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 CHEMICAL ENGINEERING   TRANSACTIONS
 

VOL. 43, 2015 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Chief Editors: Sauro Pierucci, Jiří J. Klemeš 
Copyright © 2015, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-34-1; ISSN 2283-9216                                                                               
 

Human Error Probability Estimation in ATEX-HMI Area 
Classification: from THERP to FUZZY CREAM 

Jie Geng*a,b, Salvina Murèa, Baldissone Gabrieleb, Gianfranco Camuncolia,  

Micaela Demichelab  
a
 ARIA s.r.l. – Corso Mediterraneo 140 -10129 Torino, Italia 

b
 SAfeR, Dipartimento di Scienza Applicata e Tecnologia, Politecnico di Torino, Corso Duca degli Abruzzi, 24 –  

10129 Torino, Italia 
jie.geng@aria.to.it 

ATEX (explosive atmosphere) risk assessment is required when any equipment or system can potentially 
cause explosive atmospheres. Although many operations are performed by operators, influences from human 
and organizational factors (HOFs) are mostly neglected. In order to address HOFs influence, the ATEX-HMI 
(Human-Machine Interaction) methodology is proposed: it aims at integrating HOFs into each step of the 
standard ATEX risk assessment. The first step faced is Area classification: the ATEX-HMI methodology 
introduces the Human Error Probability (HEP) into the zone calculation procedure. Human Reliability Analysis 
(HRA) is the main method for the HEP assessment, thus two HRA methods were applied for the ATEX-HMI 
methodology. The first one, THERP, demonstrated an efficient quantitative precision, but it was not easily 
applicable to real industries. Then, the Cognitive Reliability and Error Analysis Method (CREAM) was adopted, 
together with a complementary FUZZY application for quantitative analysis. The present paper introduces the 
FUZZY CREAM application, also showing a comparative analysis of THERP and FUZZY CREAM, on the 
basis of a food plant case study.      

1. Introduction 

ATEX (explosive atmosphere) risk assessment is required when an equipment or system can potentially 
cause explosive atmospheres. The standard ATEX risk assessment is a semi-quantitative approach, based on 
the following indexes: 1) likelihood of an explosive atmosphere occurring, 2) likelihood of ignition sources 
present on site, 3) consequences. Influences by human and organizational factors (HOFs) are mostly 
neglected from the standard ATEX risk assessment, although many operations are performed by operators 
(e.g. maintenance activity, as in Demichela et al., 2014, that could even bring to major accidents, as in 
Piccinini & Demichela, 2012; Leva et al., 2012). In order to deal with HOFs influence, ATEX-HMI (Human-
Machine Interaction) methodology was proposed by the authors and is actually in progress. Figure 1 shows 
the ATEX-HMI risk assessment framework with the HOFs integration: for each step of the standard ATEX risk 
assessment, human error probability (HEP) is introduced. In this way, the final result of the risk assessment 
RHOF will be influenced by the values of PHOF, CHOF and D’HOF. In an early phase (Geng et al., 2014), a task-
dominant Human Reliability Analysis (HRA) method - the Technique for Human Error Rate Prediction 
(THERP, Swain and Guttmann, 1983) - was introduced for the HEP assessment. Nevertheless, it revealed 
some issues during the on-site application among real industries:  
1) The lack of data related to actual human performances challenges the accuracy of the HEP prediction. 

Indeed the data made available by THERP simulator (Swain, 1990) are designed for nuclear plants, and it 
is difficult to adapt these raw data to other types of industries. 

2) The Performance Shaping Factors (PSFs), such as organizational factors, cultural differences, and 
irrational behavior are not adequately treated in THERP, and neither specific rules are given to assess the 
states of these PSFs and their effects on HEP. 

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DOI: 10.3303/CET1543208 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Geng J., Mure S., Baldissone G., Camuncoli G., Demichela M., 2015, Human error probability estimation in atex-hmi 
area classification: from therp to fuzzy cream, Chemical Engineering Transactions, 43, 1243-1248  DOI: 10.3303/CET1543208



3) End users generally are Health & Safety Experts, whose professional background is not related to human 
factors domain. The request to assign values in order to obtain the HEP can be very complex and strongly 
increases HSEs workload: for one single task, 27 tables have to be compiled. Also, HSEs’ insufficient 
knowledge in Human Factors may lead to uncertain HEP predictions.  

Therefore, the objective of the further phase of this study was to identify an easier and more applicable 
technique for the HEP estimation, and to integrate it into the 1st step of the standard ATEX risk assessment 
procedure (Area classification). 

 

Figure 1. The Framework of ATEX-HMI Risk Assessment Methodology (Geng et al., 2014) 

2. Integration of HOFs into ATEX-HMI Area Classification  

Standard ATEX Area classification deals with situations of normal operation, maintenance, and predictable 
failures; its first step, Area classification, generally includes: 1) the identification of release sources - each item 
of the process equipment which contains a flammable material is considered as a potential release source;  2) 
assessment of the internal and external zones of the identified emission sources, on the basis of  release rate, 
concentration, velocity, ventilation and other factors (such as prevention measures). Italian Guidelines CEI 31-
35, 2012; & CEI 31-56, 2007 provide also another method to conduct the Area classification, based on 
probability values (see Table 1); this is allowed only when the statistical data on the probability of explosive 
atmosphere occurring are available and reliable. However, Table 1 can be also employed in reverse, to 
assess probability ranges starting from normal Area classification. In fact, ATEX-HMI area classification takes 
advantage of Table 1 indexes to integrate the Human Error Probability (HEP) into zone prediction, so that the 
final probabilistic safety assessment (PSA) will be the sum of the probabilities corresponding to the obtained 
zones and the HEP. 

Table 1: Evaluation Criteria of the ATEX-HMI Area Classification (CEI 31-35, 2012; & CEI 31-56, 2007) 

Area 
Classification  

Probability of Explosive Atmosphere 
Occurring in 365 days 

Descriptor 

Zone 0/20 10-1 ˂ P 
Explosive atmosphere is continuously present, for 
long periods or frequently. 

Zone 1/21 10-3˂ P≤10-1 
Explosive atmosphere is sporadically present, 
during normal operations. 

Zone 2/22 10-5 ˂ P≤10-3 
Explosive atmosphere is not present during normal 
operations, or infrequently present, for a short 
period. 

Zone NE P ˂ 10-5 Neglectable 

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3. HEP Estimation: from THERP to FUZZY CREAM 

3.1 CREAM - Cognitive Reliability and Error Analysis Method  
After THERP application, a cognition-dominant HRA method was chosen: CREAM - Cognitive Reliability and 
Error Analysis Method. This method covers technical, human and organizational factors, and provides a 
relatively stable HEP output; also, it was designed for different types of industries (Chandler, et. al, 2006). 
CREAM defines 9 Common Performance Conditions (CPCs) as Performance Shaping Factors (PSFs), and 
provides a two-level method to calculate Human Error Probability (HEP): the basic method and the extended 
method. The basic method uses task analysis to identify human actions, and assesses the Common 
Performance Conditions (CPCs) by judging the expected effects and making a total or combined score of 

them with the triplet [reduced, not significant, improved]. Final results are interpreted through a control mode matrix: 
4 possible control modes (Strategic, Tactical, Opportunistic, Scrambled), defined by the Contextual Control 
Mode - COCOM, can be determined. If the basic method is not sufficient, CREAM provides the extended 
method to produce specific action failure probabilities (Hollnagel, 1998). 
 
3.2 FUZZY CREAM 
Starting from CREAM basic method, Konstandinidou et al. (2006) introduced FUZZY CREAM as a 
complementary methodology to assess the HEP. For this study, a dedicated tool was developed to apply 
FUZZY CREAM, based on both contributions from Konstandinidou et al. (2006) and Monferini et al. (2013). 
Meanwhile, the Fuzzy Logic Toolbox in Matlab® was used for the result validation. 
Step 1 - Fuzzification 
Fuzzy logic starts with the concept of a fuzzy set. In practice, if X is the universe of discourse and its elements 
are denoted by x, then a fuzzy set A in X is defined as a set of ordered pairs. 
A = {x, μA(x) | x X} 
μA(x) is called the membership function (or MF) of x in A. The membership function maps each element of X to 
a membership value between 0 and 1. In this FUZZY CREAM tool, triangular membership function was used 
as straight lines to describe the distributions of each level of a fuzzy input set. The 9 CREAM CPCs mentioned 
in Section 3.1. were used to build the input fuzzy sets (see Table 2) and also the output fuzzy sets were 
derived from the four control modes provided by COCOM (see Table 3).  
Step 2 -  Fuzzy inference 
Fuzzy inference is a method that interprets the values in the input vector and, based on some set of rules, 
assigns values to the output vector. The primary mechanism is doing a list of “if-then” rules. Since in fuzzy 
logic the truth of any statement is a matter of degree, min-max operations are applied to resolve the 
statement. In FUZZY CREAM, the rules are constructed in simple linguistic terms and Mamdani's fuzzy 
inference method is applied. Furthermore, 46656 rules are generated. Here the first rule is presented as an 
example: “IF Adequacy of Organization is very efficient, AND Working Conditions is advantageous, AND 
Adequacy of MMI and Operational Support is supportive, AND Availability of Procedures / Plans is 
appropriate, AND Number of Simultaneous Goals is fewer than capacity, AND Available Time is adequate, 
AND Time of Day (Circadian Rhythm) is unadjusted Night-time, AND Adequacy of Training and Experience is 
adequate with high experience, AND Crew Collaboration Quality is very efficient, THEN output is Strategic 
control mode.” 
Step 3 - Defuzzification 
Defuzzification transforms the final aggregated output fuzzy sets into a single numerical value; the developed 
FUZZY CREAM tool adopted Centroid method for it. The output from Step 2 composes an aggregated area; 
Centroid defuzzification allows to return the center of area under the curve, which is the HEP. 
Step 4 -Validation of Results by Matlab® 
Fuzzy logic toolbox in Matlab® provides an alternative way to gain HEP from FUZZY CREAM. It was used to 
validate the result derived from FUZZY CREAM tool application.  

Table 2. CPCs in CREAM as FUZZY input sets (Konstandinidou et al., 2006; Monferini et al. 2013) 

Inputs Range 
Fuzzy 
Sets 

Level/Descriptors Effect 
Membership 

Level Intervals 

CPC 1 
Adequacy of 
Organization 

[0,100] 4 

Very Efficient Improved MF1 70-100 
Efficient Not significant MF2 40-90 
Inefficient Reduced MF3 10-60 
Deficient Reduced MF4 0-25 

CPC 2 
Working 

Conditions 
[0,100] 3 

Advantageous Improved MF1 70-100 
Compatible Not significant MF2 20-80 
Incompatible Reduced MF3 0-30 

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Inputs Range 
Fuzzy 
Sets 

Level/Descriptors Effect 
Membership 

Level Intervals 

CPC 3 

Adequacy of 
MMI and 

Operational 
Support 

[0,100] 4 

Supportive Improved MF1 70-100 
Adequate Not significant MF2 40-90 
Tolerable Not significant MF3 10-60 
Inappropriate Reduced MF4 0-25 

CPC 4 
Availability of 
Procedures / 

Plans 
[0,100] 3 

Appropriate Improved MF1 70-100 
Acceptable Not significant MF2 20-80 
Inappropriate Reduced MF3 0-30 

CPC 5 
Number of 

Simultaneous 
Goals 

[0,100] 3 

Fewer than capacity Not significant MF1 70-100 
Matching current 
capacity 

Not significant MF2 20-80 

More than capacity Reduced MF3 0-30 

CPC 6 Available Time [0,100] 3 
Adequate Improved MF1 70-100 
Temporarily inadequate Not significant MF2 20-80 
Continuously inadequate Reduced MF3 0-30 

CPC 7 
Time of Day 
(Circadian 
Rhythm) 

[0,24] 3 
Night-time, (unadjusted) Reduced MF1 16-24 
Day-time, (adjusted) Not significant MF2 8-17 
Night-time, (unadjusted) Reduced MF3 0-9 

CPC 8 
Adequacy of 
Training and 
Experience 

[0,100] 3 

Adequate, High 
Experience 

Improved MF1 70-100 

Adequate, Limited 
Experience 

Not significant MF2 20-80 

Inadequate Reduced MF3 0-30 

CPC 9 
Crew 

Collaboration 
Quality 

[0,100] 4 

Very efficient Improved MF1 70-100 
Efficient Not significant MF2 40-90 
Inefficient Not significant MF3 10-60 
Deficient Reduced MF4 0-25 

Table 3. Control modes with logarithm format as Fuzzy output sets  

Action 
Failure 

Probability 

UOD 
Number of 

Fuzzy 
Sets 

Level/ 
Descriptors 

HEP Ranges 
Membership Level 

Intervals 
(Logarithm Format) 

[0,1] 4 

Strategic 0.5 ×10
-5
˂ P ˂ 1.0 ×10

-2
-5.3 to -2.3 

Tactical 1.0 ×10
-3
˂ P ˂ 1.0 ×10

-1
 -3.3 to -1.3 

Opportunistic 1.0 ×10
-2
˂ P ˂ 0.5×10

0
-2.3 to -0.3 

Scrambled 1.0 ×10
-1
˂ P ˂ 1.0 ×10

0
 -1.3 to 0 

4. Application of FUZZY CREAM  

FUZZY CREAM tool was applied to a case study from a food manufacturing company, which produced food 
stabilizers, ingredients, starches and gums. The ATEX Area Classification identified 44 emission sources; 
among them, a dust cartridge filter was chosen to analyse the difference between standard ATEX area 
classification and the ATEX-HMI area classification. According to the instruction manual, the dust cartridge 
filter needed to be regularly replaced, depending on the frequency of use. Lacking or failure of the 
replacement procedure can cause a dust surplus inside the filter that could break and produce external 
explosive atmospheres. The initial area classification results for the filter were: zone 20 (dirty side) and zone 
22 (clean side) inside, and zone 22 outside. The evaluation assumed that operators or maintainers always 
replaced the filter in the correct way. Thus, the initial probability range of explosive atmosphere occurring in 
the area around the filter was 10-3≥P>10-5 in 365 days. However, the calculated probability range did not take 
into account the human failures in the replacement phase, thus FUZZY CREAM tool was applied to estimate 
the Human Error Probability (HEP). The 9 CPCs values were estimated by the company EHS experts, and 
they were used to constitute the input vector for FUZZY CREAM application. Figure 2, reported in the 
following page, shows the tool interface for the 9 CPCs membership functions. Then, FUZZY CREAM tool 
assessed the HEP as explained in Section 3.2. The HEP output obtained for the case study was 1.58×10-2. 
After the application of FUZZY CREAM tool, the probability of explosive atmosphere occurring in 365 days 
resulted as the sum of the HEP value (1.58×10-2) and the initial probability value (10-3≥P>10-5): the probability 
range changed into 10-1≥P>10-3. As a consequence, also the area classification was modified: inside the filter 
remained the zone 20 (dirty side) and zone 22 (clean side), while the outside area was classified as zone 21, 
instead of zone 22 (see Table 4). This result shows that the risk of explosive atmosphere occurring is 
potentially higher than that calculated by the standard ATEX area classification. 

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Figure 2. Interface of FUZZY CREAM tool of the input vector: [70 65 20 65 25 50 16 60 10] 

Table 4: ATEX-HMI Area Classification Assessment Results  

Emission 
Source 

Emission 
Degree 

Generated Zone Assumption HEP Amended Zone 

A Dust 
Cartridge 

Filter 
Secondary 

Inside Dirty Side: 20 
Inside Clean Side: 22 

Outside: 22 

Replace 
GV5 in the 
incorrect 

way 

2.43×10-2* 
(THERP) Inside Dirty Side: 20 

Inside Clean Side: 22 
Outside: 21 

1.58×10-2 
(FUZZY 
CREAM) 

Note: * the HEP value is estimated in the previous work of Geng et al. (2014). 

5. Comparison of FUZZY CREAM and THERP 

The dust cartridge filter case study was firstly subjected to THERP application (Geng et al., 2014), and then to 
FUZZY CREAM, as shown in Section 4; the improvements led by the second method are hereinafter 
explained. 
1) PSF. THERP identifies Performance Shaping Factors (PSF) that influence HEP, but it doesn’t precisely 
define the rules (only 3 PSFs are involved in the calculation) for their application. On the contrary, CREAM is 
able to consider technical, human and organizational factors, and it gives very detailed indications on how to 
treat Common Performance Conditions (CREAM CPCs are the equivalent to THERP PSFs).  
2) HEP assessment. THERP requires the compiling of many tables, which need a professional background in 
HOFs. The two levels approach provided by CREAM allows the users to choose the basic method for HEP 
calculation, which is very easy to apply. Also, FUZZY CREAM tool can be easily handled by the general safety 
specialists, after a short training period. 
3) Time consuming. HEP calculation in THERP needs more time, because of the tables compiling. On the 
contrary, the developed FUZZY CREAM tool permits to spare time, because it only requires to safety 
specialists to assign a judgment to the CPCs; then HEP output is generated by the tool itself.  
The above mentioned considerations make clear that FUZZY CREAM is an easier tool for the direct 
application in real-work environments: indeed it meets the need for simple, rapid but effective tools, and 
therefore it can be employed in many different types of industries. 

6. Conclusions 

Neglecting HOFs influence can threaten both system safety and performance. As shown in Section 4, also for 
ATEX risk assessment, the assumption that operators and maintainers are constantly able to operate in a 
correct way can lead to area classifications that could not be conservative enough. As a consequence, 
unexpected events may occur. The introduction of the ATEX-HMI Risk assessment methodology, able to take 
into account HOFs, will allow to assess more precisely the ATEX risk, and then to adopt more effective 
prevention and protection measures. Until now, HOFs were integrated into the 1st step of ATEX standard Risk 
assessment – Area classification: the application of HRA method FUZZY CREAM permitted to introduce the 

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Human Error Probability, and produced more accurate results than those of the standard ATEX Risk 
assessment. Even if it is an early stage of the assessment, the change in the area classification showed in 
Section 4 can be considered an important indicator of the HOFs influence, and it could be in any case a 
starting point for safety managers to verify and improve their approach to safety. The research is actually 
proceeding in order to develop HOFs integration in each step of the ATEX Risk assessment.  

Acknowledgements 

This research was supported by INNHF project, financed under EU FP7 Marie Curie Actions Initial Training 
Networks-FP7-PEOPLE-2011-ITN: Project ID 289837. 
 
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