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基于LSTM多尺度共生关系挖掘的测井曲线复原

韩建 李婧 曹志民 高攀

韩建, 李婧, 曹志民, 高攀. 基于LSTM多尺度共生关系挖掘的测井曲线复原[J]. 电子与信息学报, 2022, 44(7): 2559-2567. doi: 10.11999/JEIT210424
引用本文: 韩建, 李婧, 曹志民, 高攀. 基于LSTM多尺度共生关系挖掘的测井曲线复原[J]. 电子与信息学报, 2022, 44(7): 2559-2567. doi: 10.11999/JEIT210424
HAN Jian, LI Jing, CAO Zhimin, GAO Pan. Logging Curve Recovery Based on LSTM Multi-scale Symbiotic Relationship Mining[J]. Journal of Electronics & Information Technology, 2022, 44(7): 2559-2567. doi: 10.11999/JEIT210424
Citation: HAN Jian, LI Jing, CAO Zhimin, GAO Pan. Logging Curve Recovery Based on LSTM Multi-scale Symbiotic Relationship Mining[J]. Journal of Electronics & Information Technology, 2022, 44(7): 2559-2567. doi: 10.11999/JEIT210424

基于LSTM多尺度共生关系挖掘的测井曲线复原

doi: 10.11999/JEIT210424
基金项目: 国家自然科学基金(51574087)
详细信息
    作者简介:

    韩建:男,1976年生,教授,研究方向为测井参数、注汽井干度检测

    李婧:女,1998年生,硕士生,研究方向为信号处理、测井数据复原

    曹志民:男,1980年生,副教授,研究方向为模式识别、勘探开发大数据分析

    高攀:男,1997年生,硕士生,研究方向为信号处理、测井数据超分辨

    通讯作者:

    曹志民 caozhimin@nepu.edu.cn

  • 中图分类号: TN911.7; TP391

Logging Curve Recovery Based on LSTM Multi-scale Symbiotic Relationship Mining

Funds: The National Natural Science Foundation of China (51574087)
  • 摘要: 利用测井数据进行储层地质描述的应用中,经常出现部分测井曲线失真或缺失的问题,为此,测井曲线复原一直以来都是相关研究领域的研究热点和难点。传统信号复原方法和基于神经网络等机器学习的复原方法,对同井不同测井曲线间关联信息的表示和利用不充分,跨井模型适应能力差。针对这些问题,该文提出一种基于长短时记忆(LSTM)网络多尺度共生关系挖掘的测井曲线复原方法:在基于神经网络测井曲线复原方法的基础上,通过引入多尺度灰度共生短阵(GLCM)关系完成对不同测井曲线间横向关联信息的表征以实现测井曲线集纵横向语义信息的全面利用,进而实现缺失测井曲线的复原。实验结果表明,与BP神经网络、随机森林(RF)、GBDT、深度森林(DF)和LSTM网络方法相比,该文所提方法具有更好的信号复原精度,且所构建模型具有一定的井间适应能力。
  • 图  1  测井曲线预测模型图

    图  2  A1井多尺度下DEN测井曲线复原结果

    图  3  A1井6组近邻井DEN复原结果

    图  4  不同模型测井曲线复原结果对比图

    图  5  A2井DEN预测结果的频谱分析图

    表  1  基于LSTM多尺度共生关系挖掘的测井曲线复原算法

     输入:训练数据集${\boldsymbol{P} } = \left\{ { { {\boldsymbol{p} }_i} \in {R^{M \times 1} },i = 1,2, \cdots ,N} \right\}$,目标井
        数据集
        ${\boldsymbol{P} }_r^{ {{\rm{target}}} } = \left\{ { {\boldsymbol{p} }_i^{ {\text{target} } } \in {R^{ {M_t} \times 1} },i = 1,2, \cdots ,N - 1} \right\}$
     输出:复原目标曲线$ {\boldsymbol{p}}_N^{{\text{target}}} \in {R^{{M_t} \times 1}} $
     相关模型训练:
     (1) 将训练数据集进行多尺度灰度化;
     (2) 生成灰度共生矩阵集${\bf{GLCM} } = {\left\{ { { {\bf{GLCM} }_i} } \right\}_{i = 1,2, \cdots ,N - 1} }$;
     (3) 训练生成式(5)中的$ {\beta _1} $和$ {\beta _2} $;
     (4) 训练多尺度灰度共生关系测井曲线复原LSTM网络;
     测试井未知曲线复原:
     (5) 测试井已知母曲线多尺度灰度化;
     (6) 令$ {g_j} \in [32,64,128,256] $为4个多尺度灰度级,进行多尺度
        曲线复原:
        For j=1:4
          (a) 直接共生关系复原目标曲线$ {\boldsymbol{p}}_{N,{\text{dir}}}^{{\text{target}}} $;
          (b) 鲁棒共生关系复原目标曲线$ {\boldsymbol{p}}_{N,{\text{rob}}}^{{\text{target}}} $:
             For m=1:Mt
             ① If m==1,复制步骤(6a)得到目标曲线样本
             序号为1的值;
             ② If m==m+1,更新灰度共生矩阵后获取直
             接共生关系复原值;
             ③ m=m+1,依次进行迭代;
             End
          (c) 利用式(5)完成目标曲线融合:
             $ {\boldsymbol{p}}_{N,{\text{glcm}}}^{{\text{target}}} = {\beta _1}{\boldsymbol{p}}_{N,{\text{dir}}}^{{\text{target}}} + {\beta _2}{\boldsymbol{p}}_{N,{\text{rob}}}^{{\text{target}}} $
          End
     (7) 得到的多尺度复原结果结合LSTM网络最终复原出目标曲线。
    下载: 导出CSV

    表  2  各个方法超参数设置表

    方法参数设置
    BP神经网络隐藏层为9,学习率为0.01,最大迭代次数为200,训练精度阈值为10–3
    随机森林树的个数为50,最大叶子数为10
    GBDT学习率为0.1,最大深度为3,最小叶子树为1
    深度森林最大层数为20,树的个数为100,最小叶子树为1,每个级联层的森林个数为2
    LSTM网络隐藏层单元个数为100,学习率为0.005,迭代次数为15,梯度下降算法设置为Adam
    下载: 导出CSV

    表  3  A1、A2井多尺度下DEN测井曲线复原定量结果

    PCCRMSEMAPE(%)MAE
    A1井:32级0.78170.044921.333.3376
    A1井:64级0.77020.087015.166.1063
    A1井:128级0.78020.183626.6713.4370
    A1井:256级0.77020.384028.6428.1911
    A2井:32级0.75920.051320.653.4353
    A2井:64级0.72970.103523.357.0856
    A2井:128级0.72850.211926.0614.6945
    A2井:256级0.72580.449034.1230.6630
    下载: 导出CSV

    表  4  A1井6组近邻点DEN复原定量结果

    PCCRMSEMAPE(%)MAE
    邻10.83820.00113.470.0806
    邻30.83480.00113.540.0819
    邻50.84750.00113.450.0785
    未邻10.82820.00123.590.0830
    未邻30.83850.00113.510.0812
    未邻50.84000.00113.460.0797
    下载: 导出CSV

    表  5  不同模型复原A1、A2井DEN的定量结果

    PCCRMSEMAPE(%)MAE
    A1井A2井A1井A2井A1井A2井A1井A2井
    BP神经网络0.78170.59480.00140.00154.454.800.10280.1157
    随机森林0.81750.75510.00140.00174.385.390.09870.1319
    GBDT0.82390.69420.00120.00254.059.130.09360.2008
    深度森林0.83520.78050.00130.00164.155.240.09660.1194
    LSTM网络0.82010.78090.00120.00123.873.560.08790.0831
    本文方法0.84750.78600.00110.00113.453.230.07850.0758
    下载: 导出CSV

    表  6  不同模型DEN谱分析定量结果

    STFTWT
    PCC (A1, A2)MAE (A1, A2)PCC (A1, A2)MAE (A1, A2)
    BP神经网络0.90980.90340.26090.26880.86490.83190.00900.0095
    随机森林0.90070.87780.28290.34820.80730.86320.01090.0102
    GBDT0.89990.86390.29340.35420.83060.85050.01090.0106
    深度森林0.91410.84210.26120.44610.81140.85050.01060.0124
    LSTM网络0.92180.92410.25700.25920.87030.82010.00990.0103
    本文方法0.91930.92490.25800.23820.87430.87840.00930.0079
    下载: 导出CSV
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出版历程
  • 收稿日期:  2021-05-18
  • 修回日期:  2021-12-16
  • 录用日期:  2022-01-12
  • 网络出版日期:  2022-02-02
  • 刊出日期:  2022-07-25

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