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Corresponding author:
1 Department of Finance and Innovation Management, Vinnytsia National Technical University.
E-mail: djedjulavv@gmail.com
2 Department of Finance and Innovation Management, Vinnytsia National Technical University.
E-mail: epifanovairene@gmail.com

DOI: https://doi.org/10.30525/2256-0742/2018-4-1-126-130

USE OF APPARATUS OF HYBRID NEURAL NET WORKS  
FOR EVALUATION OF AN INTELLECTUAL COMPONENT  
OF THE ENERGY-SAVING POLICY OF THE ENTERPRISE

Vyacheslav Dzhedzhula1, Iryna Yepifanova2
Vinnytsia National Technical University, Ukraine

Abstract. Intellectual capital has a significant impact on the energy-saving policy, which is an indicator of levels of 
competitiveness and efficiency of the enterprise. Making decisions on improving the efficiency of energy-saving 
policies of the enterprise through intellectual capital can be carried out by assessing qualitative, quantitative, and 
binary parameters of the state of the investigated object. Researchers on energy saving issues are scientists such as 
A.M. Asaul, O.I. Amosha, V.M. Heiets, Yu.V. Dziadykevych, V.V. Stadnyk, V. Parkhovnyk, R. Toud. Issues related to the 
definition of the essence of innovation were investigated by O.F. Androsova, T.P. Bubenko, M.P. Voinarenko, V.M. Heiets, 
G. Mensch, M. Kaletski, S.V. Phillippova, J. Schumpeter, A.V. Cherep. Issues of intellectual capital management were 
considered in the works of L. Antoniuk, S.V. Zakharinko, A. Kendiukhov, G.R. Natroshvili, V. Tsipuryndа, L. Fedulova. 
The issue of evaluating the intellectual component of the energy-saving policy, in particular, with the help of the 
apparatus of hybrid neural networks, remains poorly developed. The purpose of the paper is the determination of 
factors of intellectual capital that influence the energy-saving policy, the formation of a mathematical model based 
on the theory of hybrid neural networks to determine the indicator of the intellectual component of the energy-
saving policy of the enterprise. Methodology. Using the theory of hybrid neural networks, a mathematical model 
has been formed and the simulation has been carried out to determine the indicator of the intellectual component 
of the energy-saving policy of the enterprise. Results. The factors influencing the value of this indicator have been 
determined as linguistic variables. A mathematical model has been formed and the simulation has been carried 
out to determine the indicator of the intellectual component of the energy-saving policy of the enterprise. Practical 
implications. If it is necessary, the use of different components of intellectual capital, the proposed mathematical 
model will allow ranking their degree of attractiveness for energy conservation policies. The expert information can 
be provided both by an expert and a group of experts and serves as input information for modelling in the proposed 
mathematical model. Further information and practical experience of implementation of energy saving measures 
can be used for training mathematical model. Value/originality. The use of the proposed mathematical model allows 
you to determine the indicator of the intellectual component of the energy-saving policy of the enterprise, which 
in turn allows you to choose those components of intellectual capital for this enterprise that will make the greatest 
impact on the energy-saving policy.

Key words: intellectual capital, energy saving, human capital, organizational capital, market capital, hybrid neural 
networks.

JEL Classification: C45, G32, G31

1. Introduction

All transactors are trying to be competitive not only at 
the regional level but also at the global level. A high level 
of competitiveness also implies competitive products of 
the right quality, which would meet the world standards 
of quality and have the appropriate price. Taking into 

account the constant increase in the cost of energy, 
most enterprises are faced with finding ways to reduce 
their production cost. Among the promising areas, 
active implementation of energy saving policy can be 
highlighted. For this purpose, the management of the 



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enterprise should pay attention to its own intellectual 
capital.

The effective use of intellectual capital can contribute 
not only to lowering the cost, but also to substantially 
increase the enterprise’s revenues. Making decisions on 
improving the efficiency of the energy-saving policy of 
the enterprise through intellectual capital can be carried 
out by assessing qualitative, quantitative, and binary 
parameters of the state of the investigated object. That 
is why further research is needed on the justification of 
the factors influencing the energy-saving policy of the 
intellectual capital of the enterprise from the standpoint 
of the theory of fuzzy logic and hybrid neural networks.

Researchers on energy saving and the formation of 
energy saving policy are such scientists as A.M. Asaul,  
O.I. Amosha, V.M. Heiets, Y.V. Dziadykevych, 
V.V.  Stadnyk, V. Parkhovnyk, R . Toud. Energy 
saving in modern conditions involves the active 
use of innovations. Issues related to the definition 
of the essence of innovation were investigated by 
O.F.  Androsova, T.P.  Bubenko, M.P.  Voinarenko, 
V.M.  Heiets, G.  Mensch (1979), M.  Kaletski (1963), 
S.V. Phillippova, J. Schumpeter (1934), A.V. Cherep.

Issues of intellectual capital management, its 
influence on innovation activity were considered in the 
works of L. Antoniuk, S.V. Zakharinko, A. Kendiukhov, 
G.R .  Natroshvili, V.  Tsipuryndа, L.  Fedulova. The 
theory of fuzzy logic and linguistic variable allows using 
analytical, experimental, and expert input information 
for the study of causal-consequent relationships of the 
behaviour of the economic system.

At the same time, the issue of evaluating the 
intellectual component of the energy-saving policy, 
in particular, through the apparatus of hybrid neural 
networks, remains inadequately developed.

The purpose of the study is the determination of 
factors of intellectual capital that affect the energy saving 
policy, the formation of a model for determining the 
indicator of the intellectual component of the energy-
saving policy of the enterprise.

2. Components of intellectual capital
The ability of the industrial enterprise to implement 

innovative directions of energy saving is determined 
not only by the financial position of the enterprise but 
also by the level of intellectual capital of employees. 
Non-motivated and not experienced specialists are not 
sufficiently capable of generating new ideas and creating 
the energy-saving directions of the enterprise based on 
their own research. For the formation of a strategy for 
increasing energy efficiency, enterprise management 
can attract both detached and its own experts. But the 
work of attracted energy auditors and energy managers 
still needs the intellectual support of the specialists of 
the enterprise. A thorough study of the peculiarities of 
technological and auxiliary processes is possible only 

with multi-day direct contact with the technological 
and energy systems of the enterprise. Each enterprise 
owns financial and intellectual capital, which consists 
of knowledge, skills, competencies, motivation, and 
experience of employees.

Different authors determine the essence of 
intellectual capital in different ways. In our opinion, 
intellectual capital is a set of knowledge, skills, and ideas 
of employees that can bring certain economic benefits 
and/or enhance the image of the enterprise.

In general, most authors believe that intellectual 
capital consists of three components (Denisenko M. P., 
2013; Di Stefano, Paul J. Kalbaugh, G. Edward, 1999; 
Tsipurynda V., 2013; Bontis Nick, 1996; Bassi Laurie J., 
1997; Seid Mohammad, Reza, Mirahmadia Ali, Attafara 
Saideh Ketabia, 2018):

1. Human capital is a set of knowledge, skills, creative 
abilities, as well as the ability of owners and knowledge-
intensive workers to meet the requirements and targets 
of the enterprise.

2. Organizational or structural capital is computer 
software, databases, organizational structure, patents, 
trademarks, organizational mechanisms that ensure 
the productivity of employees, and the operation of the 
enterprise.

3. Market or consumer capital is future consumers of 
products of the enterprise, the ability of the product to 
meet the needs of consumers.

Thus, intellectual capital is by its nature an intangible 
asset, an integral part of the goodwill, which, due to 
skilful management, can bring significant growth in 
income, profits, and ultimately the competitiveness and 
market value of the enterprise. An essential advantage of 
intellectual capital is that it has an exclusive form and has 
a fairly high added value compared to other resources 
available at the disposal of the company.

It is difficult to assess the level of intellectual 
capital since the indicators that characterize it are 
predominantly evaluated linguistically, qualitatively, 
and not quantitatively, and even more difficult is the 
combination of all indicators of intellectual capital into 
one system and its quantification.

3. Fuzzy model for determination of indicator 
of intellectual component of the energy-saving 
policy of the industrial enterprise

The use of the hybrid neural network allows for a fairly 
accurate assessment of the level of intellectual capital in 
the industrial enterprise. An artificial neural network 
is a collection of mathematical models of neurons that 
are interconnected by synapses (Voinarenko M. P., 
Dzhedzhula V. V., Yepifanova, I. Yu., 2016; Pankevich O. D.,  
Shtovba S. D., 2005; Leonenkov A. V., 2005). The input 
of the neuron receives the result of the interaction of 
the activation function with the sum of the signals 
of the synapses. The synapse’s weight characterizes 



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the binding power and may change in the process of 
network formation and learning.

Hybrid neural networks allow logical conclusions to 
be obtained by means of fuzzy logic, and the adjustment 
of membership functions is carried out by means of 
neural networks. Hybrid networks allow us not only to 
combine the quantitative and qualitative characteristics 
of the object being investigated but also to study, that 
is, the forecast of its characteristics, which is obtained 
through the network, changes with the change of 
parameters of the object. Such features of the hybrid 
neural networks provide the proposed method of 
modelling with the advantages over the classical theory 
of fuzzy logic, where the information bases of knowledge 
formed by experts are final.

The stages of information transformation in the hybrid 
neural network are as follows: phasing – calculation of 
the logical conclusion – the formation of fuzzy logic 
equations – dephasing. The most common method 
of dephasing, that is, the transformation of fuzzy 
information into a clear, is the method of the centroid, 
the most common method of teaching the hybrid neural 
networks is the method of reciprocal error propagation.

At the first stage of modelling, a training sample is 
provided for the input of the neural network and optimal 
parameters of the network nodes are found in the 
process. When new knowledge of the research object is 
entered into the network, a test sample is submitted that 
allows you to adjust the weighting factors.

The linguistic variable Ik, which characterizes the 
value of the intellectual component of the energy-saving 
policy of an enterprise, can be represented as:

( ), ,Ik f B C D=                                                     (1)
where B is an indicator characterizing human capital;
C is an indicator characterizing organizational capital;
D is an indicator characterizing market capital.
The linguistic variable characterizing human capital 

can be represented as:
( )1 2 3 4 5, , , ,B f b b b b b=                     (2)

where b1 is LV “Potential of workers”;
b2 is LV “Level of knowledge of workers”;
b3 is LV “Motivation of workers”;
b4 is LV “Experience of workers”;
b5 –is LV “Ability to work in a team”.
The linguistic variable characterizing the 

organizational capital can be represented as:
( )1 2 3 4 5, c , c , c , cC f c=                                    (3)

where c1 is LV “Corporate culture”;
c2 is LV “Patents”;
c3 is LV “Organizational structure”;
c4 is LV “Level of information development”;
c5 is LV “Technological level of the enterprise”.
The linguistic variable characterizing the market 

capital can be represented as:
( )1 2 3 4 5, d , d , d , dD f d=                                   (4)

where d1 is LV “Loyalty of consumers”;
d2 is LV “Branding”;
d3 is LV “Suppliers”;
d4 is LV “Social activity of the enterprise”;
d5 is LV “Relations with financial institutions”.
The factors of influence as linguistic variables are 

shown in Table 1. 
The mathematical package Matlab has been used for 

simulation. By compiling the training sample according 
to the expert estimates, we set the values of the initial 
indicators within [1 ... 5]. To reduce the computational 
time and the practical use of the proposed approach on 
low-power computers, we determine the value of each 
linguistic variable separately. To select the optimal form 
of membership functions, we carry out several stages of 
simulation and define training errors.

Graphical results of the calculation of training error 
in various forms of membership functions are shown 

Table 1
The factors of influence as linguistic variables

Parameter Symbol and name of the variable Universal set Linguistic terms for evaluation

H
um

an
 c

ap
ita

l  
(B

)

b1 – LV “Potential of workers” U(b1) = {1‒4} (points) absent, low, medium, high
b2 – LV “Level of knowledge of workers” U(b2) = {1‒4}(points) absent, low, medium, high
b3 – LV “Motivation of workers” U(b3) = {1‒4} (points) absent, material, moral, mixed
b4 – LV “Experience of workers” U(b4) = {1‒4} (points) absent, low, medium, high
b5 – LV “Ability to work in a team” U(b5) = {1-3} (points) high, medium, low

O
rg

an
iz

at
io

na
l 

ca
pi

ta
l (

C
)

c1 – LV “Corporate culture”; U(c1) = {1-4} (points) high, medium, low, absent 
c2 – LV “Patents” U(c2) = {1‒3} (points) absent, used purchased, own
c3 – LV “Organizational structure” U(c3) = {1‒3} (points) effective, not sufficiently effective, ineffective
c4 – LV “Level of information development” U(c4) = {1-3} (points) high, medium, low
c5 – LV “Technological level of the enterprise” U(c5) = {1‒5} (points) high, above medium, medium, below medium, low

M
ar

ke
t c

ap
ita

l 
(D

)

d1 – LV “Loyalty of consumers”; U(d1) = {1‒3} (points) high, medium, low
d2 – LV “Branding” U(d2) = {1‒4} (points) high, medium, low, absent
d3 – LV “Suppliers”; U(d3) = {1‒3} (points) reliable, not reliable, missing constant
d4 – LV “Social activity of the enterprise” U(d4) = {1‒4} (points) high, medium, low, absent 
d5 – LV “Relations with financial institutions” U(d5) = {1‒3} (points) reliable, not reliable, absent



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in Fig. 1. The upper figure characterizes the error in the 
functions of the membership of the triangular shape, the 
lower – Gaussian. As you can see, the Gaussian form of 
membership functions allows obtaining much greater 
modelling accuracy for this case.

The overall structure of the hybrid neural network is 
shown in Fig. 2.

The combination of all neural networks in one model 
to determine the value of the index of the intellectual 

component of the energy-saving policy of the enterprise 
has been carried out in the mathematical package 
Simulink for Matlab.

4. Conclusions
The use of the proposed mathematical model will 

allow us to determine the indicator of the intellectual 
component of the energy-saving policy of the industrial 

 
Fig. 1. Graphical results of calculating training error in various forms of membership 
functions

Fig. 2. General view of the structure of the hybrid neural network to determine values of 
the indicator “B”

 
 



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Vol. 4, No. 1, 2018
enterprise, which in turn provides an opportunity to 
select those components of intellectual capital that have 
the greatest influence on the energy-saving policy of the 
enterprise.

If it is necessary, the use of different components of 
intellectual capital, the proposed mathematical model 
will allow ranking their degree of attractiveness for 

energy conservation policies. The expert information 
can be provided by both an expert and a group of 
experts and serves as input information for modelling in 
the proposed mathematical model. Further information 
and practical experience of implementation of energy 
saving measures can be used for training mathematical 
model.

References:
Denisenko, M. P. (2013) Innovative development of society based on intellectual capital. Naukovi zapysky 
Natsionalnoho universytetu «Ostrozka akademiya». Ekonomika (Scientific Notes of the National University of 
Ostroh Academy. Economy), 23, 15-19 (in Ukr.).
Di Stefano, Paul J., Kalbaugh, G. Edward (1999) Intellectual Capital. Rough Notes, 142 (7), 94-95.
Tsipurynda, V. (2013). Factors of formation of intellectual capital. Visnyk KNTEU (Bulletin of KNTEU), 2,  
18-28 (in Ukr.).
Bontis, Nick (1996) There’s a Price On Your Head: Managing Intellectual Capital Strategically. Business Quarterly, 
60 (4), 40-47.
Bassi, Laurie J. (1997) Harnessing the power of intellectual capital. Training & Development, 51 (12), 25-30.
Seid, Mohammad, Reza, Mirahmadia, Ali, Attafara Saideh, Ketabia (2018) Developing a fuzzy ANP model for 
performance appraisal based on firm strategy. Decision Science Letters, 7, 243-256.
Voinarenko, M. P., Dzhedzhula, V. V. & Yepifanova, I. Yu. (2016) Modelling the process of making decisions 
on sources of financing of innovation activity. Ekonomicniy chasopis XXI (Economic Annals-XXI), 160 (7-8),  
126-129 (in Ukr.).
Pankevich, O. D. & Shtovba, S. D. (2005) Diagnosis of cracks in building structures with the help of fuzzy knowledge 
bases. Vinnitsa: UNIVERSUM-Vinnytsya (in Ukr.).
Leonenkov, A. V. (2005) Fuzzy simulation in the MATLAB environment and fuzzyTECH. St. Petersburg. BHV-
Petersburg (in Russ.).