1. David Lubo-Robles*, Thang Ha, S. Lakshmivarahan, and Kurt J. Marfurt
USING PROBABILISTIC NEURAL NETWORKS FOR ATTRIBUTE ASSESSMENT AND GENERAL REGRESSION
David Lubo-Robles*, Thang Ha, S. Lakshmivarahan, and Kurt J. Marfurt By
The University of Oklahoma

2. Predict missing logs in well data Seismic attribute assessment.
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Probabilistic Neural Networks (PNN) is an interpolation method in which different mathematical operations can be organized in different layers forming a neural network structure (Specht 1990, Hampson et al., 2001).
Compared to Multi-layer Feedforward Networks which commonly use a sigmoid function for its implementation, PNN uses a Gaussian distribution as an activation function (Specht, 1990).
PNN was designed fundamentally for classification between two or more classes. However, it can be modified into the General Regression Neural Network for mapping/regression tasks (Masters, 1995).
Objectives:
Predict missing logs in well data
Seismic attribute assessment.
Predict reservoir properties using seismic attributes. 1

3. Hidden Layer Linear Nonlinear MLFN vs. PNN
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Multi-layer Feedforward Network (MLFN):
Linear
Nonlinear W1 W2
net = W1*i1 + W2*i2
𝟏 𝟏+ 𝒆 −𝒏𝒆𝒕
Activation function
W13
Hidden Layer
Input Layer
Hidden Layer
Output Layer i1 i2 i3 i4 2

4. Pattern Layer Summation Layer
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
𝒈 𝒙 = 𝟏 𝑵 𝒏=𝟏 𝑵 𝒆 − 𝒎=𝟏 𝑴 ( 𝒊 𝒎 −𝒑𝒏𝒎) 𝟐 𝟐 𝝈 𝟐
Probabilistic Neural Network (PNN):
𝒆 − 𝒊 𝟏 −𝒑𝟏𝟏 𝟐 𝟐 𝝈 𝟐
𝒆 − 𝒊 𝟏 −𝒑𝟏𝟐 𝟐 𝟐 𝝈 𝟐
Pattern Layer
𝒆 − 𝒊 𝟏 −𝒑𝟏 𝟐 𝟐 𝝈 𝟐 𝒆 − 𝒊 𝟏 −𝒑𝟐 𝟐 𝟐 𝝈 𝟐 + …
Summation Layer
Input Layer
Class 2
Class 1
Pattern Layer
Summation
Layer
Output
𝒊 𝟏
p11
p12
𝒈 𝟏
𝒈 𝟐
𝒊 𝟐
𝒊 𝟑
p21
𝒊 𝟒
p22 3

5. AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
General Regression Neural Network (GRNN):
Input Layer
Pattern Layer
Summation
Layer
Numerator
Denominator
Predicted Value
Output
p11
𝒊 𝟏
𝒗 = 𝒏=𝟏 𝑵 𝒗𝒏𝒆 − 𝒎=𝟏 𝑴 ( 𝒊 𝒎 −𝒑𝒏𝒎) 𝟐 𝟐 𝝈 𝟐 𝒏=𝟏 𝑵 𝒆 − 𝒎=𝟏 𝑴 ( 𝒊 𝒎 −𝒑𝒏𝒎) 𝟐 𝟐 𝝈 𝟐 𝒗 4

6. Validation Data (input) Training Data (pattern)
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
GRNN:
𝒗 = 𝒊=𝟏 𝑵 𝒗𝒏𝒆 − 𝒏=𝟏 𝑴 ( 𝒊 𝒎 −𝒑𝒏𝒎) 𝟐 𝟐 𝝈 𝟐 𝒏=𝟏 𝑵 𝒆 − 𝒎=𝟏 𝑴 ( 𝒊 𝒎 −𝒑𝒏𝒎) 𝟐 𝟐 𝝈 𝟐
Validation Data (input)
Attribute #2
Attribute #1
Property (𝑣)
Training Data (pattern)
Depth/Time
Attribute #1
Attribute #2
Predicted Property ( 𝑣 )
Depth/Time 5

7. AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Optimizing σ: Exhaustive Search. Cross-validation is used to train the neural network. (Hampson, 2001)
Training Data
Validation Data
𝟎.𝟔≤σ≤𝟕
Property (𝒗)
Predicted Property ( 𝒗 )
e = 𝒗 − 𝒗 𝟐 𝑵
e --- > Error
Leaving out
Sigma // Error 1 2 3 4
σ1 // e1
σ2 // e2
σ3 // e3
σ4 // e4 6

8. Attribute assessment: Combination List Leaving out: Well #2
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Attribute assessment:
Training Data
Validation Data
Combination List
Leaving out: Well #2
Attribute (s)
Sigma // Error 1 2 3
1,2
1,3
2,3
1,2,3
σ1 // e1
σ2 // e2
σ3 // e3
σ1,2 // e1,2
σ1,3 // e1,3
σ2,3 // e2,3
σ1,2,3 // e1,2,3 7

9. MLFN vs. PNN 8 Introduction GRNN Conclusions Optimize 𝝈
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study 8

10. AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
CASE STUDY: PREDICTING POROSITY USING WELL LOGS IN DIAMOND M FIELD, TX. 9

11. Wells: Garnet, Emerald, Topaz, Jade.
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Geologic Background:
Wells: Garnet, Emerald, Topaz, Jade.
Top Reef
Modified from Walker et al., 1995
Diamond M Field is located in Scurry County, TX., approximately 80 mi northeast of Midland, Texas.
The trend is part of the Horseshoe Atoll Reef Complex, an arcuate chain of reef mounds, made of mixed types of bioclastic debris that accumulated during the Late Paleozoic in the Midland basin (Vest, 1970).
The massive carbonates presented in the Atoll are separated by correlative shale beds (Davogustto, 2010) . 10

12. correlation coefficient
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Logs used for prediction: Gamma Ray (GR), Resistivity (RD), Density (𝜌 ), and Photoelectric Factor (PEFZ).
GR vs. Porosity
ρ vs. Porosity
RD vs. Porosity
PEFZ vs. Porosity
GR (API)
ρ (g/cm3 )
RD( omh-ft)
PEFZ
Porosity
𝒄𝒐𝒓𝒓𝒙,𝒚= 𝒄𝒐𝒗 (𝒙,𝒚) 𝝈𝒙𝝈𝒚
𝒄𝒐𝒓𝒓𝒙,𝒚 --- >
Pearson’s
correlation coefficient
Input Attribute
Correlation
Gamma Ray (GR)
0.5202
Density (ρ)
Resistivity (RD)
Photoelectric Factor (PEFZ). 11

13. Leaving out well: Garnet Leaving out well: Emerald
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Combination Lists
e = 𝒗 − 𝒗 𝟐 𝑵
Leaving out well: Garnet
Leaving out well: Emerald
Error=
Error= 12

14. Leaving out well: Topaz
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Combination Lists
e = 𝒗 − 𝒗 𝟐 𝑵
Leaving out well: Jade
Error=
Leaving out well: Topaz
Error= 13

15. MLFN vs. PNN 14 Introduction GRNN Conclusions Optimize 𝝈
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Error=
Error=
Error=
Error= 14

16. MLFN vs. PNN Garnet: Jade: Emerald: Topaz: 15
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
𝒄𝒐𝒓𝒓𝒙,𝒚= 𝒄𝒐𝒗 (𝒙,𝒚) 𝝈𝒙𝝈𝒚
Cross-plots
Garnet:
(Corr = )
Jade:
(Corr = )
Emerald:
(Corr = )
Topaz:
(Corr = ) 15

17. MLFN vs. PNN Future work 16 Introduction GRNN Conclusions Optimize 𝝈
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
Future work 16

18. PNN provides faster learning speed than MLFN.
AASPI
Introduction
GRNN
Conclusions
MLFN vs. PNN
Optimize 𝝈
Exhaustive GRNN
Workflow
Case study
PNN provides faster learning speed than MLFN.
PNN are insensitive to outliers. Therefore it can be more accurate than MLFN.
GRRN is a powerful technique to predict missing data using known properties as input.
The novel technique Exhaustive GRNN allow us to determine the best group of attributes to be used for a regression task. Computation time increases as a larger range of σ is used.
Future work:
We will apply our technique using seismic attributes in order to obtain a predicted rock property survey.
We will expand our Exhaustive GRNN technique for classification tasks (Exhaustive PNN).
Simulated annealing, and the Gradient Descent Method will be implemented to obtain different sigma for each attribute and class. 17

19. References
Davogustto, O., 2013, Quantitative Geophysical Investigations at the Diamond M Field, Scurry County, Texas. Ph.D Dissertation, The University of Oklahoma.
Hampson, D.P., Schuelke, J.S., Quirein, J.A., 2001, Use of multiattribute transforms to predict log properties from seismic data. Geophysics, 66,
Hughes D., and N. Correll, 2016, Distributed Machine Learning in Materials that Couple Sensing, Actuation, Computation and Communication, arXiv: v1.
Masters, T., 1995, Advanced Algorithms for Neural Networks.
Specht, D., 1990, Probabilistic neural networks: Neural Networks, 3,
Walker, D. A., J. Golonka, A. M. Reid, and S. T. Reid, The effects of late Paleozoic paleolatitude and paleogeography on carbonate sedimentation in the Midland Basin, Texas; Permian Basin plays: Society of Economic Paleontologists and Mineralogists, Permian Basin Chapter, Tomorrow’s Technology Today, 18