自注意力机制建模序列中不同时间步的全局依赖关系,增强长距离信息感知能力.其二为双分支融合 LSTM 模型(dual-branch fusion LSTM,DBL-LSTM),通过并行 LSTM 网络分别提取 γ 剂量率与气象参数特征,再经融合 LSTM 综合建模,提高多源数据的联合分析能力,并增强对气象变化和噪声的适应性.引入Optuna自动化超参数优化算法,以进一步提升反演精度并减少人工调参的不确定性.基于国际放射性评价系统(InterRAS)生成的模拟数据,对Sr-91、Te-132 和I-131 三种短寿命核素的释放率进行估算,并以单一LSTM 模型作为对照,采用平均相对误差(δ)作为评价指标.结果表明,单一 LSTM 模型在三种核素上的 δ分别为 15.10%、8.20%和 27.33%;LSTM-Transformer 模型分别为 13.90%、5.63%和 25.63%;DBL-LSTM 模型分别为 13.34%、4.93%和 24.21%.源项反演计算中融合模型相较单一 LSTM 模型在精度与鲁棒性方面均表现出一定提升,凸显其在核事故应急场景中的应用潜力.

During nuclear accidents,accurate estimation of source term parameters is a critical component of nclear accident consequence assessment and emergency response.However,during the transient phase of an accident,timely acquisition of monitoring data is frequently hindered by conditions including high temperature,intense radiation,and instrumentation failure.Therefore,this paper proposes two deep learning-based integrated models for source term inversion to enhance both accuracy and robustness.The first model is an LSTM-Transformer hybrid architecture,which fully utilizes the advantages of the Long Short-Term Memory(LSTM)network in handling long-term dependencies,non-stationarity,and gradient stability in time series,thereby effectively capturing the dynamic evolution of radioactive nuclide dispersion.It also introduces the Transformer structure to leverage self-attention to modelglobal dependencies between different time steps in the·124·sequence,significantly enhancing long-range contextual awareness.The second model is a dual-branch fusion LSTM model(Dual-Branch LSTM with Fusion,DBL-LSTM),which employs two parallel LSTM networks to independently extract features from gamma dose rate measurements and meteorological parameters,followed by feature-level integration via a fusion LSTM model for comprehensive modeling.This approach improves the capability for joint analysis of multi-source data and enhances adaptability to meteorological variability and noise.The Optuna automated hyperparameter optimization algorithm is integrated to further improve inversion accuracy and reduce uncertainties in manual parameter tuning.Based on the simulated data generated by the International Radioactive Assessment System(InterRAS),the release rates of three short-lived nuclides,Sr-91,Te-132,and I-131,were estimated,with a single LSTM model serving as the baseline comparator and the Mean Absolute Percentage Error(MAPE)as the evaluation indicator.Results indicate that the single LSTM achieved MAPE values of 15.10%,8.20%,and 27.33%for 91 Sr,132 Te,and 131 I respectively;the LSTM-Transformer model reduced these to 13.90%,5.63%,and 25.63%;and the DBL-LSTM achieved further improvements,yielding MAPEs of 13.34%,4.93%,and 24.21%.The integrated models demonstrate consistent improvements in both inversion accuracy and robustness relative to the single LSTM model,highlighting their potential for application in nuclear accident emergency scenarios.

聂时伟;林佳铖;杨文栋;贾文宝;凌永生

南京航空航天大学核科学与技术系,南京 211106南京航空航天大学核科学与技术系,南京 211106南京航空航天大学核科学与技术系,南京 211106南京航空航天大学核科学与技术系,南京 211106南京航空航天大学核科学与技术系,南京 211106||江苏省高校放射医学协同创新中心,江苏 苏州 215021

能源科技

核事故源项反演深度学习超参数优化

nuclear accidentsource term inversiondeep learninghyperparameter optimization

《辐射防护》 2026 (2)

116-125,10

国家自然科学基金面上项目(12475317)南京航空航天大学研究生科研与实践创新计划(xcxjh20250615).

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