基于IWOA-HKELM的矿井突水水源识别

doi:10.16265/j.cnki.issn1003-3033.2019.09.018

中国安全科学学报 ›› 2019, Vol. 29 ›› Issue (9): 113-118.doi: 10.16265/j.cnki.issn1003-3033.2019.09.018

基于IWOA-HKELM的矿井突水水源识别

邵良杉教授, 詹小凡

辽宁工程技术大学系统工程研究所,辽宁葫芦岛 125105

收稿日期:2019-05-14 修回日期:2019-07-13 出版日期:2019-09-28 发布日期:2020-10-30
作者简介:邵良杉 (1961—),男,辽宁凌源人,博士,教授,博士生导师,主要从事矿业系统工程、大数据等方面的研究。E-mail: lntushao@163.com。
基金资助:
国家自然科学基金资助(71771111)。

Identification method of mine water inrush source based on IWOA-HKELM

SHAO Liangshan, ZHAN Xiaofan

System Engineering Institute, Liaoning Technical University, Huludao Liaoning 125105, China

Received:2019-05-14 Revised:2019-07-13 Online:2019-09-28 Published:2020-10-30

摘要/Abstract

摘要： 为提高矿井突水水源识别的精度,提出一种改进鲸鱼优化算法(IWOA)-混合核极限学习机(HKELM)的水源识别模型。首先将高斯核函数和多项式核函数相结合,构造学习能力和泛化性能较好的HKELM;然后针对鲸鱼优化算法(WOA)易陷入局部最优的问题,提出IWOA算法,引入帐篷映射、改进非线性因子以及设置反向精英学习阈值等3种策略来降低算法过早收敛的概率,并得到更优结果;最后将新庄孜矿的突水水源资料作为仿真数据,降维处理后输入到IWOA-HKELM模型中结果预测。研究表明:通过IWOA优化HKELM参数,可提高HKELM的整体预测性能;IWOA-HKELM的预测结果与实际情况完全一致,与其他模型相比,该模型的平均分类准确率明显提高,平均均方误差和分类准确率标准差明显降低。

关键词: 突水水源识别, 改进鲸鱼优化算法(IWOA), 混合核极限学习机(HKELM), 帐篷映射, 非线性因子, 反向精英学习阈值

Abstract: In order to improve accuracy in identifying mine water inrush source, an IWOA-HKELM water source identification model is proposed. Firstly, HKELM, featuring better learning ability and generalization performance, was constructed on combined basis of Gaussian kernel function and polynomial kernel function. Secondly, IWOA algorithm was proposed considering that WOA was easy to fall into local optimization. Then, three strategies were introduced to reduce probability of premature convergence and obtain better results, including tent mapping, improvement of non-linear factor and setting of reverse elite learning threshold. Finally, water inrush source data of Xinzhuangzi Mine, being taken as simulation data, was put in IWOA-HKELM model for result prediction after dimension reduction. The results show that optimization of HKELM parameters through IWOA can improve the algorithm's overall prediction performance. Prediction results of IWOA-HKELM are completely consistent with actual situation. Compared with other models, the proposed model obviously excels in terms of average classification accuracy with its average mean square error and standard deviation of classification accuracy being significantly reduced.

Key words: water inrush source identification, improved whale optimization algorithm (IWOA), hybrid nuclear extreme learning machine (HKELM), tent mapping, nonlinear factor, reverse elite learning threshold

中图分类号:

X936

邵良杉, 詹小凡. 基于IWOA-HKELM的矿井突水水源识别[J]. 中国安全科学学报, 2019, 29(9): 113-118.

SHAO Liangshan, ZHAN Xiaofan. Identification method of mine water inrush source based on IWOA-HKELM[J]. China Safety Science Journal, 2019, 29(9): 113-118.

参考文献

[1] 靳德武, 刘英锋, 刘再斌, 等. 基于FCM的煤矿突水激光诱导荧光光谱分析[J]. 煤炭科学技术,2013,41(1): 1 573-1 576.
JIN Dewu, LIU Yingfeng, LIU Zaibin, et al. Laser induced fluorescence spectrum analysis of water inrush in coal mine based on FCM[J]. Coal Science and Technology, 2013, 41(1): 1 573-1 576.
[2] 徐建国, 冯增强. 矿井防治水综合技术[M].徐州:中国矿业大学出版社,2007: 34-39.
[3] 李燕, 徐志敏, 刘勇. 矿井突水水源判别方法概述[J]. 煤炭技术,2010,29(11): 87-89.
LI Yan, XU Zhimin, LIU Yong. Summary on methods for distinguishing sources of mine water-invasion[J]. Coal Technology, 2010, 29(11): 87-89.
[4] 王心义, 徐涛, 黄丹.距离判别法在相似矿区突水水源识别中的应用[J]. 煤炭学报,2011,36(8): 1 354-1 358.
WANG Xinyi, XU Tao, HUANG Dan. Application of distance discrimince in identifying water inrush resource in similar coalmine[J]. Journal of China Coal Society, 2011, 36(8): 1 354-1 358.
[5] 王心义, 赵伟, 刘小满,等.基于熵权-模糊可变集理论的煤矿井突水水源识别[J].煤炭学报,2017,42(9): 2 433-2 439.
WANG Xinyi, ZHAO Wei, LIU Xiaoman, et al. Identification of water inrush source from coalfield based on entropy weight-fuzzy variable set theory [J]. Journal of China Coal Society, 2017, 42(9): 2 433-2 439.
[6] 徐星, 郭兵兵, 王公忠. 人工神经网络在矿井多水源识别中的应用[J].中国安全生产科学技术,2016,12(1): 181-185.
XU Xing, GUO Bingbing, WANG Gongzhong. Application of artificial neural network for recognition of multiple water sources in mine[J]. Journal of Safety Science and Technology, 2016, 12(1): 181-185.
[7] 邵良杉,李印超,徐波. 矿井突水水源识别的RS-LSSVM模型[J].安全与环境学报,2017,17(5): 1 730-1 734.
SHAO Liangshan, LI Yinchao, XU Bo. RS-LSSVM model for identifying and determinating the mining water inrush origin[J].Journal of Safety and Environment,2017,17(5): 1 730-1 734.
[8] 邵良杉, 李相辰. 基于MIV-PSO-SVM 模型的矿井突水水源识别[J]. 煤炭科学技术,2018,46(8): 183-190.
SHAO Liangshan, LI Xiangchen. Identification of mine water inrush source based on MIV-PSO-SVM [J]. Coal Science and Technology, 2018, 46(8): 183-190.
[9] 冯琳. 基于EIM和FCE的矿井突水水源判别研究[D]. 太原:太原理工大学,2015.
FENG Lin. Study of source discrimination of coalmine water inrush based on EIM and FCE [D]. Taiyuan: Taiyuan University of Technology, 2015.
[10] 范君,王新,徐慧.粒子群优化混合核极限学习机的构造煤厚度预测方法[J]. 计算机应用,2018,38(6):1820-1825,1830.
FAN Jun,WANG Xin,XU Hui. Prediction method of tectonic coal thickness based on particle swarm optimized hybrid kernel extreme learning machine[J]. Journal of Computer Applications, 2018,38(6):1820-1825,1830.
[11] Gaganpreet KAUR, Sankalap ARORA. Chaotic whale optimization algorithm[J]. Journal of Computer Design and Engineering,2018,5(3): 275-284.
[12] 王涛,Ryad CHELLALI.非线性权重和收敛因子的鲸鱼算法[J].微电子学与计算机,2019,36(1): 11-15.
WANG Tao,Ryad CHELLAI. Whale optimization algorithm with nonlinear weight and convergence factor[J].Microelectronics &Computer,2019,36(1): 11-15.
[13] 黄亚飞,王国富,张法全,等.基于蜂群算法和带参阈值函数的图像去噪方法[J].计算机工程与应用,2018,54(17): 164-168.
HUANG Yafei, WANG Guofu, ZHANG Faquan, et al. Image denoising method based on bee colony algorithm and parametric threshold function. Computer Engineering andApplications, 2018, 54(17): 164-168.
[14] TIZHOOSH H R. Opposition-based learning: a new scheme for machine intelligence[C]. International Conference on Computational Intelligence for Modelling, Control and Automation 2005: 695-701.
[15] 毛志勇,黄春娟,路世昌,等.基于KPCA-MPSO-ELM的矿井突水水源判别模型[J].中国安全科学学报,2018,28(8): 111-116.
MAO Zhiyong, HUANG Chunjuan, LU Shichang, et al. KPCA-MPSO-ELM based model for discrimination of mine water inrush source [J]. China Safety Science Journal,2018, 28(8): 111-116.
[16] 关秋红.新庒孜井田地下水化学特征及突水水源快速判别模型[D].合肥:合肥工业大学,2009.
GUAN Qiuhong. Chemical characteristics of groundwater and discriminate models of water bursting source in Xinzhuangzi coalfield of Huainan mining area[D]. Hefei: Hefei University of Technology, 2009.

基于IWOA-HKELM的矿井突水水源识别

Identification method of mine water inrush source based on IWOA-HKELM

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