机器学习法在碳酸盐岩岩相测井识别中应用及对比——以四川盆地MX地区龙王庙组地层为例

doi:10.13809/j.cnki.cn32-1825/te.2021.04.015

Abstract

Abstract:

The machine learning method is the main technical means of carbonate lithofacies log identification. Selecting the appropriate machine learning method according to the different geological conditions and data is one of the key factors for high-precision identification of lithofacies. However, there are few researches on the applicability of machine learning identification methods. In this paper, four most commonly used machine learning methods for identifying lithofacies are studied, including Self Organizing Maps（SOM）, Multi-Resolution Graph-based Clustering（MRGC）, K Nearest Neighbor（KNN）, and Artificial Neural Network（ANN）. By comparing the principle and practical application effects of these methods, the advantages, disadvantages and applicability of the four machine learning methods have been summarized. When there are few core samples, MRGC is preferred, while when there are more core data, KNN is preferred as well as MRGC. Their application of lithofacies identification in the Longwangmiao Formation in the MX area in Sichuan Basin shows that MRGC and KNN are the best, SOM is the second, and ANN is the worst. This study of the application effects of machine learning methods provides a guidance for the identification of carbonate rock facies in other layers and regions, and has strong practical value.

Key words: carbonate facies, logging identification, machine learning method, Longwangmiao Formation, Sichuan Basin

CLC Number:

TE19

LI Chang,SHEN Anjiang,CHANG Shaoying,LIANG Zhengzhong,LI Zhenlin,MENG He. Application and contrast of machine learning in carbonate lithofacies log identification: A case study of Longwangmiao Formation of MX area in Sichuan Basin[J].Petroleum Reservoir Evaluation and Development, 2021, 11(4): 586-596.

Figures/Tables 11

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References 23

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SOM法测井相类型	岩心标定概率百分比					MRGC法测井相类型	岩心标定概率百分比
SOM法测井相类型	颗粒云岩		粉晶云岩		泥晶云岩	MRGC法测井相类型	颗粒云岩		粉晶云岩	泥晶云岩
测井相1	86.4	13.6		0		测井相1	80.6	19.4		0
测井相2	0	100.0		0		测井相2	0	100.0		0
测井相3	0	0		100.0		测井相3	100.0	0		0
测井相4	100.0	0		0		测井相4	0	100.0		0
测井相5	0	93.3		6.7		测井相5	84.6	15.4		0
测井相6	0	100		0		测井相6	0	0		100.0
测井相7	95.5	0		4.5		测井相7	11.8	70.6		17.6
测井相8	16.7	83.3		0		测井相8	73.7	26.3		0
测井相9	0	0		100.0		测井相9	0	0		100.0

岩相	岩性
颗粒云岩相	颗粒云岩,砾屑云岩、砂屑云岩,细晶云岩等粗结构的白云岩
粉晶云岩相	粉晶云岩、细—粉晶云岩等粉晶级别的白云岩
泥晶云岩相	泥晶云岩,泥质泥晶云岩,泥质泥—粉晶云岩等

序号	岩相	厚度（m）	声波时差（AC）（μs/ft）	自然伽马（GR）（API）	中子（NPHI）（V/V）	密度（DEN）（g/cm³）	深电阻率（RT）（Ω·m）
1	颗粒云岩	4.25	48.24	17.71	0.082	2.77	103.59
2	颗粒云岩	5.49	47.92	19.10	0.091	2.79	51.91
3	颗粒云岩	1.24	49.05	17.63	0.064	2.74	425.84
4	颗粒云岩	16.99	49.35	17.60	0.052	2.73	809.46
5	颗粒云岩	5.91	50.08	18.04	0.061	2.70	595.41
6	颗粒云岩	0.93	47.98	20.53	0.050	2.75	818.09
7	颗粒云岩	0.81	47.46	19.45	0.041	2.83	1 649.04
8	颗粒云岩	1.04	45.08	19.17	0.034	2.83	4 071.69
9	粉晶云岩	1.17	43.62	32.17	0.036	2.87	1 036.42
10	粉晶云岩	4.75	45.91	18.58	0.070	2.81	381.87
11	粉晶云岩	1.76	45.08	28.45	0.054	2.82	777.23
12	粉晶云岩	0.70	44.14	22.85	0.041	2.82	1 258.25
13	粉晶云岩	0.70	44.22	26.39	0.030	2.87	13 848.18
14	粉晶云岩	0.58	44.06	16.49	0.035	2.83	8 054.69
15	粉晶云岩	0.81	43.86	19.15	0.035	2.80	9 937.23
16	粉晶云岩	0.73	48.18	18.53	0.047	2.79	506.02
17	粉晶云岩	1.97	50.59	18.58	0.055	2.72	726.43
18	粉晶云岩	1.85	49.47	18.28	0.064	2.72	469.56
19	粉晶云岩	2.55	47.49	19.94	0.040	2.80	2 024.54
20	粉晶云岩	5.56	46.51	19.49	0.041	2.81	1 858.67
21	粉晶云岩	6.60	45.57	18.94	0.036	2.81	7 662.91
22	泥晶云岩	2.00	46.45	25.89	0.060	2.80	210.82
23	泥晶云岩	3.89	44.62	26.17	0.045	2.84	530.76
24	泥晶云岩	2.66	43.65	22.57	0.032	2.86	10 060.70
25	泥晶云岩	3.36	43.77	22.41	0.038	2.83	7 761.66
26	泥晶云岩	4.29	43.49	20.58	0.029	2.83	12 356.61
27	泥晶云岩	1.85	43.64	19.02	0.027	2.86	7 996.26
28	泥晶云岩	13.78	46.15	32.67	0.042	2.82	2 495.68

方法	优缺点		应用条件		方法关键点
方法	优点	缺点	测井资料要求	岩心资料要求	方法关键点
自组织映射神经网络聚类分析（SOM）	容错性强,稳定性好, 具有自联想性	人工经验主导聚类测井相数目,步骤较多	至少5项常规测井资料（中子、密度、声波、自然伽马、电阻率）	少量岩心资料	岩相和测井相对应关系
基于图像多分辨率聚类分析（MRGC）	善于解决类域交叉或重叠较多的问题	人工经验主导聚类测井相数目,人为影响因素大,步骤多		少量岩心资料	岩相和测井相对应关系
K最近邻分类算法（KNN）	善于解决类域交叉或重叠较多的问题, 无需训练,方法简单	样本数量不均衡或较少时,预测偏差大		中等数量岩心资料,且每类岩相类型样本数量均衡	不同类型样本数量要均衡
神经网络方法（ANN）	较强容错能力及自学习自适应能力	容易陷入局部极小化问题,对样本数量依赖性强		大量岩心样本资料	样本数据量大而且要具有代表性

Application and contrast of machine learning in carbonate lithofacies log identification: A case study of Longwangmiao Formation of MX area in Sichuan Basin

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