首页|期刊导航|华南理工大学学报(自然科学版)|融合增量学习机制的COA-BP模型及其线形预测

融合增量学习机制的COA-BP模型及其线形预测OA

A COA-BP Model Incorporating Incremental Learning Mechanism and Its Linear Prediction

中文摘要英文摘要

在进行大跨度连续刚构桥悬臂施工线形控制时,现有预测方法在模型构建与学习机制两方面存在系统性缺陷(传统方法非线性拟合能力弱,机器学习模型易陷入局部最优或泛化性能不足,且普遍采用"离线训练、固定参数"的静态建模范式),难以动态适应施工过程中结构响应的时变特性与误差累积规律.为克服该问题,研究提出一种融合小龙虾优化算法(COA)与BP神经网络的COA-BP模型,并创新性引入增量学习机制.首先,基于FEA NX建立精细化实体有限元模型,结合混凝土容重、弹性模量、预应力张拉控制应力等关键参数的变异性,采用拉丁超立方群抽样生成输入参数组合,反算各梁段理论立模标高;实测标高由现场施工完成后获取,二者差值作为模型输出目标.然后通过COA算法优化BP网络的初始权值与阈值,有效提升模型收敛速度与全局搜索能力.在此基础上,设计分阶段学习策略,3、4、5号块为静态学习阶段,利用实测与理论标高差值完成模型初始化,从6号块起进入增量学习阶段,模型基于预测结果指导立模标高调整,并在每阶段施工完成后将新实测数据对应的标高差值纳入训练集,实现"边施工、边学习、边优化"的动态闭环.研究还依托实际连续刚构桥工程进行验证,结果表明,6号块纠偏后最大误差为-1.8 mm,后续梁段预测误差持续收敛,预测曲线平滑下降,显著优于传统方法的预测效果,验证了所提出COA-BP模型在提升线形预测精度与适应性方面的有效性.

In the linear control of cantilever construction for long-span continuous rigid-frame bridge,existing pre-diction methods exhibit systemic deficiencies in both model construction and learning mechanisms.The traditional methods suffer from weak nonlinear fitting capabilities,while machine learning models are prone to local optima or insufficient generalization performance.In addition,most methods adopt a static modeling paradigm characterized by offline training and fixed parameters,which makes it difficult to dynamically adapt to the time-varying characte-ristics of structural responses and the accumulation of errors during construction.To overcome this problem,this study proposes a COA-BP model combining crayfish optimization algorithm(COA)and BP neural network,and in-novatively introduces an incremental learning mechanism.Firstly,based on FEA NX,a refined solid finite element model was established.Considering the variability of key parameters such as concrete unit weight,elastic modulus and prestressed tension control stress,the Latin hypercube sampling was used to generate the input parameter com-bination,and the theoretical formwork elevation of each beam section was inversely calculated.The measured ele-vation was obtained after the completion of the site construction,and the difference between the two was used as the output target of the model.Then,the COA algorithm was used to optimize the initial weights and thresholds of the BP network,effectively improving the model's convergence speed and global search capability.On this basis,a phased learning strategy was designed:segments No.3,4,and 5 were used for the static learning phase,where the model is initialized using the differences between measured and theoretical elevations.From block 6 onwards,the incremental learning phase begins,during which the model guides the adjustment of formwork placement elevations based on prediction results.After each construction phase,the elevation differences corresponding to newly mea-sured data were incorporated into the training set,enabling a dynamic closed loop of"construction,learning,and op-timization in parallel."The proposed method is validated using an actual continuous rigid-frame bridge project.The results show that after the correction at segment No.6,the maximum error is reduced to-1.8 mm,and the pre-diction errors for subsequent beam segments converge continuously,with a smoothly declining prediction curve.This performance is significantly superior to that of traditional methods,demonstrating the effectiveness of the pro-posed COA-BP model in improving the accuracy and adaptability of linear prediction.

邬晓光;邓志海;汪俊光;侯学军;李红

长安大学 公路学院,陕西 西安 710064长安大学 公路学院,陕西 西安 710064长安大学 公路学院,陕西 西安 710064长安大学 公路学院,陕西 西安 710064||中交路桥建设有限公司海外分公司,北京 100010中交路桥建设有限公司海外分公司,北京 100010

交通工程

线形预测连续刚构桥小龙虾算法BP神经网络增量学习COA-BP模型桥梁工程

linear predictioncontinuous rigid-frame bridgecrayfish algorithmBP neural networkincre-mental learningCOA-BP modelbridge engineering

《华南理工大学学报(自然科学版)》 2026 (5)

96-107,12

广西重点研发计划科技发展专项(2024AB15010)Supported by the Guangxi Key Research and Development Program Science and Technology Development Project(2024AB15010)

10.12141/j.issn.1000-565X.250359

评论