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|title=None
|pdfUrl=https://ceur-ws.org/Vol-2387/20190466.pdf
|volume=Vol-2387
|dblpUrl=https://dblp.org/rec/conf/icteri/ProkopenkoKO19
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https://ceur-ws.org/Vol-2387/20190466.pdf
ICT Support of Higher Education Institutions
Participation in Innovation Networks
Olha Prokopenko1 2 [0000-0003-2519-668X], Olha Kudrina3 4 [0000-0002-7364-1998], Vitaliy
Omelyanenko4 [0000-0003-0713-1444]
1
University of Bielsko-Biala, Willowa str 2, Bielsko-Biała, Poland
2 Center for European Education and Research,
International Humanitarian University, Fontanska Road, 33, Odessa, Ukraine
3 Centre for European Reforms Studies, Luxembourg, F10.340, Grand Duchy of Luxembourg
4 Sumy State Pedagogical University named after A. S. Makarenko, Romeskaia str, 87, Sumy,
40002, Ukraine
omvitaliy@gmail.com
Abstract. This research addresses the issues of information and
communications technologies (ICT) support of participation of Higher
Education Institutions (HEIs) in innovation networks by indicating some
strategies and approaches for ICT infrastructure management. The study is
based on the idea, that the management of the formation and transfer of
intellectual resources becomes the key task of HEIs in the framework of their
new role in development. Based on research results the main directions of ICT-
innovations application for the creation of educational programs based on
unified scientific-educational and innovation processes with application of
interdisciplinary problem-oriented and project-oriented educational
technologies were formulated. Moreover, this paper explores the effects of C-
engineering approach application for multidisciplinary engineering analysis
purposes in S2B-B2S (Science-to-Business – Business-to-Science) cooperation
processes. The main issues and cases of ICT application in HEIs for technology
transfer management thought the creation of smart environment of HEIs
researches programs for business were considered.
Keywords: Digitalization, Technology Transfer, Cooperation, Digital
Education, ICT Support, Innovations, C-engineering, Network
1 Introduction
Innovation networks are an effective mechanism for mutually beneficial interaction
between research and development, start-ups and innovative business, interested in
the practical implementation of their scientific and technological developments and
projects both in their own territory and internationally.
This need is also caused by Industry 4.0 trends [1]. A typical feature of Industry
4.0 solutions is efficiency from interaction. Ability to interact with other participants
of innovation system, to integrate into innovation networks or to adapt the new
�conditions; openness to such interactions becomes important factors of the
competitiveness of any product or business. For this reason, one of the key topics in
the development of Industry 4.0 technologies is the theme of interoperability and
communications standards. Support for a standard makes a product, service or system
open to interactions for other participants.
High and increasing information and communications technologies (ICT)
accessibility necessitates a rethinking of many processes. A wave of breakthrough
innovations not only passes through technological markets, but also destroys many
seemingly formed and predictable industries, including education and science in
education. In this situation, higher education institutions (HEIs) should take
responsibility for the formation of new technologies, both in terms of equipping the
economy with qualified personnel and technological development of industries.
The innovative potential of HEIs is one of the most effective levers in state
innovation policy and one of the most important factors for economic development.
Therefore, at present, in all countries, the search for a new institutional form of
organization of scientific and educational activities is actively carried out, designed to
take on the main burden in personnel and scientific support for the demands of high-
tech sectors of the economy. This, in turn, leads to the search for new approaches not
only to change the paradigm of education, the introduction of experimental methods,
forms and technologies of organizing integrated scientific and educational activities.
Thus, the organizational aspects of implementing of innovation networks principles
through the creation of ICT infrastructure are an important task. The implementation
of ICT is based not only on the operational approach for HEI management as a factor
in modernizing the efficiency of internal communications, but also on trends in the
knowledge economy and the post-industrial economy.
The reports devoted to Industry 4.0 (e.g. [1]) note that development strategies must
be based on a completely new approach to production as a network conglomerate of
major industrialists, experts, economists and academics. Therefore, the question arises
about the development of tools for designing relevant networks that will form
synergies of interaction. This approach is also suitable for open innovation context [2]
and open innovation networks development [3].
This synergy of interaction can be created within the framework of ecosystems of
innovation in relation to interacting groups of actors operating in a single environment
and creating value that none of the companies could produce alone [4; 5]. From the
point of [6], the innovation ecosystem consists of partners, on whom your success
depends in the creation of innovation. And they include both those who are directly
involved in the innovations creation and those who are not directly involved in
creating the product, but are needed for its successful launch (for example, a network
of special gas stations for electric vehicles that you want to produce). Therefore, when
developing an innovation strategy, it is necessary to identify all the interdependencies
and partnerships that are necessary for success, as well as the ways to create these
partnerships. This idea can be successfully applied for HEIs which are innovation
agents with development goals.
In view of above, we can note that the existing innovation infrastructure lacks such
innovation network communication component [7; 8], which would provide not just
�access to supporting information for innovation activity, but would help innovation
actors to enter into network contact with each other, as well as to receive the
necessary information directly from the subjects of innovation and give feedback in
business – education system. Therefore, the development of a model of ICT support
for HEIs based on the network mechanism is a relevant scientific and practical task.
The purpose of this study is to develop a communication model of the university’s
innovation infrastructure in order to improve the efficiency of the innovation ICT
infrastructure through increasing the efficiency of information transfer and network
communication interactions with the business sector.
Formation and transformation of the conceptual model of HEI in the conditions of
Industry 4.0 is proposed to be studied in such aspects: the place of the HEI in the
educational structures and development institutes system; the identification of the
specifics of the HEI's activities in the relationship education – science – practice in
the era of Industry 4.0 and analysis of the value-semantic content of education. The
research is based on the need to develop integrated vocational and education
strategies that reveal the potential of new social role of academic institutions in
modern conditions.
2 ICT Based HEIs R&D Strategies
According to the modern approach, to ensure the competitiveness of educational
services, HEIs should implement appropriate quality assurance procedures, develop
innovation management policies, standards of practice-oriented educational programs,
form and implement a strategy for continually improving the quality of education
through interaction with business and society (demand approach). At the same time,
the management of innovations in modern HEI should include the digitization of the
main directions of its innovation activity.
Digitalization and specialized ICT offer new platforms and applications to interact
and integrate the processes of educational & research and innovation processes, as
well as information technologies for variety of analytics. In addition, domestic and
international R&D cooperation, which has become more effective through modern
communication tools, is crucial for solving complex problems, crisis management,
internal and international security, and much more. In general, innovative
communications, collaboration tools and cloud services create completely new
opportunities for coordinating efforts and overcoming future challenges. So according
to the new role of HEIs, these capabilities are critical.
In this context, it can be accurately asserted that individual ICT solutions, modern
network infrastructure and scalable cloud solutions will play a major role in HEIs
R&D and technology transfer. ICT can be considered as a key for reengineering and
streamlining of educational processes. In this way it will be crucial in future efforts to
modernize of the higher education system, especially the technology transfer
(including social). Thus, the digital transformation of the higher education system is
important to maintain competitiveness in the era of globalization and Industry 4.0.
Therefore, a promising aspect is the analysis of modern ICT components that HEIs
�need to participate in innovation networks in the formation of Industry 4.0. In order to
achieve the goals of university development, it is necessary to analyze the
peculiarities, problems and trends of the global knowledge generation environment in
a post-industrial society, as well as the foreign experience of developing existing
prototypes of ICT-based scientific and innovation networks in order to identify the
possibilities for its adaptation to the conditions of the formation of the national
innovation system.
Creation of information space and relevant communication tools to support S2B-
B2S cooperation activities is one of the urgent tasks solved with the help of a
specialized ICT platform. It is also important to note that the participants in the
innovation network are geographically distant from each other organizations,
including those located in different states. The ICT platform of innovation network
S2B-B2S cooperation is one of the most important tools for the common work of the
system’s participants and should provide the following functions [9]:
informational (databases of technological offers and requests profiles, interface for
remote information management, website);
communication (tools for organizing the tracking of expressions of interest and
correspondence with customers, forum of participants of the system, tools for
collaborative education projects);
reference and training (library of methodical materials, program and regulatory
documents, samples);
monitoring of system (statistical reports on performance indicators).
3 C-technology as Approach for S2B-B2S Cooperation
Networks
C-technology in high-tech industries and S2B-B2S cooperation is based on integrated
product and process development, decision-making technologies and can be
considered at three stages: the formation of specification of requirements, conceptual
design and detailed design. At the first stage, the analysis of initial requirements and
constraints is carried out, an assessment is made of the feasibility of finding a design
solution, at the second – the selection of acceptable (in the context of subsequent
integration) types of design decisions (concepts for implementing the domain model
elements), at the third – the choice of technical solutions.
When using C-engineering in S2B-B2S cooperation digitization, there is a problem
of information exchange between various project participants of innovation network
from HEIs and business (students, researchers, customers, researchers, developers,
manufacturers, operators, etc.). When transferring project data from one ICT
component to another, it takes a lot of work and time to re-encode, which leads to
numerous errors and loss of time. In addition, as the project becomes more complex,
there is a sharp increase in the volume of technical documentation. Traditionally in
the project firms there are considerable difficulties in finding the necessary
information, making changes in the design and technology of manufacturing products.
�There are many errors, the elimination of which takes a lot of time. As a result, the
efficiency of the processes of development, production, operation, maintenance, and
repair of complex high-tech products decreases sharply. There are difficulties in S2B-
B2S cooperation both in the preparation and implementation of innovative projects.
To solve this problem, we propose to consider the technologies of system
information support and maintenance of the product life cycle in the S2B-B2S
network integrated information environment, defined as a set of distributed databases
containing information about products, production environment, resources and
processes. This system should ensure the correctness, relevance, safety and
availability of data to those subjects of production and economic activities involved in
the product life cycle processes that need and be allowed.
For HEI, it is important that the process of creating specifications with information
for software-controlled technological equipment, sufficient for the manufacture of a
product, can be distributed in time and space among many project studios (student
groups, labs, off.).
4 Conclusion
Creation of ICT support of network mechanisms will provide an opportunity to
consolidate information resources of HEIs, innovation centers and integrate them into
innovation networks. As a result, the communication model of innovation
infrastructure will allow to coordinate, regulate and coordinate the activities of
innovative labs, provide consumers with information about the market of scientific
services, the market of innovative products and projects, technical problems of
enterprises, provide authorities with all the information to record and monitor the
results of scientific and innovative activities , to assess the innovation potential of the,
to determine the priority directions of development of science and technology in HEI.
Based on research results the main directions of ICT-innovations application for
the creation of educational programs based on unified scientific-educational and
innovation processes with application of interdisciplinary problem-oriented and
project-oriented educational technologies were formulated. Moreover, this paper
explores the effects of C-engineering approach application for multidisciplinary
engineering analysis purposes in S2B-B2S innovation network cooperation processes.
The results suggest that the creation of network mechanisms based on C-
engineering will provide an opportunity to consolidate the information resources of
HEIs, government agencies, specialized organizations and innovation business centers
in modern innovation projects. The main issues and cases of ICT application in HEIs
for technology transfer management thought the creation of smart environment of
HEIs researches programs for business were considered. Empirically examining of
these cases produced a more complete understanding of HEI ICT-based networked
strategies. The application of ICT in HEI management will contribute to the
emergence of new projects, increase the survival rate of existing R&D projects due to
their expansion through practical testing and implementation, the formation of new
partnerships, start-ups, an increase in the HEI achievements being implemented, the
�use of existing intellectual, industrial and financial potential, close ties between the
scientific community and business.
The given recommendations can be used by policy makers in R&D, managers of
education and/or R&D organizations within the technology transfer strategies and
innovation education technologies implementation projects to improve the interaction
between HEIs and business within the innovation networks.
5 Acknowledgement
The publication was publicly funded by Ministry of Education and Science of
Ukraine for developing of research project № 0117U003855 «Institutional and
technological design of innovation networks for Ukraine national security systemic
providing», research project № 0119U100179 «Development of scientific and
methodological foundations and practical tools for evaluating of the product
innovations commercial (market) prospects» and Project LET EDU 85399 / 17 (Italy).
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