International Journal of Interactive Mobile Technologies (iJIM) – eISSN: 1865-7923 – Vol. 14, No. 21, 2020


Paper—Improving the Project Risk Competence using M-Learning: A Case of Bachelors in Technical… 

Improving the Project Risk Competence using  
M-Learning: A Case of Bachelors in  

Technical Fields 
https://doi.org/10.3991/ijim.v14i21.18443 

Anatoly Kozlov (*), Olga Tamer, Larisa Bondarovskaya,  
Svetlana Lapteva 

Branch of Tyumen Industrial University, Noyabrsk, Russia 
kozlovanat77@rambler.ru / nashdoc@yandex.ru 

Abstract—Mobile technology is a popular tool used to improve education 
efficiency, increase the availability of education and motivation for it across 
generations who have grown up in a digital environment. However, its impact on 
learners in risk assessment training in financial and engineering education fields 
is unknown. Projects are fraught with risks, so individuals responsible for a 
project need to possess strong skills to handle the risky circumstances 
successfully. Unfortunately, candidates for a bachelor’s degree in technical fields 
in Russia have an insufficient risk competence. This study offers a five-unit 
program combined with mobile learning to solve this problem. The study 
involved 128 students recruited from the Noyabrsk Institute of Oil and Gas 
(Yamalo-Nenets Autonomous Okrug, Russia). All participants were divided into 
three groups: two experimental and one control. During a semester, participants 
in the experimental groups followed the proposed program in a mobile setting, 
while the control group was offered the standard curriculum. One of the 
experimental groups received a part of the instruction using mobile technology, 
while the other was trained according to a traditional in-class mode. Based on the 
learning outcomes, three types of tests were conducted: one was on math 
problems, and two others comprised problem-solving tasks. The results showed 
an improvement in the student outcomes: the test scores of the experimental 
groups were higher by 24.78% and 32.75% than that of the control group. 
Furthermore, mobile learners were found to perform better than classroom 
learners. Thus, the hypothesis of the study about the advantage of the proposed 
training program (IAMF) in the field of risk management was confirmed, and the 
greater effectiveness of training based on mobile learning was provided. 

Keywords—Innovation activity assessment, mobile learning, project risk, risk 
assessment, technical specialist 

1 Introduction 

In digital pedagogy, mobile learning and cloud technology in financial training are 
amongst the least studied topics [1]. Meanwhile, the role of digital systems that permit 

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Paper—Improving the Project Risk Competence using M-Learning: A Case of Bachelors in Technical… 

deepening of learning is not to be called into question [2]. A risk management system 
is a complex top-down framework for manipulating risks and opportunities in order to 
reach the desired result. The system deals with capital investment and economic rela-
tions between businesses that pose a certain degree of risk. In modern conditions, risk 
management systems coexist and integrate with digital technologies that enable big data 
processing, cloud computing, forecasting and decision-making operations [3,4]. The 
risk management framework is a selection of techniques and tools for predicting the 
likelihood of risks so that their negative consequences can be excluded or reduced. It 
also includes policies and procedures established for the identification, measurement, 
management, and control of risks [5]. 

The use of mobile devices and cloud technologies makes it possible to simultane-
ously implement several of the most important concepts of higher education. These are 
learning anytime, anywhere, lifelong learning and learning from multiple sources [1,6]. 
The accessibility of technologies and information becomes real only with the use of 
mobile devices and networks as a means of learning, which requires the formation of 
certain skills in students, preferably from a very early age [7]. Mathematical knowledge 
and skills require a relatively large amount of so-called deep work, concentration and 
frequent reference to sources and exercises. It is more convenient to organize such ac-
cess using mobile and online technologies [4,8]. 

To date, there are little undertakings for the design of digital, specifically mobile, 
learning environments for corporate risk specialists [6]. Furthermore, technical fields 
are challenged by insufficient project risk competence. The process of decision making 
by project executors is fraught with risks (uncertainty), especially when there are many 
random factors influencing the execution [9]. In view of this, the economic efficiency 
analysis of the investment project will be incomplete and unreliable if the risk aspect of 
the project is neglected. 

2 Literature Review 

Very few studies are devoted to risk analysis training in a mobile setting. Most of 
them relate to single cases of using mobile technologies to educate users or facilitate 
financial analysts in their work [1,10]. Nevertheless, it is known that mobile technolo-
gies offer the potential to significantly improve the quality of education within many 
fields. This effect arises from the increased degree of freedom given to students, on the 
one hand, and from the improved communication with the teacher, on the other [8]. 

Mobile devices give access to information, which may be taken at any time from the 
cloud. This feature provides a student with the opportunity to learn at their own pace 
[2,6]. With the aid of mobile devices, students can find help instantly, whilst teachers 
may control the learning process and better guide their students during the assignments 
[11]. The use of ready-made mobile platforms makes it possible to accelerate the inte-
gration of classic programs focused on classroom teaching into an online format. This, 
in turn, increases the audience’s access to new knowledge and makes it easier for stu-
dents to form their own educational trajectory [12]. From this perspective, the use of 
mobile technologies facilitates in-depth learning and immersion into the topic. 

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Paper—Improving the Project Risk Competence using M-Learning: A Case of Bachelors in Technical… 

Mathematical knowledge requires constant work and regular revision. In the practice 
of using a digital environment, researchers have noticed that the use of elements of 
mobile learning and access to assignments and class materials through mobile devices 
increase the quality of learning, reduce anxiety, and create conditions for improving 
academic achievements [13]. The scholars have also found that a critical factor in the 
formation of effective skills using mobile learning is the level of acceptance, the level 
of digital competence and the high assessment of mobile and online learning technolo-
gies by teachers [7,14]. These criteria correspond almost equally to the use of mobile 
technologies in elementary, secondary, and higher education. If at an early age the foun-
dations of digital literacy are laid, and the skills of using the digital environment as a 
learning environment are formed, then the success of a student and future professional 
will be much more prominent [12,14]. 

In the economic analysis of a company, there is a variety of risk-based decision-
making techniques. These methods are based on the assessment of innovation activity 
performed by a company. Nikolskaya et al. [15] used a taxonomy-based approach to 
assess innovative potential. The comprehensive assessment framework for innovation 
activity consists of a composite innovation activity indicator and three variables that 
affect the composite: the percentage of R&D; the number of new solutions over the 
year; and the number of new competencies acquired by a company due to innovative 
activities [16]. A stepwise approach to assessing the company’s level of innovation in-
volves the settlement of metrics; adjustment of measurements; and identification of 
those parameters that can make up an integrated measure [17]. The risk assessment 
framework for investment projects has been recently given attention [4,18,19]. One of 
the most common methods for assessing innovative project risks is the expert method 
[20]. Using a fuzzy logic approach, Boldyrev sky et al. [21] conducted a quantitative 
and qualitative analysis of risk factors based on impact and probability variables. Each 
and every risk management system is unique, as it deals with risks that vary depending 
on the project. Within the industry, though, projects may be exposed to similar risks 
[22]. Since the risk level of the project varies depending on the amount of expected 
losses, managers make decisions by using risk scales, a tool for determining the threat 
level [23]. 

Some studies examine risk management frameworks for higher education [24,25], 
other focus on projects implemented in various industries. Dehdasht et al. [26] have 
investigated risks in oil and gas construction projects with the DEMATEL-ANP ap-
proach (Laboratory for Testing and Evaluation of Decision Making and Analytical Net-
work Processes). That method helps one to construct a structural relationship among 
the different influence factors to visualize complex correlations. The financial risk of 
investments in timber transportation was quantified by building pseudorandom scenar-
ios with the Monte Carlo simulation method, in addition to the Net Present Value tech-
niques, the Modified Internal Rate of Return, and the Profitability Index, all commonly 
used in financial investment projects [27]. Risks of investment in water management 
projects were addressed using a hybrid multi-criteria decision-making method that in-
tegrates quantitative and qualitative criteria value domains in the same decision-making 
model. The method is based on a decision expert and multi-attribute utility theory meth-
ods, which were modified to facilitate conversion between criteria domains [28]. 

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Muriana and Vizzini [29] used a deterministic technique to assess and prevent pro-
ject risks. Comparing input factors with the planned ones (costs, quality, and time) at 
each phase of the project, they measured the impact of actual performances on the pro-
ject. The risk degree of the project was determined using the Weighted Sum Method. 
Through a cross-country survey, Weingarten et al. [30] examined differences in supply 
chain integration efficacy based on the business risk (measured in terms of the rule of 
law) and the mitigating effect of the supply chain risk management practices. Dereli 
and Altun [31], Guerard et al. [32], Farooq et al. [33], and Korol [34] addressed the risk 
of innovation projects using mathematical methods for calculation. Raskatova [35] as-
sessed the risk of investment projects through the Fuzzy Set Theory. 

Preliminary analysis of bachelor training revealed the following shortcomings. First, 
bachelors majoring in technical fields have insufficient competencies to assess and han-
dle project risks as well as to model innovation activities through a variety of methods 
for quantitative risk analysis. This requires more regular classes and a number of special 
tasks that increase student’s competence that can naturally be implemented using mo-
bile learning and mobile access to learning materials and assignments [12,36]. These 
include statistical and analytical techniques, expert and analogy methods, financial sta-
bility and solvency assessment frameworks, and cost-benefit approach. Second, the 
teaching and learning framework needs improvement to meet modern requirements to 
its methodological and organizational dimensions. 

Research hypothesis: vocational technical education will become more effective 
with the use of mobile devices (M-learning) and a systematic approach to model inno-
vation activities in a risky context. The aim of the study is to improve the risk manage-
ment competence of bachelors in technical fields by offering a series of sessions aimed 
at modeling innovation activities of a company operating in a risky environment. 

3 Methods 

The study of three groups of same-year students (two experimental groups and one 
control group with 32 students in each group) was carried out in the Noyabrsk Institute 
of Oil and Gas (Yamalo-Nenets Autonomous Okrug, Russia). Students in the experi-
mental groups received lectures on innovation activity modeling frameworks (IAMF) 
for companies operating in a risky environment, whilst the control group was assigned 
to follow the standard program (the description of the program is given below). 

All participants were 3rd-year students. An experiment with the use of different 
types of training was carried out over three months in the first semester. The participants 
were invited on condition of anonymity; no personal data were collected or stored dur-
ing the study. Based on the results of the training, the participants of all groups passed 
the tests described below almost simultaneously, within two working days, being in 
classroom conditions. Each of the test results was assigned with a unique identifier, and 
thus the personal data of the students were not shared. 

The statistical data obtained as a result of the study were processed and visualized 
using the MS Excel 2016 program. 

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The first and second experimental groups comprised students who received 
knowledge through M-learning and students taught the traditional way, respectively. In 
the M-learning group, learners were given the opportunity to access learning content 
using free cloud storage services such as Google Drive, Microsoft Azure and DropBox 
as well as mobile apps. As a learner proceeded through the course, a teacher uploaded 
a variety of new learning materials to the cloud in the form of a text or a hyperlink. In 
this study, audio and video lectures as well as textual and graphic materials were used. 
All participants were selected on a voluntary basis, informed of the aim of the study, 
guaranteed anonymity and confidentiality. To ensure anonymity in competence assess-
ment, each learner was given a unique identifier. 

The assessment of progress towards competence was carried out via three 10-item 
tests at the end of the training course. The first test consisted of math problems, whilst 
the second and third tests comprised objective questions related to the theory of risk 
and risk modeling, respectively. The correct answers and solutions to the problem were 
rewarded with one point. The maximum score on each test was 10 points. After the 
results of the assessment have been processed, the mean and standard deviation (SD) 
were calculated. The correlation between groups was found.  

The study had limitations due to the fact that it was conducted only in one of the 
universities and specialized only in mathematical problems of determining risks. The 
results for similar training programs can be verified and extrapolated to a wider area, 
and this is the goal of further research. 

4 Results 

4.1 Results of competence assessment  

The results of the study are displayed in Fig. 1. It is evident that learners receiving 
IAMF lectures performed better as compared to control group learners. The difference 
between means of all groups is lower than their standard deviations. For instance, the 
mean of M-learners on the risk modeling test was 8.16 with a standard deviation of 
0.26; the mean of classroom learners on the risk modeling test was 7.88 (SD, 0.27); and 
the mean of the control group was 5.54 (SD, 1.18). 

Thus, the results of different tests within each group are more stably distributed and, 
to a small extent, depend on the qualitative characteristics of the complexity of a par-
ticular test. Moreover, the difference between groups in each test is statistically signif-
icant. The only exception is the risk modeling test, the results of which are always lower 
than in other tests in all groups. 

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Fig. 1. A Comparative Display of Test Results after the IAMF Program 

The best scores in this study belong to M-learners. This suggests that providing stu-
dents with the opportunity to control their own learning experience helps them achieve 
higher results. Not only experimental groups performed significantly better than the 
control one, they scored higher on every test. This indicates the high efficiency of the 
proposed IAMF program. M-learners had scores on the first, second, and third tests 
higher than those of the control group by 24.78%, 30.57%, and 32.75%, respectively. 
At the same time, differences between the means of those tests were not significant: 
8%, 3.5%, and 3.5%, respectively. Nevertheless, the improvement in learning outcomes 
with mobile learning is noticeable enough to conclude that this technology has the  
potential to increase learning efficiency. 

It should be noted that the results also demonstrate their possible dependence on the 
type of tasks. In all three types of tests, the participants showed the lowest results on 
risk modeling tests (8.11, 7.88 and 5.64, respectively). The difference for these tests is 
statistically relevant for each of the results, which indicates the significance of the  
parameter of the qualitative value of the tests performed. The results demonstrated by 
the control group are consistently and statistically lower than the other two groups for 
all types of tests. This indicates that the application of the IAMF methodology shows 
significantly higher learning outcomes compared to the conventional training program. 

4.2 The IAMF program description 

The IAMF program includes course work in statistical (unit 1) and analytical (unit 
2) risk assessment, fuzzy-plural models for evaluating risks (unit 3), and expert analysis 
(unit 4). 

Unit 1. Statistical Methods of Risk Analysis: In this unit, students will learn about 
methods for quantifying risks, for analyzing profits and losses (P&L), for determining 
the probability of a threat event, and for determining the risk level.  

Unit 2. Analytical Methods of Risk Analysis: This unit gives knowledge about the 
sensitivity analysis method, risk-adjusted discount rate approach, certainty equivalent 
method; and the scenario analysis technique. 

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Unit 3. Fuzzy-Plural Approach to Risk Analysis: Students will learn that the 
fuzzy-multiple approach may be efficient in producing solutions with low-quality input 
or in situations where there is no sufficient information base. 

Unit 4. Expert Judgment in Risk Analysis: This unit focuses on a set of logical, 
mathematical, and statistical procedures for processing the expert survey results. 

5 Discussion 

For over a decade, mobile learning has been successfully adopted in many countries. 
Today, many universities around the world integrate M-learning with their education 
programs [36]. There are several factors underlying M-learning effectiveness. Of these, 
the most important factor is that students are already familiar with mobile devices, as 
they were born into the world with digital technology. So far, students view the use of 
smartphones and other gadgets in the classroom as a natural way to learn [11]. Second, 
mobile learning creates flexibility. This is especially important when senior students 
combine study with work. Students who are not yet working, but strive for high aca-
demic success, need to form their own rhythm of learning and access study materials 
and assignments at any time as well as interact with a teacher and classmates in the 
general educational environment. Such an environment is provided by special online 
training systems that support mobile access to their services [13]. 

The ease of access to the learning content gives many students the opportunity to 
deepen their knowledge by looking at sources other than those offered by a teacher 
[1,6]. It is stressful to increase the effectiveness of education while coping with the 
increasing load of information. The solution may be the use of modern teaching aids 
such as mobile devices, gamification tools, and even special means for stimulating the 
nervous system [37]. It is important to understand that mobile learning makes it easier 
to master the material and reduces the stress experienced by students in traditional  
educational environments [38]. A number of studies convincingly demonstrate that it is 
representatives of engineering, mathematics and other computational specialties who 
benefit greatly from the use of mobile learning [1,6,8,11]. There are also separate stud-
ies confirming the effectiveness of the use of mobile and online learning by financiers 
as well as in the framework of education of different age categories and in different 
countries [12,38]. 

It should be noted that very little research is devoted to mobile learning in financial 
education. The study of analytical models for risk modeling normally is calculation-
intensive. Nevertheless, mobile technologies have already been used in Thailand to  
improve decision making in financial management [38]. The advantages of M-learning 
have been demonstrated in this study. Even though both groups in presented research 
receiving training under the new methodology showed significantly better results, the 
group focused on the mobile form of learning showed higher results for all types of 
mathematical problems associated with risk assessment. This indicates both the novelty 
of the current work and the fact that the traditional approach to financial education may 
not be justified today. 

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The proposed education program resulted in significant improvement in student out-
comes. It provides in-depth knowledge about the analytical methods of risk assessment. 
In risk-based innovation activity modeling, analytical methods are applied when the 
available information is limited and quantitative risk analysis is required. These  
methods assess the probability of losses by mathematical models and are used mainly 
for investment projects [19]. 

6 Conclusion 

The present study proves that M-learning will improve the quality of vocational tech-
nical education. The proposed learning course design will help vocational education to 
produce specialists who are capable of dealing with project risks. For instance, redefin-
ing the training framework for bachelors with a systematic approach to innovation  
activity modeling may boost their risk competence. This study does not claim to provide 
an exhaustive scientific description of how the risk competence of bachelors in  
technical fields can be improved. Future research may focus either on developing an 
innovation activity modeling program that will embrace methods other than those  
incorporated in the proposed solution or on improving the present framework for risk 
analysis. 

7 References 

[1] Abou El-Seoud, S., AboGamie, E.A., Salama, M. (2017). Integrated education management 
system via cloud computing. International Journal of Interactive Mobile Technologies, 
11(2): 24-33. https://doi.org/10.3991/ijim.v11i2.6560 

[2] Al-Emran, M., Elsherif, H.M., Shaalan, K. (2016). Investigating attitudes towards the use of 
mobile learning in higher education. Computers in Human behavior, 56: 93-102. 
https://doi.org/10.1016/j.chb.2015.11.033 

[3] Borisova, V.V., Panfilova, E.E., Zhukov, P.V., Matulis, S.N., Matveev, V.V., Teymurova, 
V.E. (2019). Information Support in the Enterprise Risk Management. International Journal 
of Management and Business Research, 9(1): 158-169. 

[4] Fomina, S., Sizikova, V., Shimanovskaya, Y., Kozlovskaya, S., Karpunina, A. (2019). The 
effect of teaching and supply chain management on employees’ skills in small and medium 
sized enterprises of Russia. International Journal of Supply Chain Management, 8(4): 930-
938. 

[5] Hoffmann, R., Kiedrowicz, M., Stanik, J. (2016). Risk management system as the basic par-
adigm of the information security management system in an organization. In MATEC Web 
of Conferences. EDP Sciences. Vol. 76, p. 04010. https://doi.org/10.1051/matecconf/2016 
7604010 

[6] Almaiah, M.A., Man, M. (2016). Empirical investigation to explore factors that achieve high 
quality of mobile learning system based on students’ perspectives. Engineering science and 
technology, an international journal, 19(3): 1314-1320. https://doi.org/10.1016/j.jestch.201 
6.03.004 

114 http://www.i-jim.org



Paper—Improving the Project Risk Competence using M-Learning: A Case of Bachelors in Technical… 

[7] Kalogiannakis, M., Papadakis, S. (2019). Evaluating pre-service kindergarten teachers’ in-
tention to adopt and use tablets into teaching practice for natural sciences. International Jour-
nal of Mobile Learning and Organisation, 13(1): 113-127. https://doi.org/10.1504/ijmlo.20 
19.10016617 

[8] Han, I., Shin, W.S. (2016). The use of a mobile learning management system and academic 
achievement of online students. Computers & Education, 102: 79-89. https://doi.org/10. 
1016/j.compedu.2016.07.003 

[9] Chursin, A., Tyulin, A., Yudin, A. (2016). The model of risk assessment in the management 
of company’s competitiveness. Journal of Applied Economic Sciences, 11(8): 1781-1790. 

[10] Nawaz, A., Waqar, A., Shah, S.A.R., Sajid, M., Khalid, M.I. (2019). An innovative frame-
work for risk management in construction projects in developing countries: Evidence from 
Pakistan. Risks, 7(1): 24. https://doi.org/10.3390/risks7010024 

[11] Thomas, K., Muñoz, M.A. (2016). Hold the phone! High school students’ perceptions of 
mobile phone integration in the classroom. American Secondary Education, 44(3): 19-37. 

[12] Papadakis, S., Kalogiannakis, M., Sifaki, E., Vidakis, N. (2017). Access Moodle using smart 
mobile phones. A case study in a Greek University. In Interactivity, Game Creation, Design, 
Learning, and Innovation. Springer, Cham, pp 376-385. https://doi.org/10.1007/978-3-319-
76908-0_36 

[13] Papadakis, S., Kalogiannakis, M., Sifaki, E., Vidakis, N. (2018). Evaluating Moodle use via 
Smart Mobile Phones. A case study in a Greek University. EAI Endorsed Transactions on 
Creative Technologies, 5(16): 1-9. https://doi.org/10.4108/eai.10-4-2018.156382 

[14] Papadakis, S. (2018). Evaluating pre-service teachers’ acceptance of mobile devices with 
regards to their age and gender: a case study in Greece. International Journal of Mobile 
Learning and Organisation, 12(4): 336-352. https://doi.org/10.1504/ijmlo.2018.10013372 

[15] Nikolskaya, E.Y., Lepeshkin, V.A., Kulgachev, I.P., Popov, L.A., Romanova, M.M., Lebe-
dev, K.A. (2018). Methodological approaches to assessing the innovative potential of enter-
prises in the hotel business. Revista ESPACIOS, 39(27): 30. 

[16] Trachuk, A.V., Linder, N.V. (2019). Innovative activity of industrial enterprises: measure-
ment and effectiveness evaluation. Strategic decisions and risk management, 10(2): 108-
121. https://doi.org/10.17747/2618-947x-2019-2-108-121 

[17] Kretova, N.V., Tsaregorodtseva, E.Y., Khohlova, G.I. (2017). Applying advanced methods 
of evaluation of level of innovative development for industrial sector. In International Con-
ference on Trends of Technologies and Innovations in Economic and Social Studies 2017. 
Atlantis Press. pp. 712-716. https://doi.org/10.2991/ttiess-17.2017.116 

[18] Li, Y., Wang, X. (2018). Risk assessment for public–private partnership projects: using a 
fuzzy analytic hierarchical process method and expert opinion in China. Journal of Risk 
Research, 21(8): 952-973. https://doi.org/10.1080/13669877.2016.1264451 

[19] Nesticò, A. (2016). Risk-Analysis Techniques for the Economic Evaluation of Investment 
Projects. In Seminar of the Italian Society of Property Evaluation and Investment Decision. 
Springer, Cham. pp. 617-629. 

[20] Treshchevsky, D.Y., Franovskaya, G.N., Gladkih, M.O., Treshchevskaya, N.Y. (2020). 
Risks of Innovative Projects: An Expert Review. In Popkova, E., Sergi, B. (Eds.), Digital 
Economy: Complexity and Variety vs. Rationality. ISC 2019. Lecture Notes in Networks 
and Systems. Vol 87. pp 591-598. https://doi.org/10.1007/978-3-030-29586-8_68 

[21] Boldyrevskii, P.B., Igoshev, A.K., Kistanova, L.A. (2018). Assessing the risk inherent in 
innovation processes. Economic analysis: theory and practice, 17(8): 1465-1475. https:// 
doi.org/10.24891/ea.17.8.1465 

[22] Konovalova, A. (2018). Risk Management of Innovative Projects: New Aspects. In Kabash-
kin, I., Yatskiv, I., Prentkovskis, O. (Eds.), Reliability and Statistics in Transportation and 

iJIM ‒ Vol. 14, No. 21, 2020 115



Paper—Improving the Project Risk Competence using M-Learning: A Case of Bachelors in Technical… 

Communication. RelStat 2017. Lecture Notes in Networks and Systems. Vol 36. pp 172-
181. https://doi.org/10.1007/978-3-319-74454-4_16 

[23] Gasparyan, M.S., Kiselev a, I.A., Korneev, D.G., Lebedev, S.A., Lebedev, V.A. (2018). 
Strategic analysis of risks when implementing investment projects. Revista Espacios, 
39(27): 16. 

[24] Borkovskaya, V., Bardenwerper, W., Roe, R. (2018). Interactive teaching of risk manage-
ment in the Russian construction industry. In IOP Conference Series: Materials Science and 
Engineering. IOP Publishing. Vol. 365, No. 6, p. 062030. https://doi.org/10.1088/ 
1757-899x/365/6/062030 

[25] Kalimullin, A.M., Youngblood, V., Kozyrev, E.A. (2016). The System of Management of 
Innovation Projects at a Higher Education. International Journal of Environmental and Sci-
ence Education, 11(5): 613-622. 

[26] Dehdasht, G., Mohamad Zin, R., Ferwati, M.S., Abdullahi, M., Keyvanfar, A., McCaffer, 
R. (2017). DEMATEL-ANP risk assessment in oil and gas construction projects. Sustaina-
bility, 9(8): 1420. https://doi.org/10.3390/su9081420 

[27] Simões, D., Mosquera, G.A.D., Batistela, G.C., de Souza Passos, J.R., Fenner, P.T. (2016). 
Quantitative analysis of uncertainty in financial risk assessment of road transportation of 
wood in Uruguay. Forests, 7(7): 130. https://doi.org/10.3390/f7070130 

[28] Brelih, M., Rajkovič, U., Ružič, T., Rodič, B., Kozelj, D. (2019). Modelling decision 
knowledge for the evaluation of water management investment projects. Central European 
Journal of Operations Research, 27(3): 759-781. https://doi.org/10.1007/s10100-018-0600-
5 

[29] Muriana, C., Vizzini, G. (2017). Project risk management: A deterministic quantitative tech-
nique for assessment and mitigation. International Journal of Project Management, 35(3): 
320-340. https://doi.org/10.1016/j.ijproman.2017.01.010 

[30] Weingarten, F., Humphreys, P., Gimenez, C., McIvor, R. (2016). Risk, risk management 
practices, and the success of supply chain integration. International Journal of Production 
Economics, 171: 361-370. https://doi.org/10.1016/j.ijpe.2015.03.020 

[31] Dereli, T., Altun, K. (2003) A novel approach for assessment of technologies with respect 
to their innovation potentials. Expert Systems with Applications, 40(3): 881-891. https://d 
oi.org/10.1016/j.eswa.2012.05.044 

[32] Guerard, J.B. Jr., Markowitz, H.M., Xu, G. (2015). Earnings forecasting in a global stock 
selection model and efficient portfolio construction and management. International Journal 
of Forecasting, 31: 550-560. https://doi.org/10.1016/j.ijforecast.2014.10.003 

[33] Farooq, M., Thaheem, M., Arshad, H. (2018). Improving the risk quantification under be-
havioural tendencies: a tale of construction projects. International Journal of Project Man-
agement, 3: 414-428. https://doi.org/10.1016/j.ijproman.2017.12.004 

[34] Korol, S.P. (2016) Innovative development of the construction industry as an economic cat-
egory of the management object. Regional economy and management: electronic scientific 
journal, 1(45): 4501 

[35] Raskatova, M.I. (2013). Risk assessment of investment projects through the fuzzy set theory. 
Issues of Economics and Management, 4(20): 63-67.  

[36] Suartama, I., Setyosari, P., Sulthoni, S., & Ulfa, S. (2020). Development of Ubiquitous 
Learning Environment Based on Moodle Learning Management System. International Jour-
nal of Interactive Mobile Technologies, 14(14): 182-204. https://doi.org/10.3991/ijim. 
v14i14.11775 

[37] Yumashev, A.V., Utyuzh, A.S., Admakin, O.I., Doroshina, V.Y., Volkova, I.R. (2018) Ef-
fect of mesodiencephalic stimulation on adaptation to stress and academic performance of 

116 http://www.i-jim.org



Paper—Improving the Project Risk Competence using M-Learning: A Case of Bachelors in Technical… 

students. International Journal of Learning and Change, 10(4): 359-367. 
https://doi.org/10.1504/ijlc.2018.10016003 

[38] Mueangpud, A., Khlaisang, J., Koraneekij, P. (2019). Mobile Learning Application Design 
to Promote Youth Financial Management Competency in Thailand. International Journal of 
Interactive Mobile Technologies, 13(12):1 9-38. https://doi.org/10.3991/ijim.v13i12.11367 

8 Authors 

Kozlov Anatoly Vasilyevich is a Doctor of Pedagogical Sciences, Head of the De-
partment of Transport and Technologies of Oil and Gas Complex, Branch of Tyumen 
Industrial University in Noyabrsk, Noyabrsk, Russia. Email: kozlovanat77@rambler.ru, 
nashdoc@yandex.ru  

Tamer Olga Salikhyanovna is a Doctor of Pedagogical Sciences, Head of the De-
partment of Applied Mathematics and Natural Sciences, Branch of Tyumen Industrial 
University in Noyabrsk, Noyabrsk, Russia. 

Bondarovskaya Larisa Vladimirovna is a Candidate of Pedagogical Sciences, As-
sistant Professor of the Department of Applied Mathematics and Natural Sciences, 
Branch of Tyumen Industrial University in Noyabrsk, Noyabrsk, Russia. 

Lapteva Svetlana Vasilievna is a Candidate of Pedagogical Sciences, Assistant 
Professor of the Department of Transport and Technologies of Oil and Gas Complex, 
Branch of Tyumen Industrial University in Noyabrsk, Noyabrsk, Russia. 

Article submitted 2020-09-11. Resubmitted 2020-10-21. Final acceptance 2020-10-21. Final version pub-
lished as submitted by the authors.  

iJIM ‒ Vol. 14, No. 21, 2020 117