TX_1~AT/TX_2~AT


International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021 1

International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2021, 11(4), 1-6.

The Implementation of Smart Energy into Transformation of 
the Rural Area: The Use of Public Policies for Smart Villages 
Development

Petr Hlavacek1*, Vladimír Skalník2

1Department of Regional Development and Public Administration, Faculty of Social and Economic Studies, Jan Evangelista Purkyně 
University, Pasteurova 1, 400 96 Ústí nad Labem, Czech Republic, 2Innovation Centre of Ústecký Region, Ústí nad Labem, Czech 
Republic. *Email: petr.hlavacek@ujep.cz

Received: 15 February 2021 Accepted: 27 April 2021 DOI: https://doi.org/10.32479/ijeep.11203

ABSTRACT

The article aims to evaluate the government policies in the Czech Republic that have an impact on energy development and energy production 
development in the rural areas, and to propose the areas where smart energy solutions are appropriate for rural communities. The setup of the public 
companies is compared with respect to current trends in the development of Smart Villages, where the smart energy solutions are being developed. The 
research and development conclude that the development policies will require a setup to make the decentralization of the energy sources strengthened. 
As well, to allow more intensive communication and negotiation with local communities. Achieving the synergy effect, while starting up the process 
of use of local energy resources of the location and community energy in transformation of the rural area, should be the goal.

Keywords: Energy Policy, Smart Cities, Smart Villages 
JEL Classifications: Q42, Q48, R11

1. INTRODUCTION

In connection with how quickly new technologies appear in the 
field of energy production, a standalone topic of the use of these 
innovative technologies, or concept, in the rural areas comes to 
the forefront (Holtmeyer et al., 2013; Jenkins et al., 2018). These 
challenges need our intensive focus to strengthen the energy 
independence of the rural areas. According to Clausen and Rudoplh 
(2020), the existence of the best technology will not guarantee its 
use, which, rather likely with respect to the lagging of the rural 
areas, behind the development of urban regions, in the field of 
the energy. On top of that, the lower density of the population of 
rural areas makes unit costs for provision of available energies to 
inhabitants of the rural areas higher. The disadvantage of the areas 
is that they lack political power and the agglomeration benefits of 
the urban regions (O’Sullivan et al., 2020; Klaniecki et al., 2020). 

Abbas et al. (2020) point out the risk of growing energy poverty 
being associated in particular with peripheral rural areas.

Not only the availability of the energy sources, but also the setup of 
the energy policy and other policies, which deal with the rural area 
development with respect to availability and use of the energies 
to a certain level, influences the development of the rural regions 
in the field of energy.

To that end, the article evaluates the current setup of the public 
policies, what targets have been defined for development of smart 
energy, and for the use of the energy sources in the rural areas 
in association to the support for implementation of the smart 
solutions there. Upon evaluation of the government policies, the 
article will define the field for implementation of smart energy to 
the development of the rural areas, and directions for establishing 

This Journal is licensed under a Creative Commons Attribution 4.0 International License



Hlavacek and Skalník: The Implementation of Smart Energy into Transformation of the Rural Area: The Use of Public Policies for Smart Villages Development

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 20212

a new energy transformation policy for the rural areas for the 
development of the smart rural areas.

2. LITERATURE REVIEW

According to OECD, the rural and interjacent areas (OECD, 
2016) occupy 88.2% of the territory of the European Union 
(Eurostat, 2016), and they include most of its natural resources. 
Many European villages, including those in the Czech Republic, 
have already been using the potential for making the projects 
focused on energy saving happen with the emphasis on the use 
of the renewable energy sources. An example of such a functional 
design is the energy communities in some European states where 
there is an environmental law, which is much more favourable for 
the individual and decentralized production of energy (ENRD, 
2018). The local system outside the grids then complements those 
centralized ones (Groth, 2020). It is inevitable for the rural areas 
to avoid the import of knowledge and capital necessary for the 
introduction and use of innovative and smart solutions in energy 
in the future. However, Benedek et al., (2018) draw attention that 
the use of the renewable energy will require good predictions of 
the capacities of the local energy sources.

In conformity with the policy of the European Union in the 
field of climate and energy, the Czech Republic prepares for 
the transposition of the laws from the “Clean Energy for All 
Europeans” package into the Czech laws. By 2050, the European 
Union intends to be a climate-neutral area. The European 
Commission implements initiatives at the EU level that deal 
with the challenges of towns and municipalities in the field 
of energy. One of these initiatives is the European innovation 
partnership, the Initiative for Smart Cities and Communities. It is 
a partnership across the areas of energy, transport and information 
and communication with the objective to catalyse progress in the 
said areas. Energy production, distribution and use, mobility and 
transport, and information and communication technologies (ICT) 
are intimately lined and offer new interdisciplinary opportunities 
to improve services while reducing energy consumption (European 
Commission, 2012).

The change to shift to low-carbon and a sustainable economy will 
require a huge effort, investments, and interdisciplinary approach. 
The development and use of modern energy systems, technologies, 
and infrastructure needed are the fundamental requirements for 
achieving the change (Naumann and Rudolph, 2020). There has 
already been a start with the implementation effort of the European 
laws in the Czech Republic in the field of energy represented 
in particular by the Directive (EU) 2018/2001 of the European 
Parliament and of the Council on the promotion of the use of 
energy from renewable sources, directive (EU) 2018/2002 of the 
European Parliament and of the Council on energy efficiency, 
and directive (EU) 2018/844 of the European Parliament and of 
the Council on the energy performance of buildings, i.e., with 
respect to energy transformation processes and renewable energy 
sources (RES) development. The Rural Area Development Draft 
of the Ministry of Regional Development of the Czech Republic 
deals with the field of the rural area development. The draft aims 
to support the rural area development by a more intensive use of 

the local energy sources (Ministry of Regional Development of 
the Czech Republic, 2019). It would be therefore necessary to 
implement the activities related to smart energy so that the rural 
areas have created a quality infrastructure (energy, transport, 
and technical), powerful, stable, and diversified economy, as 
well as a healthy and climate stable environment. According 
to Mekhdiev et al., (2018), the governments should focus on 
increasing the energy consumer’s satisfaction level regarding 
quality and energy supply costs with good support from the 
decentralization of its production. Despite increasing energy 
savings, the consumption and demand for energies will continue 
to grow. Involvement of the government programs, regional, 
and local governments will be required to secure the new energy 
sources where there is just room for support of implementing the 
smart solutions. However, the use of the public support should 
be linked to collective bargaining about future forms of energy 
production and distribution. According to Berka and Creamer 
(2018), these factors will play a key role in the transformation 
processes, towards increased energy production at the local level, 
i.e., in the rural communities as well.

3. METHODS

The article is structured into a couple of related chapters that 
conform to the phases of the methodology of the research. 
First, collection of information was made on current needs for 
development of the communities, and the description of expert 
publications. The next phase mapped out legal and planning 
dimensions, and analysis of policies of the Czech ministries 
focused on the field of energy with impact on the rural areas. Then, 
the Smart City concept analysis followed, including identification 
of the main directions of the smart energy development for the 
rural areas. The analytical part of the present article is topped 
up by the specification of smart solution for rural areas with an 
emphasis on endogenous energy sources, including findings and 
recommendations for the smart energy development in the rural 
areas.

The descriptive analysis in scripted documents, public policies, 
methodologies, and expert bibliography study will be used in the 
research. The good practice method (Stockley, 2012) is being 
applied for the searching and mapping of the smart solutions in 
the field of energy in the rural areas. The good practice method 
has been developed in the field of management from where it 
expanded to other areas. The method aims at the mapping of 
solutions employed as model examples and uses them for the 
solution of other problems or development goals.

4. RESULTS AND DISCUSION

A couple of planning and strategic documents indicate the 
development in the field of energy in the Czech Republic – 
National Action Plan of Energy Efficiency of the Czech Republic, 
National Action Plan for Smart Networks, National Action Plan 
for Renewable Energy Sources 2010-2020 for the Czech Republic, 
State Energy Concept of the Czech Republic, and the Strategy for 
Regional Development of the Czech Republic 2021+. The analysis 



Hlavacek and Skalník: The Implementation of Smart Energy into Transformation of the Rural Area: The Use of Public Policies for Smart Villages Development

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021 3

of the disciplinary policies of the ministries showed that they define 
the development goals in the field of energy impacted also by the 
rural areas in many of their own disciplinary policies. The Ministry 
of Industry and Trade of the Czech Republic, being responsible for 
agenda in the field of the energy and energy policy of the Czech 
Republic, is the main entity responsible in the Czech Republic for 
energy development, also in the rural areas. Not only, this ministry 
also deals with the themes of energy and transformation of energy 
sources, including the consequences of the transformation. The 
analysis of the policies of other ministries revealed that other goals 
of the individual programs may be found in the impact on the field 
of the energy production and energy also in the rural areas. For 
the summary of evaluation of individual goals of the government 
programs and policies, refer to Table 1.

In addition to the above-mentioned goals of government policies, 
the need to develop smart energy networks is also mentioned, 

which is associated with the expectation of achieving greater 
efficiency of energy networks, but creating greater independence 
in deciding how to meet the energy needs of the rural areas. 
Hence, measures such as energy distribution, production, and 
accumulation based on the principle of smart network and smart 
instrumentation, including the support for the development of 
distributed and centralized energy accumulation systems should 
be adopted. At the same time, the new infrastructure should also 
expand the options for customer consumption management at the 
level of low voltage as a part of the smart network systems. The 
development of smart energy aimed at achieving carbon neutrality 
by 2050 brings about a lot of new challenges and opportunities. 
From the energy sources perspective, the priority is logically put 
on the maximum use of the RES. However, the use of secondary 
energy sources, as well as the use of waste, must not stay aside as 
they are the representatives of typical examples of linear economy 
transformation into the circular one. The sources may be called 
modern or innovative energy sources.

4.1. From Smart Cities to Smart Villages
Recently, the Smart Cities concept has been penetrating, over the 
last years, in the development of the energy policies at the regional 
level, which is based on the principles of sustainable development 
and the organization of cities with the use of smart technologies in 
the field of energy as well. An important concept document from 
the Ministry of Regional Development of the Czech Republic is 
the Smart Cities Methodology (Ministry of Regional Development, 
2018) that considers smart energy, sources, and services as the 
main areas of the Smart Cities’ technological infrastructure. Smart 
energy includes the following areas:
•	 Smart energy consumption control, including energy 

management of municipal buildings and support of their 
energy-saving solutions

•	 Use of RES or combined electricity and heat production, and 
their safe integration into the municipal energy grid

•	 Use of the “smart grid” elements in the municipal or regional 
distribution grid, including smart micro-grids

•	 Smart control of municipal services towards effective use of 
energy and natural resources – in particular, energy-saving and 
environmentally-concerned public lighting, effective waste 
management, and effective water management (Ministry of 
Regional Development of the Czech Republic, 2018).

The development of the rural areas’ development policy is 
inevitable without the development of smart energy in the rural 
areas. Smart rural areas are the rural areas and communities that 
build on their advantages and values to date, as well as on new 
opportunities in their effort to achieving increased value where 
both traditional and new grids are upgraded through digital 
communication technologies, innovation, and improved use of 
knowledge in favour of inhabitants (ENRD, 2018). A synonym 
for the power development could to some extent be the Energy 
4.0 concept (the Ústí Region, 2020). From the perspective of this 
energy, it is a portion of the energy eco-system integrating the 
ICT elements, in particular smart production, distribution, and 
energy consumption management in real time, which supports the 
distributed production from renewable sources of energy.

Table 1: Evaluation of policy goals of the Czech ministries 
with an impact on energy transformation of the rural 
areas
Ministry in the 
Czech Republic

Goals of the policy

Ministry of Industry 
and Trade

- To implement energy-saving measures
-  To increase efficiency in use of energy, 

and reduce energy demands
-  To process design and territorial 

documentation to support energy saving
-  To make loans intended for reduction of 

energy demand more favourable in order 
to achieve energy saving

Ministry of 
Agriculture

- To support biomass use as RES

Ministry of Regional 
Development

-  To permit energy transformation of the 
rural areas background of the regional 
centres

-  To ensure effective prevention of social 
exclusion and energy poverty, and 
to support the community life in the 
communities

-  To improve air quality in the 
communities where the emission limits 
are exceeded (replacement of local 
air-polluting energy sources)

- To develop new energy repositories
-  To develop net energy sources extracting 

energy from RES
-  To modify the transmission and 

distribution grid in order to make the 
connection of a new RES possible

-  To use smart solutions in urban and rural 
areas

Ministry of Interior -  To repair or maintain properties of the 
communities, in particular, in the field of 
transport and energy

Ministry of 
Environment

-  To reduce energy demand of the existing 
blocks of flats

-  To fund the construction of the blocks of 
flats of very low energy demand

- To effectively use the energy sources
- To use heat from waste water

Ministry of Education, 
Youth and Sports 

-  Use examples of energy saving solutions 
and environmental measures to educate

Source: Own processing



Hlavacek and Skalník: The Implementation of Smart Energy into Transformation of the Rural Area: The Use of Public Policies for Smart Villages Development

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 20214

Based on the targets and policies specified above, which directly 
or indirectly coordinate the energy development at the level of 
regions and municipalities as well, the basic smart solutions may 
be defined as the upcoming vision of the rural areas as being the 
territory attractive for true living. The effective use of the smart 
systems for the operation of the community and communication 
with inhabitants is important for the rural area in the field of energy. 
It is necessary to evaluate the level of self-sufficiency of the rural 
areas in the energy production for the system development of smart 
rural areas and their energy sources, and to transform the energy 
sources into low-carbon economy. With the change processes 
being set, differences of individual rural areas and endogenous 
principles must be considered in creating the local energy policies 
in the rural communities.

The energy self-sufficiency of a municipality may be the potential 
goal of the smart solutions in the field of smart energy (Figure 1). 
An energy self-sufficient municipality is not an isolated entity, it 
remains integrated with the other communities and territories in 
a communal way. It is able to procure all the needs, or its energy 
consumption right in the community. The essence is a principle that 
consumption and production occurs at one place with an effort to 
cover the consumption as most as possible from its own sources, 
which widely opens doors to modern technologies. In no way is the 
essence of the energy self-sufficiency separated from the central 
power supply systems, but rather to use as most as possible the 
local available potential, which also improves the resilience of the 
community and provides extended safety. The smart solution in 
the power field and energy production in the rural areas should be 
applied in the fields described in Table 2. The self-sufficiency level 
is given by a specific layout of the community or territories to a 
high extent. Therefore, the definition of the territorial potential and 
possibilities of its technical and economical use are the keys for the 
rural area’s development. An energy self-sufficient municipality 
consists of a community being able to sustain its needs, i.e., local 
consumption through energy production on spot. It does not mean 
that it is isolated from the central power supply but local energy 
sources will be used as much as possible.

The smart energy consists in diminishing fossil fuels and the 
development of low-carbon economy also in the rural areas, for 
example by the use of RES (solar and wind energy, biomass and 
bio-gas for electricity production, reduction of energy demand, 
and more) at higher levels and in overall energy management.

The ability of the community’s policy to communicate with a 
wider area, to advance in a horizontal approach in the creation 
of a symbiotic relationships with other communities, and in a 
vertical approach in the development of energy; this will play 
an irreplaceable role by the integration of the rural communities 
and locations with the regional centres at a higher level. To 
achieve an acceptable level of resilience and self-sufficiency 
of the rural areas, it is necessary to deliver relevant technical 
infrastructure (local distribution systems with the elements of 
smart grids).

Figure 1: Basic representation of smart village

Source: Antoine-Santoni et al., (2019)

Table 2: Areas for implementation of the smart solutions 
in the rural areas
Energy grids

Reconstruction of distribution grids for connection of new sources 
of electricity, or RES
Development of transmission and distribution system and energy 
repositories
Building of infrastructure for island systems for energy supply

Energy production
Reduction of energy demands
Use of alternate sources of energy, e.g., in bio-gas stations
Use of RES
Support of new local (innovative) sources of energy
Support of effective use of energy sources and switching to 
low-carbon rural economy
De-concentrated energy systems

Socioeconomic area
Reinforcement of the circular economy in the field of the energy 
production
Development of low-carbon economy
Reduced risk of energy poverty
Support of local energy producers

Source: own processing



Hlavacek and Skalník: The Implementation of Smart Energy into Transformation of the Rural Area: The Use of Public Policies for Smart Villages Development

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 2021 5

Should there be an insufficiency of individual energy sources, the 
smart energy solution should perform the control and coordination 
activity between both systems so that community inhabitants 
notice no inferior quality of supply or outages. In addition, a lot 
of smart solutions are related to Internet and electricity, and thus 
it is necessary to eliminate potential outages as a prevention so 
that purely technological smart solutions will be able to operate 
in a continuous way.

Consolidation of diversification of the source base and tight 
cooperation with the surrounding communities and regional 
centres under clearly defined rules and correct management will 
allow the reduction of the operation expenses, and provide higher 
stability of the environment and resiliency of the rural areas against 
extreme situations. According to Vallivaara (2017), the Artic 
Smart Community Cluster project may be an example where the 
community in cooperation with various organizations, including 
companies, funding institutions, researchers, and mediators 
harnessed the potential for capital outflow and increasing the 
local quality of services in two key areas – energy and food sale. 
The cluster participants have developed an integrated strategy to 
support local business operators, which includes education through 
schools, making public tenders accessible, and establishing local 
food and energy hubs. It has been confirmed that the implemented 
projects create new jobs, reduce waste and emissions, control 
costs, and keep local income in the local economy (ENRD, 2018).

5. DISCUSSION AND CONCLUSION

In essence, smart energy in the rural areas is not limited to the 
size of the area, and it belongs among the fundamental pillars of 
the smart development concept of the rural areas. The object is 
that it may be generally considered as a part of everyday life of 
all inhabitants, and it does not matter whether it is applied in a 
metropolis or in a rural community. It includes a set of systems 
and activities that a modern society may not simply operate. 
What distinguishes smart energy from a “traditional” perception 
of the energy is the achieved level of energy efficiency of all 
systems being used, the level of RES, its availability (limitation 
of the energy poverty), and the resilience level towards changes 
to conditions.

The energy self-sufficiency of a community and the development 
of community energy is an apposite result, however, the central 
energy systems should remain as a backup, or add-on, because 
energy self-sufficiency is the first aspect and provision of 
individual services in the community, so that inhabitants will 
live well and better in the future, as this is the other aspect. In 
reality, perhaps only a few communities would be capable of 
securing the services using its own sources at a level available 
from the central system, and therefore, each system needs to be 
interconnected. For pushing smart energy through, a properly 
configured energy policy is absolutely fundamental – to ensure 
the conditions for a long-term sustainable development and 
decentralization of the energy sources (Yazdanie et al., 2016). 
The policy should be characterized by achieving the synergy in 
the integration of the energy and information and communication 
technologies (ICT).

For rural communities, it is better that the energy challenge 
(and therefore, the energy self-sufficiency) is discussed at the 
level of locations and not by way of individual communities, 
and hence, to support so-called community energy. The energy 
associations being formed by the communities, and therefore by 
inhabitants, show growing importance, and the energy policy 
should aim toward more intense communication and negotiation 
with the local communities. It would be ideal in each case, that all 
directions described for the new solutions in the field of the energy 
development of the rural areas are supported by the government 
policy by the system of subsidies and invitations to help in the 
transformation of the energy sources and higher independence of 
the rural communities.

The next steps in the research could focus on mapping out the 
efficiency of the government programs and looking for successful 
projects of the community energy development in the rural areas. 
The above mentioned is associated with the need of looking for 
examples of an effective energy transformation of the rural regions. 
The knowledge gained about the transformation processes could 
be the examples and they may be universally portable to other 
rural areas.

6. ACKNOWLEDGMENT

The paper presents the results of the research within the TACR 
project No. TL03000066, “Smart countryside: sustainable rural 
development using Smart solutions.”

REFERENCES

Abbas, K., Li, S., Xu, D., Baz, K., Rakhmetova, A. (2020), Do 
socioeconomic factors determine household multidimensional energy 
poverty? Empirical evidence from South Asia. Energy Policy, 146, 
111754.

Antoine-Santoni, T., Poggi, B., Federici, D. Manicacci, F.M., 
Gualtieri, J.S., Aiello, A. (2019), Proposition of a Smart Environment 
Architecture for Ressources Monitoring and Rural Activities 
Management. The 13th International Conference on Sensor 
Technologies and Application, Conference Paper IARIA. p62-68.

Benedek, J., Sebestyén, T., Bartók, B. (2018), Evaluation of renewable 
energy sources in peripheral areas and renewable energy-based 
rural development. Renewable and Sustainable Energy Reviews, 
90, 516-535.

Berka, A.L., Creamer, E. (2018), Taking stock of the local impacts of 
community owned renewable energy: A review and research agenda. 
Renewable and Sustainable Energy Reviews, 82, 3400-3419.

Clausen, L.T., Rudolph, D. (2020), Renewable energy for sustainable 
rural development: Synergies and mismatches. Energy Policy, 138, 
111289.

ENRD. (2018), EU Rural Review 26 Smart Villages: Revitalising 
Rural Services. Available from: https://www.enrd.ec.europa.eu/
publications/eu-rural-review-26-smart-villages-revitalising-rural-
services_en. [Last accessed on 2021 Jan 21].

European Commission. (2012), Sdělení Komise Inteligentní Města a 
Obce evropské Inovační Partnerství. Available from: https://www.
ec.europa.eu/info/eu-regional-and-urban-development/topics/cities-
and-urban-development/city-initiatives_cs. [Last accessed on 2021 
Jan 19].

Eurostat. (2016), Share of Land Area Using Different Typologies. Available 



Hlavacek and Skalník: The Implementation of Smart Energy into Transformation of the Rural Area: The Use of Public Policies for Smart Villages Development

International Journal of Energy Economics and Policy | Vol 11 • Issue 4 • 20216

from: https://www.ec.europa.eu/eurostat/statistics-explained/index.
php?title=File:Share_of_land_area_using_different_typologies_
(%25_of_land_area)_update.png. [Last accessed on 2021 Jan 21].

Groth, A. (2020), Overcoming one-way impact evaluation of rural 
electrification projects. International Journal of Energy Economics 
and Policy, 10(2), 464-476.

Holtmeyer, M.L., Wang, S., Axelbaum, R.L. (2013), Considerations for 
decision-making on distributed power generation in rural areas. 
Energy Policy, 63, 708-715.

Jenkins, K., Sovacool, B.K., McCauley, D. (2018), Humanizing 
sociotechnical transitions through energy justice: An ethical 
framework for global transformative change. Energy Policy, 117, 
66-74.

Klaniecki, K., Duse, I.A., Lutz, L.M., Leventon, J., Abson, D.J. (2020), 
Applying the energy cultures framework to understand energy 
systems in the context of rural sustainability transformation. Energy 
Policy, 137, 111092.

Ministerstvo Pro Místní Rozvoj ČR. (2018), Metodika Smart Cities. 
Available from: https://www.mmr.cz/getmedia/f76636e0-88ad-
40f9-8e27-cbb774ea7caf/Metodika_Smart_Cities.pdf.aspx?ext=.
pdf. [Last accessed on 2021 Jan 15].

Mekhdiev, E.T., Prokhorova, V.V., Makar, S.V., Salikhov, G.G., & 
Bondarenko, A.V. (2018). Smart Cities in Future Energy System 
Architecture. International Journal of Energy Economics and Policy, 
8(5), 259-266.

Ministerstvo Pro Místní Rozvoj ČR. (2019), Koncepce Rozvoje Venkova. 
Available from; https://www.mmr.cz/getmedia/279d5264-6e9e-
4f80-ba4a-c15a26144cd0/Koncepce-rozvoje-venkova_202001.pdf.
aspx?ext=.pdf. [Last accessed on 2021 Jan 15].

Ministry of Regional Development of the Czech Republic (2018). 
Metodika Smart Cities. Available from; https://mmr.cz/getmedia/
f76636e0-88ad-40f9-8e27-cbb774ea7caf/Metodika_Smart_Cities.
pdf.aspx?ext=.pdf.

Naumann, M., Rudolph, D. (2020), Introduction to the special section: 
Rural energy transitions - Contestations and perspectives. Energy 
Policy, 142, 111531.

O’Sullivan, K., Golubchikov, O., Mehmood, A. (2020), Uneven energy 
transitions: Understanding continued energy peripheralization in 
rural communities. Energy Policy, 138, 111288.

OECD. (2016), OECD Regional Outlook 2016: Productive Regions for 
Inclusive Societies. Available from: https://www.regions20.org/wp-
content/uploads/2016/08/OECD-Regional-Outlook-2016.pdf. [Last 
accessed on 2021 Jan 10].

Stockley, D. (2012), The Rise and Fall of the Best Practice Method. 
Available from: http://www.derekstockley.com.au/newsletters-
05/042-best-practice-consulting.html.

Ustecky Region. (2020), Energetika 4.0. Available from: https://
w w w. k r- u s t e c k y. c z / a s s e t s / F i l e . a s h x ? i d _ o rg = 4 5 0 0 1 8 & i d _
dokumenty=1748688. [Last accessed on 2021 Jan 21].

Vallivaara, J. (2017), Implementation of Smart Specialisation Arctics 
Smart Rural Community. Available from: https://www.enrd.
ec.europa.eu/sites/enrd/files/s4_rural-businesses_aritc-cluster_
havukainen.pdf. [Last accessed on 2021 Jan 15].

Yazdanie, M., Densing, M., Wokaun, A. (2016), The role of decentralized 
generation and storage technologies in future energy systems 
planning for a rural agglomeration in Switzerland. Energy Policy, 
96, 432-445.