Plane Thermoelastic Waves in Infinite Half-Space Caused


Decision Making: Applications in Management and Engineering  
Vol. 2, Issue 2, 2019, pp. 1-18. 
ISSN: 2560-6018 
eISSN: 2620-0104  

 DOI: https://doi.org/10.31181/dmame1902001v 

* Corresponding author. 
 E-mail addresses: m.j.vilela-ibarra@rgu.ac.uk (M. Vilela), g.f.oluyemi@rgu.c.uk (G. 
Oluyemi), a.petrovski@rgu.ac.uk (A. Petrovski). 

A FUZZY INFERENCE SYSTEM APPLIED TO VALUE OF 
INFORMATION ASSESSMENT FOR OIL AND GAS 

INDUSTRY  

Martin Vilela*1, Gbenga Oluyemi 1 and Andrei Petrovski 2 
 

 1 School of Engineering, Robert Gordon University, Aberdeen, United Kingdom 
2 School of Computing, Robert Gordon University, Aberdeen, United Kingdom 

  
 
Received: 20 March 2019;  
Accepted: 21 May 2019;  
Available online: 23 May 2019. 

 
Original scientific paper 

Abstract: Value of information is a widely accepted methodology for 
evaluating the need to acquire new data in the oil and gas industry. In the 
conventional approach to estimating the value of information, the outcomes 
of a project assessment relate to the decision reached following Boolean logic. 
However, human thinking logic is more complex and include the ability to 
process uncertainty. In addition, in value of information assessment, it is often 
desirable to make decisions based on multiple economic criteria, which, 
independently evaluated, may suggest opposite decisions. Artificial 
intelligence has been used successfully in several areas of knowledge, 
increasing and enhancing analytical capabilities. This paper aims to enrich the 
value of information methodology by integrating fuzzy logic into the decision-
making process; this integration makes it possible to develop a human 
thinking assessment and coherently combine several economic criteria. To the 
authors’ knowledge, this is the first use of a fuzzy inference system in the 
domain of value of information. The methodology is successfully applied to a 
case study of an oil and gas subsurface assessment where the results of the 
standard and fuzzy methodologies are compared, leading to a more robust 
and complete evaluation. 

Key words: Value of information, fuzzy logic, fuzzy inference system, oil and 
gas industry, uncertainty.  

mailto:m.j.vilela-ibarra@rgu.ac.uk
mailto:g.f.oluyemi@rgu.c.uk
mailto:a.petrovski@rgu.ac.uk


 Vilela et al./Decis. Mak. Appl. Manag. Eng. 2 (2) (2019) 1-18  

2 

1. Introduction  

1.1. Review of Value of information  

Value of information (VoI) is a prescriptive methodology embedded in the 
discipline of decision analysis that has the aim of assessing the value assocted with 
gathering information. To that end, the methodology maximizes an objective function, 
which defines the value of a project. 

Grayson (1960), Raiffa and Schlaifer (1961) and Newendorp (1967) were the 
pioneers in the field of decision making for data acquisition in the oil and gas industry. 
Subsequently, more research and applications, such as those of Warren (1983), 
Lohrenz (1988), Demirmen (1996), Newendorp and Schuyler (2000) and Koninx 
(2000), among others, expanded the scope of the subject, adding more robustness to 
the methodology.  

Recently, more applications have emerged—like those of Clemen (1996), 
Coopersmith and Cunningham (2002), Suslick and Schiozer (2004)—which enrich the 
process of assessing the VoI decision problem from a methodological perspective. 
Several papers, such as Walls (2005) and Vilela et al (2017), have discussed the use of 
utility theory in VoI assessment in the oil and gas industry; similarly, Santos and 
Schiozer (2017) discussed the impact of the risk attitude of the decision makers in VoI 
assessments; Kullawan et al (2017) developed a discretized- -programming approach, 
based on value of information, to optimize stochastic-dynamic the geosteering 
operations; Steineder et al (2018) discussed the maximization of the VoI on a 
horizontal polymer pilot project; all these researchers used one or more crisp decision 
criteria to make decisions. 

In the oil and gas industry, the scope of a project varies from the complex 
exploitation of hydrocarbon fields to theoretical reservoir studies or laboratory tests; 
project’s economic benefits are calculated based on the estimated figures of 
hydrocarbons’ production and price, operating cost, taxes, royalties, and investments. 
All these figures carry uncertainties because it is not possible to predict their future 
fluctuations accurately—in particular, future hydrocarbon production is uncertain 
due to a combination of: 

(a) the uncertainties associated with the reservoir parameters (permeability, 
thickness, top reservoir, well producibility, aquifer support, etc.); 

(b) the uncertainties associated with the methods used to estimate future 
production based on the reservoir parameters (dynamic reservoir models, decline 
curve analysis, etc.) 

On occasion, additional data can be acquired to change the uncertainty in the 
reservoir parameters; however, acquiring data involves a cost that could be greater 
than the benefits of the data. Changes in the reservoir parameters’ uncertainties 
translate into changes in the value of the project. In general, acquiring additional data 
makes sense in cases in which the outcome from the data acquisition can change the 
decisions being made. 

For a project with uncertain outcomes, the VoI is the difference between the 
expected value (EV) of the project with and without the newly acquired data (Clemen, 
1996): 

  with information without informationVOI EV EV   (1) 

where both values, 𝐸𝑉𝑤𝑖𝑡ℎ 𝑖𝑛𝑓𝑜𝑟𝑚𝑎𝑡𝑖𝑜𝑛  and 𝐸𝑉𝑤𝑖𝑡ℎ𝑜𝑢𝑡 𝑖𝑛𝑓𝑜𝑟𝑚𝑎𝑡𝑖𝑜𝑛    , assess the outcome 

of the project in these circumstances and refer to a future situation. 



A fuzzy inference system applied to value of information assessment for oil and gas industry 

3 

In the ‘without-information’ case, for 𝜅 possible scenarios (which include 
endorsing the project with the current knowledge and uncertainties and the 
alternative of relinquishing it), the EV of the project corresponding to the 𝑗𝑡ℎ  scenario 
is defined as: 

   
1

n

j ji i

i

V a u p s



  (2) 

where 𝑢𝑗𝑖  is the value of the state of nature 𝑠𝑖  for the scenario 𝑎𝑗  and 𝑝(𝑠𝑖 ) is the 

prior probability of the state of nature 𝑠𝑖 . The most often used decision criterion is to 
select the alternative that maximizes the EV: 

   * max  j
j

EV a EV a   (3) 

Equation (3) is the 𝐸𝑉𝑤𝑖𝑡ℎ𝑜𝑢𝑡 𝑖𝑛𝑓𝑜𝑟𝑚𝑎𝑡𝑖𝑜𝑛  term shown in Equation (1). 

Similarly, in the ‘with-information’ alternative, for 𝜅 possible scenarios and for each 
possible data outcome, 𝑥𝑘 , the EV for the 𝑗

𝑡ℎ  alternative is: 

 
1

| ( | )

n

j k ji i k

i

EV a x u p s x



   (4) 

where 𝑢𝑗𝑖  is the value of the state of nature 𝑠𝑖  for the scenario 𝑎𝑗 ; 𝑝(𝑠𝑖 |𝑥𝑘 ) is the 

posterior probability of the state 𝑠𝑖  given the outcome 𝑥𝑘 ; and the term 𝐸𝑉(𝑎𝑗 |𝑥𝑘 ) is 

the expected project value for the 𝑗𝑡ℎ  alternative given the outcome 𝑥𝑘 . 
Similarly, as in the ‘without-information’ case, the optimum alternative in the ‘with-

information’ case for a given data outcome 𝑥𝑘  (EV conditioned on the outcome 𝑥𝑘 ) is 
the one that maximizes the EV: 

 *| max ( | )k j k
j

EV a x EV a x   (5) 

The unconditional maximum EV (which is the EV of the project considering the 
data acquisition outcomes) is the sum of the conditional EV weighted with the 
corresponding marginal probabilities: 

 * *
1

( | ) ( )

n

k k

k

EV a EV a x p x



   (6) 

The VoI is the difference between the estimates of EV in Equation (6) and Equation 
(3). 

So far, the discussion has focused on the classical methodology to assess the VoI in 
a decision problem in which the output values (hydrocarbon production, total 
benefits, etc.) are uncertain due to uncertainties in the input variables; these 
uncertainties have been included using probabilistic measures. In the next section, we 
will include the imprecision in the input variables by making use of fuzzy logic. 

 

1.2. Review Fuzzy Logic 

Fuzzy logic, pioneered by Zadeh (1965), is one of the most prolific areas of artificial 
intelligence, which has enriched the analysis of challenging and complex problems. 



 Vilela et al./Decis. Mak. Appl. Manag. Eng. 2 (2) (2019) 1-18  

4 

Bellman and Zadeh (1970) introduced an important distinction between randomness 
and fuzziness: while randomness relates the uncertainty concerning membership or 
non-membership of an object or event to a non-fuzzy set (a crisp set), fuzziness deals 
with classes in which there may be degrees of membership (between the full- and the 
no-membership relationship).  

These distinct sources of uncertainties are managed during different phases of the 
VoI assessment: 

Phase 1) Assessing: assesses, using one or more decision criteria, whether the new 
data add value to the project or not.  

Phase 2) Categorization: relates the values obtained during the assessing phase to 
the options available for the decision problem.  

During the Phase 1, the uncertain nature of the input variables (e.g. reservoir 
parameters) and outcome values (e.g. financial benefits or economic parameter 
values) is captured using probabilistic analysis based on EV calculations.  

In the standard VoI approach, Phase 2 is implemented using crisp criteria to make 
decisions that do not correspond with human fuzzy thinking for making decisions. 
Following Bellman and Zadeh (1970), the uncertainty related to fuzziness is a major 
source of uncertainty in many decision processes.   

In classical set theory, the events (values) belong (or not) to sets in a crisp manner 
that is represented by the “characteristic function”, defined by Equation (7), which is 
a mapping from the input variables to the Boolean set  {0,1}:  

1 ,            
 

0,       

k
M

x M

otherwise






   (7) 

Thus, an event (e.g. X) belongs totally or not at all (1 or 0) to a set; these kinds of 
relationships follow Boolean logic.  

As a practical example, in subsurface reservoirs, the characteristic function allows 
establishing a Boolean relationship (1 or 0, i.e. totally belongs or totally excluded) 
between quantitative input variables (e.g. reservoir depth of 5000 ft) and descriptive 
terms (e.g. deep reservoir). Fuzzy logic extends the mapping between events and sets 
using the membership function (MF) to include all the values between 0 and 1, [0,1]; 
mathematically, the MF is a mapping from a given universe of discourse “X” to the 
continuous unit intervals that are the membership values. Equation (8) shows the 
mathematical expression for the MF:  

       / 0,1M x y y     (8) 

which shows that the values of the MF belong to the interval [0,1]. The membership 
values measure the degree of belonging of each event to a given set, representing the 
“degree of membership” of the mentioned event to that set. In this logic, an event (e.g. 
reservoir depth of 5000 ft) belongs partially (with a value between 0 and 1) to a set 
(e.g. deep reservoir). 

In the standard VoI, the results of the assessment are a set of crisp values that 
measure the project benefits or losses of the different alternatives under evaluation. 
Comparing those values with a set of threshold values, a decision is made regarding 
the project fate; however, a decision made in this manner is limited because it does 
not follow the human thinking for decision making which works with fuzzy categories 
like “the project is viable to endorse”, “the project is unviable to endorse” or “the 
project needs reframing”. 



A fuzzy inference system applied to value of information assessment for oil and gas industry 

5 

1.3. Review Fuzzy Inference Systems 

In practice, fuzzy logic is implemented through a process called a “fuzzy inference 
system” (FIS). A FIS is a non-linear procedure that derives its output based on fuzzy 
reasoning and a set of IF-THEN rules. The FIS performs approximate reasoning like 
the human brain, albeit in a much more straightforward manner. 

The FIS is one of the most prolific applications of fuzzy logic. It has been used 
recently in very different areas and within various problem domains, such as: the 
assessment of water quality in rivers (Ocampo, 2008), the improvement of image 
expansion quality (Sakalli et al, 1999), the differential diagnosis of non-toxic 
thyropathy (Guo and Ling, 2008), the development of a fuzzy logic controller for a 
traffic junction (Pappis and Mamdani, 1997), maintenance scheduling of Smart Grid 
systems (Malakhov et al, 2012), the design of fire monitoring sensors in coal mines 
using fuzzy logic (Muduli et al, 2017), the estimation of the impact of tax legislation 
reforms on the tax potential (Musayev et al, 2016), pipeline risk assessment (Jamshidi 
et al., 2013), depression diagnosis (Chattopadhyay, 2014), river discharge prediction 
assessments (Jayawardena et al., 2014), geological strength index calculation and 
slope stability assessments (Sonmez et al, 2004), the regulation of industrial reactors 
(Ghasem, 2006) and the use of a fuzzy logic approach for file management and 
organization (Gupta, 2011). In the domain of the oil and gas industry several 
applications of FIS have been reported such as the streamline based fuzzy logic 
workflow to redistribute water injection by accounting for operational constraints and 
number of supported producers in a pattern (Bukhamseen et al, 2017), the 
identification of horizontal well placement (Popa, 2013), for estimating strength of 
rock using FIS (Sari, 2016), for predicting the rate of penetration in shale formations 
(Ahmed et al, 2019). Fuzzy logic has been used in combination with others Artificial 
Intelligence techniques such as Adaptative Neuro-Fuzzy Inference system (ANFIS) on 
practical applications, e.g. for predicting the inflow performance of vertical wells 
producing two-phase flow (Basfar et al, 2018) or to predict geomechanical failure 
parameters (Alloush et al, 2017); FIS has also been used in conjunction with Analytical 
Hierarchical processes to evaluate the water injection performance in heterogeneous 
reservoirs (Oluwajuwon and Olugbenga, 2018). 

From the point of view of applications, there are two kinds of FIS (Guillaume, 
2001): 

1) Fuzzy expert systems or fuzzy controllers: fuzzy rules built on expert 
knowledge. This kind of FIS uses the ability of fuzzy logic to model natural language.  

2) Automatic learning from data: neural networks have become the most 
popular tool using a numerical performance index, typically based on the mean square 
error. These kinds of development are distinguished by their accuracy, and their main 
drawback is their “black-box” approach. 

For the current application, we will focus on the first kind of FIS. 
From a methodological perspective, the FIS can be understood as a general 

procedure that transforms a set of input variables into a set of outputs, following the 
workflow shown in Figure 1.  

 



 Vilela et al./Decis. Mak. Appl. Manag. Eng. 2 (2) (2019) 1-18  

6 

 

Figure 1. Fuzzy inference system 

As shown in Figure 1, FIS as a procedure entailing five blocks in which the inputs 
and outputs are in crisp form.  

For a Mandani FIS, shown in Figure 1, the outcome is a crisp number, 
independently of the number of crisp parameters used the asses the value of the 
project (e.g. NPV, DPI, IRR, etc.); this is FIS aggregation process; in general, higher FIS 
values means higher value of the project and vice versa. 

1.4. Objective of this research work 

The objective of this work is to investigate whether considering the fuzzy nature of 
human thinking can impact the decision’s assessment in VoI problems, especially in 
oil and gas projects; to reach this objective we integrate Fuzzy Inference System into 
the VoI assessment. 

2. Application 

2.1. Reservoir Description 

An exploration campaign conducted in Algeria discovered a medium-sized oil field 
located at 5200 ft. TVD SS. Four wells were drilled—the discovery well and three 
appraisal wells. The range of original oil in place (minimum and maximum figures) has 
been assessed; the fluid characteristics are known based on samples taken from the 
appraisal wells. The operator’s technical team has estimated, based on the available 
information, technical experience, and analogue fields, that the main source of 
subsurface uncertainty is the well productivity. The four wells drilled were tested for 
six hours; however, considerable uncertainty remains regarding well productivity due 
to reasons described in Table 1. 

 
 
 
 



A fuzzy inference system applied to value of information assessment for oil and gas industry 

7 

Table 1. Causes of well productivity uncertainty 

Reason for uncertainty Comment 
Quality and reliability of the well 

test 
Possible calibration issues on well 

testing equipment 
Duration of the tests Well test period too short, no 

enough to reach stabilized flow 

Based on the information gathered during the exploration phase and from similar 
fields in the same basin, a material balance model is built to represent the forecast oil 
rate for the high-, medium- and low-development scenarios, as shown in Figure 2.  

 

  Figure 2. High, medium and low cases of the oil production rate 

The difference between the profiles is the well model used in each case. The full 
development of the field includes twelve vertical wells, four of which have already 
been drilled—at present these are “suspended”, to be used in the development phase 
of the project if a decision is taken to move the project forwards; otherwise, those wells 
should be abandoned entirely. 

The rig will be available in four months, and each well can be drilled in two months; 
the duration of the campaign to drill and complete the remaining eight wells included 
in the development plan is sixteen months. The first period of oil production was 
planned to have a fixed plateau rate followed by a period of oil rate decline (Figure 2). 

2.2. Decision Problem 

At this stage, the operator company must decide whether acquiring additional 
information would increase the project’s value.  

Alternative A: without-information. The decision on project development is made 
based on the current information using the expected value (EV) of the net present 
value (NPV) and the discounted profit to investment ratio (DPI), which is discussed 
further in Section 3.3. Prior probabilities are assigned according to the technical team 
members’ judgment on the subjective probabilities of realizing the different states of 
nature; the economic parameters are estimated based on the assumptions and 
assessments included in the high-, medium- and low-production scenarios. If this 



 Vilela et al./Decis. Mak. Appl. Manag. Eng. 2 (2) (2019) 1-18  

8 

option is chosen, the first oil can be reached in two years’ time, including facilities and 
wells. 

Alternative B: with-information. Additional information is acquired regarding the 
uncertain parameters of the reservoir and, subsequently, based on the outcomes of the 
data obtained, a decision is made on the future development of the project. The 
operator’s technical team has estimated, based on the reservoir and fluid properties, 
that, to obtain meaningful well test results, the minimum well test duration per well 
should be four months. It was decided that two of the appraisal wells could be used to 
perform an extended well test (EWT) in each one. Following these assumptions, there 
will be a delay of one year (four months rig move + eight months EWT) compared with 
the without-information alternative. 

After the test results have been gathered, the technical team expects to have a more 
certain criterion to assign well deliverability, although uncertainty will still be present 
because the data are not perfect. The cost associated with the well test in these two 
wells is US$20 million. It should be considered that, if the project is relinquished now, 
the US$90 million already spent on exploration and appraisal will be lost; additionally, 
the abandonment cost for the 4 drilled wells, US$4 million, and the facilities’ 
abandonment cost, US$10 million, should be added to the economic evaluation. If new 
data are acquired and afterwards the decision is made to abandon the project, the cost 
of the data acquisition must be added to the previously mentioned costs. 

The outcome of the assessment of the alternatives without-information and with-
information will result in one of the following options:  

1) the project is viable to endorse: it will proceed to the development phase, which 
necessitates a large investment; 

2) the project is not viable to endorse : it will be relinquished, carrying the losses 
associated with the exploration costs;  

3) the project needs additional analysis before deciding: it will be reframed. 

2.3. Economic Parameters for Decision Making 

Two economic parameters are used to make the decision: the net present value 
(NPV) and the discounted profit to investment ratio (DPI). The NPV is the yearly net 
cash flow discounted to the weighted average cost of capital (WACC—the average rate 
of return with which a company expects to compensate all its different investors, in 
which the weights are the fraction of each financing source in the company’s target 
capital structure), which in this case is 10.5%; the DPI is the result of dividing the 
discounted net cash flow by the discounted sum of the investment using the WACC. 
The values of NPV and DPI are shown in Section 2.4.2. 

2.4. Classical VoI Assessment 

As discussed in Section 1.1, the VoI is described by Equation (1); in this section, the 
classical approach to the VoI is discussed. 

2.4.1. Decision rules 

Based on the operator’s portfolio of projects, the criterion for making decisions on 
projects with a financial investment higher than US$500 million is: A) a project with 
NPV lower than US$100 million is unviable to endorse, which means that it is 
relinquished, B) a project with NPV higher than US$500 million is viable to endorse 
and, C) a project with NPV between US$100 million and US$500 million is reframed to 
find alternative development options.    



A fuzzy inference system applied to value of information assessment for oil and gas industry 

9 

Regarding the DPI: A) a project with DPI higher than 0.5 is viable to endorse, B) a 
project with DPI lower than 0.0 is unviable to endorse and, C) a project with DPI 
between 0.0 and 0.5 should be reframed. 

2.4.2. VoI assessment for the without-information and with-information alternatives 

For the without-information alternative, Table 2 shows the prior probabilities, the 
calculated NPV, and DPI of each state of nature and the EV of the without-information 
alternative. 

Table 2. Prior probabilities, NPV, DPI and expected values for the without-

information alternative 

State of nature Prior probabilities 
(%) 

NPV (US$ 
million) 

DPI 
(fract.) 

S1=High 25 2,139 2.27 
S2=Medium 40 414 0.42 

S3=Low 35 -631 -0.61 
EVNPV-A1 (US$ million) 479   
EVNPV-A2 (US$ million) -102   

EVNPV (US$ million) 479   
EVDPI-A1 (fraction) 0.52   
EVDPI-A2 (fraction) -1.00   

EVDPI (fraction) 0.52   

For the with-information alternative, the technical team members estimated the 
reliability probabilities for the well test. It is acknowledged that, in a developed field, 
wells perform differently depending on their location and well test results are 
representative of a specific location; additionally, the duration of the test, although 
designed to capture the well performance, might not be long enough to assess the long-
range well operation. Table 3 shows the reliability probabilities of the well test 
estimated by the technical team members. 

Table 3. Reliability probability of the well test 

Reliability 
probability 

X1=High 
productivity 

X2=Medium 
productivity 

X3=Low 
productivity 

𝑝(𝑥𝑘 |𝑠1) 0.9 0.1 0.0 
𝑝(𝑥𝑘 |𝑠2) 0.1 0.8 0.1 
𝑝(𝑥𝑘 |𝑠3) 0.0 0.1 0.9 

Reliability probabilities are used together with prior probabilities to obtain 
posterior probabilities, which are combined with the project values to generate the 
expected value of the net present value (EVNPV) and the EV of the discounted profit 
to investment ratio (EVDPI). The results of these assessments are shown in Table 4. 
  



 Vilela et al./Decis. Mak. Appl. Manag. Eng. 2 (2) (2019) 1-18  

10 

Table 4. Posterior probabilities, residual probabilities and expected values 

for the with-information alternative 

 X1=High 
productivity 

X2=Medium 
productivity 

X3=Low 
productivity 

𝑝(𝑠1|𝑥𝑘 ) 0.85 0.07 0.00 
𝑝(𝑠2|𝑥𝑘 ) 0.15 0.84 0.11 
𝑝(𝑠3|𝑥𝑘 ) 0.00 0.09 0.89 

𝑝(𝑥𝑘 ) 0.27 0.38 0.36 
𝐸𝑉𝑁𝑃𝑉(𝐴1|𝑥𝑘 ) 1,667 357 -497 
𝐸𝑉𝑁𝑃𝑉(𝐴1|𝑥𝑘 ) -114 -114 -114 
𝐸𝑉𝑁𝑃𝑉(𝐴1|𝑥𝑘 ) 1.667 357 -114 

𝐸𝑉𝑁𝑃𝑉(𝑈𝑆$ 𝑚𝑖𝑙𝑙𝑖𝑜𝑛) 537   
𝐸𝑉𝐷𝑃𝐼(𝐴1|𝑥𝑘 ) 1.76 0.37 -0.48 
𝐸𝑉𝐷𝑃𝐼(𝐴1|𝑥𝑘 ) -1.00 -1.00 -1.00 
𝐸𝑉𝐷𝑃𝐼(𝐴1|𝑥𝑘 ) 1.76 0.37 -0.48 

𝐸𝑉𝐷𝑃𝐼( 𝑓𝑟𝑎𝑐𝑡𝑖𝑜𝑛) 0.44   

2.4.3. Results of the VoI using the classical approach 

Decision based on NPV: Based on the results obtained in Section 2.4.2, and using 
the decision rules (Section 2.4.1), it can be concluded that, the without information 
project should be reframed and the with information project should be endorsed; in 
this manner, acquiring data increase the project’s value; Summarizing, according to 
the NVP figures, the preferred alternative is to perform the well test (the with-
information alternative) and, depending on the data outcomes, decide whether the 
project should be endorsed or not.   

Decision based on DPI: Using DPI as the decision criterion, the without-information 
alternative suggests endorsing the project, while the with-information alternative 
suggests reframing the project; summarizing, the alternative that maximizes the DPI 
is the without-information one, which means that it is not recommended to perform 
the well test. 

At this stage, using two financial criteria, we have two contrasting 
recommendations about the future of the project. 

Making a decision using these crisp criteria does not include the sophisticated 
elements used by human thinking in which, the criteria may overlap. In addition, from 
the independent NPV and DPI results, it is not clear which is the optimum alternative 
unless some form of weighted valuation is made by combining the two economic 
parameters into one.  

2.5. FIS VoI Assessment 

Up to this stage, the criterion to decide the future of the project has been based on 
linguistic variables like “not endorse”, “endorse”, “viable”, “unviable”, “high”, 
“medium” and “low”. Indeed, a crisp relationship is established between the NPV and 
DPI and the linguistic variables: if the NPV is less than US$ 𝑿 million, the project is 
“unviable to endorse”, if the NPV is higher than US$ 𝒀 million, the project is “viable to 
endorse” and if the NVP is higher than 𝑿  but lower than 𝒀, the project should be 
reframed; similar relationships apply to the DPI criterion. 



A fuzzy inference system applied to value of information assessment for oil and gas industry 

11 

However, it is worth recognizing that these criteria are fuzzy and not always 
aligned. The fuzziness occurs because, if the project NPV is US$ 𝑿 − 𝜺 million, where 𝜺  
is a given amount, the crisp logic decision criterion catalogues the project as “unviable 
to endorse”, although 𝜺 could be “small” compared with 𝑿. In the same manner, if the 
project value is US$ 𝒀 + 𝜺, in a crisp decision, the project is catalogued as “viable to 
endorse”, although 𝜺 could be “small” compared with 𝜺.  

The no alignment between the criteria happens because very often the two indices, 
NPV and DPI, can produce a contradictory assessment of the same problem; for 
example, it could be the case that, using the NPV, the project is “viable to endorse” but, 
using the DPI, the project is “unviable to endorse” or vice versa, as has been witnessed 
in this case study.   

These cases suggest that fuzzy logic can be used advantageously to make VoI 
decisions by providing a more versatile tool to assess these decision problems; fuzzy 
logic is implemented through the FIS. 

2.5.1. FIS building and application 

The FIS used in this work was developed using MATLAB. The input parameters in 
the FIS are the NPV and DPI; for each input parameter, six Membership Functions are 
built, representing the linguistic variables high NVP or NVP viable to endorse, low NVP 
or NVP unviable to endorse, mid NVP or NVP for reframing, high DPI or DPI viable to 
endorse, low DPI or DPI unviable to endorse and mid DPI or DPI for reframing; the 
corresponding MFs are: NVP HIGH, NVP MID, NVP LOW, DPI HIGH, DPI MID and DPI 
LOW. 

In MATLAB, a set of predefined MFs—triangular-shaped functions—are selected. 
These MFs are chosen because they capture the technical team members’ 
interpretation of the degree to which the NPV and DPI figures belong to the three 
categories into which the range of potential values are divided. Equation (9) shows the 
mathematical form of the triangular-shaped MF: 

 

0                             

                   

; , ,

                    

0                              

x a

x a
a x b

b a
f x a b c

c x
b x c

c b

c x





  
 

 
  

 




   (9) 

The comparison between the output of the FIS for the with-information and that 
for the without-information alternative indicates which alternative has more value 
(the better decision).  

A Mamdani FIS with the centroid defuzzification method was used in this 
assessment. Figure 3 shows the design of the FIS using MATLAB. 

In Section 1.3 we show the Figure 2 which describe the FIS process; that figure is 
shown below but now numbering the steps, in order, we are following in this work 

 
 



 Vilela et al./Decis. Mak. Appl. Manag. Eng. 2 (2) (2019) 1-18  

12 

 

Figure 3. FIS implementation 

Step1: the crisp data is generated, in this case, the project value, NPV and DPI 
Step 2: data is fuzzified using the membership function located in the data base; 

those MF describe the degree of belonging of different input values which is defined 
according with the analyst belief. In this work, the MF used for NPV and DPI are shown 
in Figure 4 and Figure 5. 

 

Figure 4. Membership Function for NPV (input) 



A fuzzy inference system applied to value of information assessment for oil and gas industry 

13 

 

Figure 5. Membership Function for DPI (input) 

Step 3: once input variables are fuzzified, the decision rules, which are part of the 
knowledge base, are applied to the membership functions in the Decision-making unit; 
in the Mandani type inference, the decision rules are a mapping from the input 
membership function to the output membership functions, which are also part of the 
knowledge base; the rules aggregation process generate the fuzzy outcome.  

The output membership functions used in this work, describing the different 
decision options are show in Figure 6. 

 

Figure 6. Membership Function for the decision (output) 

 



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14 

The decision rules indicate the manner in which the two fuzzy financial parameters 
combine to result in a fuzzy decision. In this work we define the rules shown in Table 
5 to include the cases of interest, 

Table 5. Fuzzy rules 

RULES IF THEN 
Rule 1 (NPV is NPV_HIGH) & (DPI is DPI_HIGH) ENDORSE 
Rule 2 (NPV is NPV_HIGH) & (DPI is DPI_MID) ENDORSE 
Rule 3 (NPV is NPV_HIGH) & (DPI is DPI_LOW) REFRAMING 
Rule 4 (NPV is NPV_MID) & (DPI is DPI_LOW) REFRAMING 
Rule 5 (NPV is NPV_LOW) & (DPI is DPI_LOW) NO ENDORSE 
Rule 6 (NPV is NPV_LOW) & (DPI is DPI_HIGH) REFRAMING 
Rule 7 (NPV is NPV_MID) & (DPI is DPI_MID) ENDORSE 

Step 4: fuzzy output gets into the defuzzification interface to generate crisp output. 
Step 5: the value of the project is the crisp out; different crisp outputs are compared 

and, the one with the higher value is the optimum decision. 
The MFs of the NVP are chosen in accordance with past decisions taken by the 

decision maker, as discussed in Section 1.2. The rationale for the selection of these MFs 
is that, for very high or very low NPV values, the NPV belongs to only one set, the 
NPV_HIGH or the NPV_LOW, with a membership value of 1; for the intermediate NPV 
value, the NPV belongs partially to the three fuzzy sets. This fuzzy representation of 
the criteria for categorizing the project is based on past decisions made by the field 
operator company. The selection of the MFs needs to be updated once more decisions 
have been taken. 

The MFs for the DPI are chosen following the same procedure used for the NPV 
The authors define a set of seven rules that determine the logic of this decision; 

these rules (IF-THEN rules) are made by pairs of NPV and DPI figures and a 
consequential sentence (THEN). The rules do not pretend to be exhaustive but must 
be coherent. All the rules were built using the AND connector; although, in general, 
they can be defined equally well with OR. 

2.5.2. FIS applied to the without-information and with-information alternatives; VOI 
assessment 

Referred to Section 1.3, the outcome of FIS (a crisp number) is the value of the 
project resulting from aggregating the project’s values in terms of NPV and DPI; in 
addition, the FIS assessment includes the imprecision in the terms used to decide 
whether a project worth or not to endorse (Section 2.2). 

For evaluating the project using the FIS developed in Section 2.5.1, the crisp values 
for NPV and DPI estimated in Section 2.4.2 Table 2 (US$479 million and 0.52), are 
input in the FIS; the outcome of the assessment made by the FIS indicates that the 
value associated with the without-information alternative is 7.2. 

Similarly, in the with-information alternative, the NPV and DPI figures (US$537 
million and 0.44), contained in Table 3, are input in the FIS; as a result, the FIS 
assessment for the with-information alternative is 6.97. 

Due to the fact that, the value of the FIS for the without-information alternative is 
higher than the value of the FIS for the with-information case, the best alternative for 
the decision problem discussed is to endorse the project now and move it forward to 
the development phase without acquiring additional data.  



A fuzzy inference system applied to value of information assessment for oil and gas industry 

15 

This result is explained by the fact that, although the data acquisition reduces the 
uncertainty regarding well deliverability, the cost of this data acquisition, in terms of 
the additional investment and oil production delay, is higher than the increased 
project value due to uncertainty reduction.   

3. Conclusions 

In this study, an FIS has been successfully implemented with the aim of assessing 
the VoI of an oil and gas project. In the discussed case study, the use of the FIS was able 
to introduce the fuzzy thinking of the decision maker into a subsurface VoI assessment 
while removing ambiguity coming from the use of more than one economic parameter 
for decision making.  

The proposed methodology for VoI assessment using FIS has improved the 
conventional approach because: 

1) instead of using a Boolean relationship between project valuation and project 
decision, the FIS uses a fuzzy human thinking approach to make decisions; 

2) the FIS uses a coherent method to integrate more than one criterion into the 
assessment, while, in the conventional VoI approach, when more than one criterion is 
used, they can reach contradictory outcomes which conduct to inconclusive 
assessment.     

In addition to the aspects discussed above, the FIS provides a tool for “self-
learning” in which the quality of the VoI assessments can be improved through 
continuous updating of the decision-making unit, knowledge base, and fuzzification 
and defuzzification interfaces with actual decisions, progressively generating a more 
robust FIS and making the system act closer and closer to the way in which humans 
make decisions. The FIS brings the VoI methodology closer to the decision maker’s 
reasoning. 

These are important advantages of the fuzzy compared with the classical VoI 
assessment.  

The fuzzy approach for VoI assessment requires a longer and more complex 
analysis of the data to be acquired and their outcomes. However, this additional effort 
worth due to the impact it has in the decision. 

As a summary, the use of the FIS makes it possible to have a system that can 
integrate the linguistic variables that are part of human language, reasoning, and 
understanding, but not necessarily part of the Boolean logic used in the standard VoI, 
into the prescriptive VoI assessment. 

VoI assessment using the FIS brings the decision-making process one step forward 
with respect to the classical VoI approach. To have tools and methods that replicate 
the human reasoning process for assessing VoI increases the confidence of the 
decision maker in those procedures, thereby increasing their use and making the tools 
more reliable. 

Decisions are made by human, and because human thinking is approximated more 
accurately by imprecise logic than by crisp logic, this research work successfully 
develop a methodology that integrate the human logic in the VoI assessment, in special 
to problems in the oil and gas industry; the integration of the imprecise thinking and 
terminology in the VoI is made through the use of FIS. 

 



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