基于VMD-TCN-Transformer的复杂环境测井曲线重构

朱奕龙; 陈思路; 彭晓波; 秦迎春

doi:10.19509/j.cnki.dzkq.tb202603027

基于VMD-TCN-Transformer的复杂环境测井曲线重构

doi: 10.19509/j.cnki.dzkq.tb202603027

1a.
长江大学：油气资源与勘探技术教育部重点实验室
1b.
长江大学：地球物理与石油资源学院，武汉 430100
2.
中联煤层气有限责任公司，北京 100016
3.
北京耀齐科技有限公司，北京 100102

详细信息

作者简介:
朱奕龙：E-mail：zhuyl1206@163.com

通讯作者:
E-mail：pxbcn@126.com

计量
- 文章访问数: 93
- PDF下载量: 4
- 被引次数: 0
出版历程
- 收稿日期: 2026-03-17
- 录用日期: 2026-04-27
- 修回日期: 2026-04-21
- 网络出版日期: 2026-04-30

VMD-TCN-Transformer-based approach for logging curve reconstruction under complex conditions

1a.
Key Laboratory of Exploration Technologies for Oil and Gas Resources, Ministry of Education, Yangtze University
1b.
College of Geophysics and Petroleum Resources, Yangtze University, Wuhan 430100, China
2.
China United Coalbed Methane Co., Ltd., Beijing 100016, China
3.
Beijing Yaoqi Technology Co., Ltd., Beijing 100102, China

More Information

Author Bio:
E-mail：zhuyl1206@163.com

Corresponding author: E-mail：pxbcn@126.com

摘要

摘要:
声波测井曲线，尤其是纵波时差（DTC）与横波时差（DTS），是岩石物理分析、地震合成记录制作及储层精细表征的重要基础资料，但在实际钻井过程中，受井眼条件及复杂测量环境噪声等因素影响，声波测井曲线易发生畸变或缺失，从而制约其工程应用效果。传统经验公式与统计回归方法难以刻画测井曲线之间复杂的非线性关系，近年来引入的机器学习与深度学习方法虽在一定程度上提升了重构精度，但在复杂井况条件下，对测井信号非平稳特征、局部变化特征及长程地质相关性的综合表征仍存在一定局限。针对上述问题，本文提出一种基于变分模态分解（VMD）与时域卷积网络（TCN）-Transformer融合架构的声波测井曲线重构方法。该方法通过VMD对原始测井信号进行多尺度分解，在最大程度保留地层有效信号的同时，滤除高频环境噪声，引入TCN刻画测井曲线的局部变化特征，并结合Transformer多头自注意力机制提取测井序列的长程依赖信息，从而实现对复杂沉积旋回特征的整体建模。基于山西某区块实测测井资料，开展模型对比分析、消融实验、井径异常条件下的曲线重构实验及盲井预测验证。结果表明，所提出方法在声波测井曲线重构精度与稳定性方面表现优异，测试井段中DTC与DTS预测的决定系数（R²）分别达到0.9142和0.9165；VMD信号分解与TCN-Transformer混合架构对模型性能提升均有显著贡献；在井径异常发育井段，模型能够有效抑制环境噪声干扰，重构的曲线形态连续合理；盲井预测结果生成的合成地震记录与实测地震剖面在波组特征与相位特征上具有较好一致性。该方法在复杂井况条件下具有较好的适应性与实用性，可为低质量测井资料校正、补全及后续地震反演与储层精细表征提供可靠基础数据支持。
- 测井曲线重构 /
- 变分模态分解 /
- 时域卷积网络 /
- Transformer /
- 井径扩径 /
- 盲井预测
Abstract:
Objective
Acoustic logging curves, particularly compressional wave slowness (DTC) and shear wave slowness (DTS), serve as fundamental data for petrophysical analysis, synthetic seismogram generation, and refined reservoir characterization. However, during actual drilling operations, these curves are prone to distortion or gaps due to factors such as borehole conditions and complex environmental measurement noise, which constrains their practical application. Traditional empirical formulas and statistical regression methods struggle to capture the complex nonlinear relationships between logging curves. Although machine learning and deep learning methods introduced in recent years have improved reconstruction accuracy to some extent, they still exhibit limitations in comprehensively representing the non-stationary features, local variations, and long-range geological dependencies of logging signals under complex borehole conditions.
Methods
To address these issues, this study proposed an acoustic logging curve reconstruction method based on a fusion architecture combining variational mode decomposition (VMD) and temporal convolutional network (TCN)-Transformer. The method first employed VMD to perform multi-scale decomposition of the original logging signals, preserving the effective formation signals to the greatest extent while effectively filtering out high-frequency environmental noise. Subsequently, TCN was introduced to characterize the local variation features of the logging curves, while the Transformer’s multi-head self-attention mechanism was employed to extract long-range dependencies within the logging sequences, enabling holistic modeling of complex sedimentary cyclicity. Based on measured logging data from a block in Shanxi, comparative model analysis, ablation experiments, curve reconstruction experiments under conditions of severe borehole enlargement, and blind-well prediction validation were conducted.
Results
The results demonstrated that the proposed method performed well in terms of accuracy and stability for acoustic logging curve reconstruction. The coefficients of determination (R²) for DTC and DTS predictions in the test intervals reached 0.9142 and 0.9165, respectively. Both the VMD signal decomposition and the TCN-Transformer hybrid architecture contributed significantly to the model’s performance. In intervals with significant borehole enlargement, the model effectively suppressed environmental noise interference, producing reconstructed curves with continuous and geologically reasonable morphology. The synthetic seismograms generated from the blind-well prediction results showed good consistency with the measured seismic profile in terms of wavelet characteristics and phase features.
Conclusion
The proposed method exhibits strong adaptability and practicality under complex borehole conditions. It can provide reliable foundational data for the correction and completion of low-quality logging data, as well as for subsequent seismic inversion and refined reservoir characterization.
- logging curve reconstruction /
- variational mode decomposition /
- temporal convolutional network /
- Transformer /
- borehole enlargement /
- blind-well prediction

HTML全文

图 1 时域卷积网络（TCN）的膨胀因果卷积示意图

K为卷积核大小；d为膨胀因子；S₀～S_n为输出层序列；a^[2]₀～a^[2]_n为隐藏层2的输出特征序列；a^[1]₀～a^[1]_n为隐藏层1的输出特征序列；a₀～a_n为输入层序列；n为序列位置

Figure 1. Schematic diagram of dilated causal convolution in temporal convolutional network (TCN)

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图 2 Transformer编码器（Encoder）结构示意图

Add & Norm为残差连接与层归一化；Feed Forward Network为前馈神经网络；Multi-Head Attention为多头注意力机制；Q，K，V分别为查询、键与值矩阵；下同

Figure 2. Schematic diagram of Transformer Encoder structure

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图 3 基于VMD-TCN-Transformer的测井曲线预测流程图

Input为输入；VMD为变分模态分解；IMF₁，IMF₂，…，IMF_N为N个模态分量；R为残余分量；Dilated Causal Conv为膨胀因果卷积；BatchNorm为批量归一化；GELU为高斯误差线性单元激活函数；Dropout为随机失活；1×1 Conv为1×1卷积层；TCN Block为时域卷积网络块；Positional Encoding为位置编码；Transformer Block为Transformer 模块；Attention Pooling为注意力池化层；Output为输出；下同

Figure 3. Flowchart of VMD-TCN-Transformer-based logging curve prediction

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图 4 LX-53井的测井曲线(a)-(h)分别为井径、自然伽马、光电吸收截面、补偿中子、密度、电阻率、纵波时差、横波时差

CAL为井径；GR为自然伽马；P_e为光电吸收截面；CNCF为补偿中子；DEN为密度；M₂RX为深感应电阻率；DTC纵波时差；DTS为横波时差；黑色虚线框内为扩径区；下同

Figure 4. Logging curves of well LX-53 (a)-(h) represent the caliper, natural gamma ray, photoelectric factor, compensated neutron porosity, bulk density, resistivity, compressional wave slowness, and shear wave slowness, respectively.

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图 5 测井曲线互信息分析（a）和自相关系数（b）

Figure 5. Mutual information analysis (a) and autocorrelation coefficient (b) of logging curves

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图 6 原始信号幅值(a)、VMD 算法分解所得各固有模态函数（IMF）分量的幅值(b～k)及皮尔逊相关系数绝对值|r| (l)

Figure 6. Amplitude of original signal (a), amplitude of each intrinsic mode function (IMF) component decomposed by VMD algorithm (b-k), and absolute value of Pearson correlation coefficient ∣r∣ (l)

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图 7 6种方法对纵波时差（DTC）(a～f)和横波时差（DTS）(g～l)曲线的重构效果对比

黑色曲线为实测声波曲线；红色曲线为重构的DTC曲线；蓝色曲线为重构的DTS曲线

Figure 7. Comparison of reconstruction performance of DTC (a-f) and DTS (g-l) curves using six methods The black curves represent the measured data, while the red and blue curves represent the reconstructed DTC and DTS, respectively.

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图 8 5种网络模型训练损失函数曲线对比

Figure 8. Comparison of training loss function curves for five network models

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图 9 消融实验结果图

Figure 9. Ablation experiment results

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图 10 LX-61井DTC、DTS曲线校正分析(a1～k1)和LX-59井DTC、DTS曲线预测分析(a2～j2)

黑色实线为实测测井曲线；红色虚线为本研究方法重构曲线；蓝色虚线为多元线性回归法重构曲线；下同

Figure 10. Correction analysis of DTC and DTS curves for Well LX-61 (a1-k1) and prediction analysis of DTC and DTS curves for Well LX-59 (a2-j2)

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表 1 实验环境与工具

Table 1. Experimental environment and tools

项目	配置
操作系统	Windows 11
CPU	Intel(R) Core(TM) i7-14650HX
GPU	NVIDIA GeForce RTX 4060 8GB
编程语言	Python3.9
CUDA版本	11.3
工具包	PyTorch、NumPy、Pandas、Scikit-learn、 Matplotlib、Seaborn、VMDpy、SciPy等

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表 2 模型超参数

Table 2. Model hyperparameters

模块	关键参数	设置值
TCN	层数	4
TCN	卷积核大小	5
Transformer	编码器层数	2
Transformer	注意力头数	2
回归器	结构	64→32→2
回归器	激活函数	GELU
数据参数	时间窗长度	64
训练策略	学习率	0.001
	优化器	AdamW
	Batch大小	64
	训练轮数	100
	正则化	Dropout（0.1）

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表 3 各模型预测DTC、DTS曲线的评估指标

Table 3. Evaluation indicators of each model for predicting DTC and DTS curves

模型方法	DTC			DTS			参数量/10⁶	计算复杂度/GFLOP
模型方法	R²	RMSE	MAE	R²	RMSE	MAE	参数量/10⁶	计算复杂度/GFLOP
MLR	0.6345	4.9669	4.2230	0.7025	14.5676	12.4837	<0.0001	<0.0001
GRU	0.8565	3.0046	2.2360	0.8728	4.7593	3.8748	0.1032	0.0539
LSTM	0.8773	2.8784	2.1542	0.8764	4.7378	3.3009	0.1374	0.0716
Informer	0.8801	2.7354	2.1198	0.8779	4.3191	3.5587	0.2001	0.0391
TCN-BiGRU-Attention	0.8907	2.5523	1.9406	0.9006	4.1956	3.1229	0.1779	0.0879
TCN-Transformer	0.9142	2.4064	1.7611	0.9165	3.8931	2.8234	0.1822	0.0661

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表 4 消融实验评估指标

Table 4. Evaluation indicators for ablation experiments

模型方法	DTC			DTS			参数量/10⁶	计算复杂度/GFLOP
模型方法	R²	RMSE	MAE	R²	RMSE	MAE	参数量/10⁶	计算复杂度/GFLOP
TCN	0.7763	2.5741	1.7541	0.7706	7.1682	5.9686	0.1112	0.0550
Transformer	0.8048	2.3582	1.5721	0.7972	6.5491	5.3059	0.2343	0.0648
TCN-Transformer	0.8539	2.0042	1.3719	0.8487	6.1137	4.9542	0.1822	0.0661
VMD-TCN-Transformer	0.8872	1.8341	1.3068	0.8734	5.5723	4.2967	0.1822	0.0661
注：VMD为信号预处理模块，不增加模型的可训练参数量，也不显著增加计算复杂度，故VMD-TCN-Transformer与TCN-Transformer的参数量和计算复杂度保持一致

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