A Transfer Learning-Enabled Optimized Extreme Deep Learning Paradigm for Diagnosis of COVID-19

Many respiratory infections around the world have been caused by coronaviruses.COVID-19 is one of the most serious coronaviruses due to its rapid spread between people and the lowest survival rate.There is a high need for computer-assisted diagnostics(CAD)in the area of artificial intelligence to help doctors and radiologists identify COVID-19 patients in cloud systems.Machine learning(ML)has been used to examine chest X-ray frames.In this paper,a new transfer learning-based optimized extreme deep learning paradigm is proposed to identify the chest X-ray picture into three classes,a pneumonia patient,a COVID-19 patient,or a normal person.First,three different pre-trainedConvolutionalNeuralNetwork(CNN)models(resnet18,resnet25,densenet201)are employed for deep feature extraction.Second,each feature vector is passed through the binary Butterfly optimization algorithm(bBOA)to reduce the redundant features and extract the most representative ones,and enhance the performance of the CNN models.These selective features are then passed to an improved Extreme learning machine(ELM)using a BOA to classify the chest X-ray images.The proposed paradigm achieves a 99.48%accuracy in detecting covid-19 cases.

Deep kernel extreme learning machine classifier based on the improved sparrow search algorithm

In the classification problem,deep kernel extreme learning machine(DKELM)has the characteristics of efficient processing and superior performance,but its parameters optimization is difficult.To improve the classification accuracy of DKELM,a DKELM algorithm optimized by the improved sparrow search algorithm(ISSA),named as ISSA-DKELM,is proposed in this paper.Aiming at the parameter selection problem of DKELM,the DKELM classifier is constructed by using the optimal parameters obtained by ISSA optimization.In order to make up for the shortcomings of the basic sparrow search algorithm(SSA),the chaotic transformation is first applied to initialize the sparrow position.Then,the position of the discoverer sparrow population is dynamically adjusted.A learning operator in the teaching-learning-based algorithm is fused to improve the position update operation of the joiners.Finally,the Gaussian mutation strategy is added in the later iteration of the algorithm to make the sparrow jump out of local optimum.The experimental results show that the proposed DKELM classifier is feasible and effective,and compared with other classification algorithms,the proposed DKELM algorithm aciheves better test accuracy.

State of health estimation for lithium-ion battery based on particle swarm optimization algorithm and extreme learning machine

Lithium-ion battery State of Health(SOH)estimation is an essential issue in battery management systems.In order to better estimate battery SOH,Extreme Learning Machine(ELM)is used to establish a model to estimate lithium-ion battery SOH.The Swarm Optimization algorithm(PSO)is used to automatically adjust and optimize the parameters of ELM to improve estimation accuracy.Firstly,collect cyclic aging data of the battery and extract five characteristic quantities related to battery capacity from the battery charging curve and increment capacity curve.Use Grey Relation Analysis(GRA)method to analyze the correlation between battery capacity and five characteristic quantities.Then,an ELM is used to build the capacity estimation model of the lithium-ion battery based on five characteristics,and a PSO is introduced to optimize the parameters of the capacity estimation model.The proposed method is validated by the degradation experiment of the lithium-ion battery under different conditions.The results show that the battery capacity estimation model based on ELM and PSO has better accuracy and stability in capacity estimation,and the average absolute percentage error is less than 1%.

Swarm-Based Extreme Learning Machine Models for Global Optimization

Extreme Learning Machine(ELM)is popular in batch learning,sequential learning,and progressive learning,due to its speed,easy integration,and generalization ability.While,Traditional ELM cannot train massive data rapidly and efficiently due to its memory residence,high time and space complexity.In ELM,the hidden layer typically necessitates a huge number of nodes.Furthermore,there is no certainty that the arrangement of weights and biases within the hidden layer is optimal.To solve this problem,the traditional ELM has been hybridized with swarm intelligence optimization techniques.This paper displays five proposed hybrid Algorithms“Salp Swarm Algorithm(SSA-ELM),Grasshopper Algorithm(GOA-ELM),Grey Wolf Algorithm(GWO-ELM),Whale optimizationAlgorithm(WOA-ELM)andMoth Flame Optimization(MFO-ELM)”.These five optimizers are hybridized with standard ELM methodology for resolving the tumor type classification using gene expression data.The proposed models applied to the predication of electricity loading data,that describes the energy use of a single residence over a fouryear period.In the hidden layer,Swarm algorithms are used to pick a smaller number of nodes to speed up the execution of ELM.The best weights and preferences were calculated by these algorithms for the hidden layer.Experimental results demonstrated that the proposed MFO-ELM achieved 98.13%accuracy and this is the highest model in accuracy in tumor type classification gene expression data.While in predication,the proposed GOA-ELM achieved 0.397which is least RMSE compared to the other models.

Extreme learning with chemical reaction optimization for stock volatility prediction

Extreme learning machine(ELM)allows for fast learning and better generalization performance than conventional gradient-based learning.However,the possible inclusion of non-optimal weight and bias due to random selection and the need for more hidden neurons adversely influence network usability.Further,choosing the optimal number of hidden nodes for a network usually requires intensive human intervention,which may lead to an ill-conditioned situation.In this context,chemical reaction optimization(CRO)is a meta-heuristic paradigm with increased success in a large number of application areas.It is characterized by faster convergence capability and requires fewer tunable parameters.This study develops a learning framework combining the advantages of ELM and CRO,called extreme learning with chemical reaction optimization(ELCRO).ELCRO simultaneously optimizes the weight and bias vector and number of hidden neurons of a single layer feed-forward neural network without compromising prediction accuracy.We evaluate its performance by predicting the daily volatility and closing prices of BSE indices.Additionally,its performance is compared with three other similarly developed models—ELM based on particle swarm optimization,genetic algorithm,and gradient descent—and find the performance of the proposed algorithm superior.Wilcoxon signed-rank and Diebold–Mariano tests are then conducted to verify the statistical significance of the proposed model.Hence,this model can be used as a promising tool for financial forecasting.

基于IAOA-KELM的储气库注采管柱内腐蚀速率预测

针对储气库注采管柱的内腐蚀速率预测问题,建立了基于阿基米德优化算法(Archimedes Optimization Algorithm,AOA)与核极限学习机(Kernel Extreme Learning Machine,KELM)相结合的模型提高腐蚀速率预测精度。通过引入佳点集、改进密度降低因子、采用黄金正弦算法缩小搜索空间,提高局部开发能力,利用改进阿基米德优化算法(Improved Archimedes Optimization Algorithm,IAOA)优化KELM正则化系数(C)和核函数参数(γ),进而建立IAOA-KELM储气库注采管柱内腐蚀速率预测模型;使用MATLAB软件运用该模型对某注采管柱内腐蚀数据集进行学习与预测,将IAOA-KELM模型与KELM、粒子群优化算法(Particle Swarm Optimization,PSO)-KELM、AOA-KELM结果进行预测误差对比。结果表明,IAOA-KELM模型的预测值与实际值较为拟合,其E RMSE为0.65%,E MAE为0.39%,R 2为99.83%,均优于其他模型。研究表明,IAOA-KELM模型能够更为准确地预测储气库注采管柱内腐蚀速率,为储气库注采管柱的运维及储气库的健康管理提供参考。

基于AdaBoost.M2-ISSA-ELM算法的电力变压器故障诊断方法

为提高电力变压器故障诊断精度,将集成学习和群体智能优化算法相结合,提出一种电力变压器故障诊断方法。使用极限学习机(ELM)作为基学习算法,构建集成学习框架下的基分类器,并针对ELM模型性能受参数初始化影响较大、易陷入局部最优问题,引入基于正弦优化的改进麻雀搜索算法(ISSA)优化相关参数,提高基分类器的分类性能。使用改进的自适应增强(AdaBoost.M2)算法构建集成学习模型,扩展基分类器的输出,并引入伪损失函数替代传统AdaBoost算法中的加权误差,以增强集成分类器综合表达能力,得到基于AdaBoost.M2-ISSA-ELM算法的电力变压器故障诊断模型,进一步提高模型识别精度。通过909组油中溶解气体分析(DGA)样本对所提方法进行实例分析,结果表明该方法具有较好的诊断精度和分类性能,能够实现电力变压器故障类型的准确识别。

基于改进Q学习算法和组合模型的超短期电力负荷预测

单一模型在进行超短期负荷预测时会因负荷波动而导致预测精度变差,针对此问题,提出一种基于深度学习算法的组合预测模型｡首先,采用变分模态分解对原始负荷序列进行分解,得到一系列的子序列。其次,分别采用双向长短期记忆网络和优化后的深度极限学习机对每个子序列进行预测。然后,利用改进Q学习算法对双向长短期记忆网络的预测结果和深度极限学习机的预测结果进行加权组合,得到每个子序列的预测结果。最后,将各个子序列的预测结果进行求和,得到最终的负荷预测结果。以某地真实负荷数据进行预测实验,结果表明所提预测模型较其他模型在超短期负荷预测中表现更佳,预测精度达到98%以上。

基于VMD-LILGWO-LSSVM短期风电功率预测

目的为了减小风电功率并入国家电网时产生的频率波动,提高风电功率预测精度,方法提出一种结合变分模态分解(VMD)、改进灰狼算法(LILGWO)和最小二乘支持向量机(LSSVM)的风电功率短期预测方法。首先通过VMD方法将风电功率序列分解重构成3个复杂程度性不同的模态分量,降低风电功率的波动性;其次使用LSSVM挖掘各分量的特征信息,对各分量分别进行预测,针对LSSVM模型中重要参数的选取对预测精度影响较大问题,引入LILGWO对参数进行寻优;最后将各分量预测结果叠加重构,得到最终预测风电功率。结果以宁夏回族自治区某地区风电站实际数据为例,对未来三天分别进行预测取平均值,本文方法的预测平均绝对误差(mean absolute error,MAE)为2.7068 kW,均方根误差(root mean square error,RMSE)为2.0211,拟合程度决定系数(R-Square,R^(2))为0.9769,与对比方法3~6相比,RMSE分别降低了40.93%,25.21%,14.7%,6.24%;MAE分别降低了42.34%,28.04%,16.97%,7.77%;R^(2)分别提升了4.21%,1.78%,0.82%,0.28%。预测时长方面,BP和LSSVM平均训练时间分别是10,138 s,虽然LSSVM预测时间较长但效果最好,采用PSO、GWO、LILGWO对LSSVM进行寻优后训练时间分别平均缩短了39,44,58 s。结论仿真验证了所提方法在短期风电功率预测方面的有效性。

基于WOA-ELM的空间分层结构FBG三维振动加速度传感器非线性解耦

针对三维振动加速度传感器存在的维间耦合干扰问题,以空间分层结构光纤布拉格光栅(FBG)三维振动加速度传感器为研究对象,阐述了三维振动加速度传感的基本原理。其次,构建了振动加速度动态标定实验平台,并分析了传感器的结构耦合特性。最后,提出一种基于鲸鱼算法优化极限学习机(WOA-ELM)的神经网络模型并进行了非线性解耦实验,其结果显示,在x、y、z三轴的平均测量误差分别降至1.58%、1.17%、0.95%,平均I类和II类误差最大值分别降至0.73%和0.37%。为验证解耦效果,将WOA-ELM与其他算法等进行解耦效果对比。结果表明,WOA-ELM更有效地降低三维振动加速度传感器的维间耦合干扰,提高测量精度。

基于手机传感器识别行人步态的PSO-ELM算法

针对因手机携带位置不同对传感器产生干扰而导致行人步态识别准确率降低的问题,提出了一种粒子群优化极限学习机(PSO-ELM)识别算法。首先,基于极限学习机(ELM)分类方法,借助分层ELM多层降维的特点,利用粒子群优化算法对ELM算法参数进行寻优,设计有效识别行人手机携带位置的分层PSO-ELM分类方法。然后,通过线性判别分析的降维算法和PSO-ELM完成对行人步态的有效识别。实验使用Android手机对五种携带位置四种步态下的加速度和角速度数据进行采集,结果表明:在识别手机携带位置层面,训练集与测试集的识别准确率分别达到99.54%、99.47%;在识别行人步态层面,两种准确率分别达到95.74%、95.31%,证明所提算法具有较高的步态识别准确率。

基于改进ELM和计算机视觉的核桃缺陷检测

目的:解决现有食品生产企业在核桃缺陷检测中存在的准确性低和效率差等问题。方法:提出一种结合改进极限学习机和计算机视觉的核桃缺陷快速无损检测方法。通过计算机视觉采集核桃大部分表面图像信息,通过高斯滤波对图像进行预处理,通过迭代和保留信息变量法对颜色和纹理特征进行优化,最后,通过改进蝴蝶算法对极限学习机参数(随机权重和偏差)进行优化,实现核桃缺陷快速无损检测,并对所提缺陷检测方法的性能进行验证。结果:试验方法可以实现核桃多种缺陷的有效判别。与常规方法相比,试验方法在核桃缺陷检测中具有更优的检测准确率和效率,检测准确率>98.00%,平均检测时间<9.00 ms。结论:将智能算法和机器视觉技术相结合可以实现核桃缺陷的快速无损检测。

基于GMPE和GWO-MKELM算法的往复压缩机轴承故障诊断

针对往复压缩机内部结构复杂,轴承间隙故障特征提取困难和识别准确率不高等问题,提出了多尺度排列熵和多核极限学习机混合算法的智能诊断新方法。首先,针对多尺度排列熵在多尺度过程中,利用均值粗粒化的方式在一定程度上“中和”了原始信号的动力学突变行为,降低了熵值分析的准确性,提出了一种广义多尺度排列熵算法;然后,为解决核极限学习机处理复杂数据样本分类存在的局限性,将高斯核函数、多项式核函数和感知器核函数进行线性叠加,构建混合核函数,提出了多核极限学习机模型。仿真实验结果表明,该故障诊断方法识别准确率高达98%,高效地实现了轴承不同种类故障的智能诊断。

基于改进DELM在不同放电工况下的锂电池SOH预测方法研究

锂电池性能受到多种因素的影响,尤其在不同放电工况下其健康状态(SOH)预测难度极大增加.因此,研究以基于深度极限学习机为基础的锂电池SOH预测方法为基础,利用改进鲸鱼优化算法解决深度极限学习机中存在的随机权重和偏置问题,旨在提高锂电池SOH预测的精确率.对比实验结果表明,研究提出的预测方法算法的误差在[-0.02,0.04]之间,平均精确率达到96.23%,相比利用麻雀搜索算法、灰狼优化算法,改进的深度极限学习机算法分别提升了9.67%和5.05%.平均召回率为90.83%,平均误报率为3.75%.此外,高负载工况下,100次充放电循环后锂电池SOH值仅有0.221,下降幅度最大.不同工况下研究提出的预测方法平均精确率达到96.07%.研究提出的锂电池健康状态预测方法对于提高电池性能、延长寿命、提高安全性和降低环境影响具有重要的实际意义.

基于改进粒子群算法优化的染色木材颜色检测算法研究

为提高染色木材颜色的检测精度和速度,对樟子松木材单板进行染色,选取染色单板的光谱反射率作为输入,以极限学习机模型为基础构建预测模型,对染色单板的色度参数L^(*)、a^(*)、b^(*)进行预测,运用粒子群算法对ELM权值和阈值进行寻优,并引入非线性惯性权重和新的位置与速度更新策略改进粒子群算法,以消除其易陷入局部最优的缺点。此外,以L^(*)、a^(*)、b^(*)平均绝对误差为评价指标,与基础ELM模型及其他模型作对比,发现优化后的模型平均绝对误差为0.16,测色效果相较于基础ELM的0.68、麻雀算法优化的ELM的0.37等具有明显优势,这对于提高木材染色生产效率具有重要意义。

基于HMFDE和t-SNE的旋转机械故障诊断方法

针对旋转机械的故障特征提取较难,以及单一类型的特征无法全面反映故障特性的问题,提出了一种基于混合多尺度波动散布熵(HMFDE)、t分布-随机邻域嵌入(t-SNE)和郊狼优化算法(COA)优化极限学习机(ELM)的旋转机械故障诊断方法。首先,采用特征加权提出了混合多尺度波动散布熵方法,并将其用于提取旋转机械振动信号的故障特征;随后,采用t-SNE方法对混合故障特征进行了特征降维,挑选出了最能够反映故障特性的特征子集,构建了敏感特征样本;最后,采用郊狼优化算法对极限学习机的输入权重和隐含层阈值进行了优化,完成了旋转机械的故障识别和分类;以齿轮箱和滚动轴承故障数据集为对象,对基于HMFDE、t-SNE和COA-ELM的故障诊断方法进行了实验,验证了方法的有效性。研究结果表明:采用HMFDE-t-SNE-CAO-ELM故障诊断方法可以取得100%的故障识别准确率,该方法能够有效地诊断旋转机械的不同故障类型和损伤;相较于基于单一类型特征的故障诊断方法,其准确率分别可以提高0.68%、22.42%、29.18%(齿轮箱)和1.43%、8.23%、23.67%(滚动轴承),虽然牺牲了一定的计算效率,但准确率得到了明显的提高;相较于其他常规故障分类器,COA-ELM的故障识别准确率具有明显的优势。

基于IHHO-HKELM输电线路覆冰预测模型

为了进一步提高输电线路覆冰预测精度,提出一种基于改进哈里斯鹰算法(improved harris hawk optimiza-tion,IHHO)优化混合核极限学习机(hybrid kernel extreme learning machine,HKELM)的输电线路覆冰预测模型。在核极限学习机(KELM)中引入混合核函数,形成HKELM,利用黄金正弦、非线性递减能量指数和高斯随机游走等策略对IHHO算法进行改进;以IHHO算法的优化性能采用其对HKELM的权值向量和核参数进行优化,建立基于IHHO-HKELM的输电线路覆冰预测模型,并通过计算气象因素与覆冰厚度之间的灰色关联度确定覆冰预测模型的输入量。算例分析结果表明,IHHO-HKELM模型预测结果的均方误差、最大误差和平均相对误差分别为0.285、0.860 mm和2.83%,预测效果好于其他模型,将本文覆冰预测模型应用于其他覆冰线路,可获得良好的应用效果并验证模型的优越性和实用性。

基于WPT-IDBO-RELM和WPT-IDMO-RELM模型的日径流预测

为提高日径流时间序列预测精度,改进正则化极限学习机(RELM)的预测性能,对比验证改进蜣螂优化(IDBO)算法和改进侏獴优化(IDMO)算法与其他算法的优化效果,提出了基于小波包变换(WPT)的WPT-IDBO-RELM和WPT-IDMO-RELM日径流时间序列预测模型。对云南省暮底河水库、马鹿塘电站入库日径流进行预测,结果表明WPT-IDBO-RELM和WPT-IDMO-RELM模型对暮底河水库日径流预测的平均绝对百分比误差分别为1.048%、1.015%,对马鹿塘电站日径流预测的平均绝对百分比误差分别为1.493%、1.478%,优于其他对比模型;IDBO、IDMO算法对标准测试函数和实例目标函数的寻优效果均优于其他对比算法,且IDBO、IDMO算法优化效果越好,RELM超参数越优,WPT-IDBO-RELM、WPT-IDMO-RELM模型预测精度越高;WPT可将日径流序列分解为分量更少、规律性更强的子序列分量,在提高预测精度的同时显著降低模型复杂度和计算规模。

基于数据分解与斑马算法优化的混合核极限学习机月径流预测

为提高月径流预测精度,改进混合核极限学习机(HKELM)预测性能,提出小波包分解(WPT)-斑马优化算法(ZOA)-HKELM组合模型。利用WPT处理月径流时序数据,构建局部高斯径向基核函数和全局多项式核函数相混合的HKELM;通过ZOA优化HKELM超参数(正则化参数、核参数、权重系数),建立WPT-ZOA-HKELM组合模型,并构建WPT-遗传算法(GA)-HKELM、WPT-灰狼优化(GWO)算法-HKELM、WPT-鲸鱼优化算法(WOA)-HKELM、WPT-ZOA-极限学习机(ELM)、WPT-ZOA-最小二乘支持向量机(LSSVM)、ZOA-HKELM作对比模型,通过黑河流域莺落峡、讨赖河水文站月径流时间序列预测实例对各模型进行检验。结果表明:(1)莺落峡、讨赖河水文站月径流时间序列WPT-ZOA-HKELM模型预测的平均绝对百分比误差分别为1.054%、0.761%,决定系数均达0.999 9,优于其他对比模型,具有更高的预测精度,预测效果更好。(2)利用ZOA优化HKELM超参数,可提高HKELM预测性能,优化效果优于GWO、WOA、GA。(3)预测模型能充分发挥WPT、ZOA和HKELM优势,提高月径流预测精度;在相同分解和优化情形下,HKELM的预测性能优于ELM、LSSVM。

基于GRO优化的VMD-HKELM月蒸发量预测方法研究

水面蒸发预测对于水库水量预测、区域水量平衡分析和水资源量核算等具有重要意义。水面蒸发量预测影响因素众多,并最终体现在随时间变化的蒸发量监测数据中。为此,基于淘金热(GRO)算法优化变分模态分解(VMD)-混合核极限学习机(HKELM)提出两种方案。方案Ⅰ先对月蒸发量时间序列分解,后划分训练集、测试集;方案Ⅱ先对月蒸发量划分训练集、测试集,再进行时间序列分解。通过一种新型元启发式算法对分解技术VMD、预测器HKELM超参数进行目标寻优并建立多种模型,采用云南省龙潭寨、西洋街水文站月蒸发量预测实例对方案Ⅰ、方案Ⅱ各模型进行检验。结果表明:方案Ⅰ各模型性能优于方案Ⅱ,各模型的拟合精度和预测精度总体上随分解分量数的增加而提高,但方案Ⅰ使用了测试集信息,导致预测精度虚高;方案Ⅱ各模型具有较好的预测精度和稳健性能,其用于月蒸发量时间序列预测是可行的,反映出客观真实的预测效果,具有较好的实用价值和意义。