=Paper=
{{Paper
|id=Vol-2254/invited-1
|storemode=property
|title=Key
information technologies for digital economy
|pdfUrl=https://ceur-ws.org/Vol-2254/invited-1.pdf
|volume=Vol-2254
|authors=Nafisa Yusupova,Konstantin Mironov
}}
==Key
information technologies for digital economy==
https://ceur-ws.org/Vol-2254/invited-1.pdf
Key information technologies for digital economy
Nafisa Yusupova and Konstantin Mironov
Faculty of Computer Science and Robotics
Ufa State Aviation Technical University, Ufa, Russia
yussupova@ugatu.ac.ru, mironovconst@gmail.com
Abstract
The paper is dedicated to the key information technologies, which are
important for the economic progress of various countries. Common
properties of the IT sphere are discussed. Examples of research work
at Ufa State Aviation Technical University are given for the topics of
Big Data, Artificial Intelligence, Robotics and Sensorics.
1 Introduction
The role of information technologies (IT) in different areas become increasingly significant. They have be-
come important factor of progress for developed and developing countries, which ensures a stable high rate of
development and the effectiveness of integration into the global space. In European Union the list of main im-
plementation steps towards the creation of a single digital market was published in May 2016 [EU16]. In Russia,
the program for the development of digital economy [PDE17] was approved in May 2017. Updating cycle of the
IT has a direct impact on all other industries. Not only scientists, but also practitioners, managers, etc., are
engaged in the research, development, application and implementation of IT in various types of activity. This
article focuses on issues related to key information technologies. The second section discusses the characteristics
of the IT industry and key IT, which provide the development of the digital economy. In the third section, some
relevant scientific results by authors from the Ufa scientific school are given.
2 The field of information technology
The activity in the sphere of IT include IT services, software development, and equipment supply and mainte-
nance[APC18]. IT services include systems integration and implementation, customized application development,
outsourcing and offshoring, support, maintenance, consulting, training and education. Software development in-
clude infrastructure applications, solutions for decision support, user applications, business software, consumer
software, embedded software. Equipment supply sphere is related to the supply of PCs, servers, peripherals,
external devices, equipment for data storage. The IT industry also includes such sectors as sales of telecommu-
nications equipment, e-commerce enterprises for the mass market and for corporate clients, and Internet-based
media resources [APC18]. Globally IT services occupy a larger market share than the software sector, but their
growth is already stabilized. In the field of software development, emerging markets start to play more important
role due to rapid economic development and decreasing level of piracy. Equipment supplies has a small share
of costs in developed countries, and a large part in developing ones. The global IT industry retains great long-
term growth potential. The most demanded IT-specializations in Russia are 1C programmers and developers,
Copyright c by the paper’s authors. Copying permitted for private and academic purposes.
In: Marco Schaerf, Massimo Mecella, Drozdova Viktoria Igorevna, Kalmykov Igor Anatolievich (eds.): Proceedings of REMS 2018
– Russian Federation & Europe Multidisciplinary Symposium on Computer Science and ICT, Stavropol – Dombay, Russia, 15–20
October 2018, published at http://ceur-ws.org
�system administrators, maintenance specialists, java programmers and developers, web-programmers, testers,
PhP-programmers, deployment specialists, web-designers, technical writers.
Regional issues of IT-development mostly coincide with issues at the federal level. In particular, these are in-
sufficient financing, personnel shortage, inconsistency of actions between different levels of government. However,
there are some peculiarities in the regions, e.g., a weak development of the information and telecommunication
infrastructure. Another problem is that in Russia in recent years no significant bank of solutions or services has
been established at the federal level, which regions can use together and at no additional charge; in fact, every
region is seeking funds for the same solutions.
Nine key IT for the development of digital economy are stated in [PDE17]. They are listed in table 1.
Table 1: Key IT for the development of digital economy
Technology Description Applications
Big Data Processing large amounts of data (large in comparison with medical and socio-
standard scenarios); work with fast stream of these data; par- economical data
allelized work with unstructured and weak-structured data. analysis, GIS, etc.
Neurotechnology Artificial intelligence (including artificial neural networks) is medicine; unmanned
and Artificial a technology for creating intelligent machines or programs, vehicles; management
Intelligence which are capable to model human intelligence for implement- of human resources,
ing complicated task, such as natural language text processors, industry; finance;
expert systems, virtual agents, recommendation systems, etc. household robots,
smart buildings, etc.
Distributed Distributed ledger is a database that is stored and updated banking, finances, en-
Ledger Systems independently by each node of the network. The most well- ergy systems, etc.
known type of distributed ledger is blockchain. Security of the
stored data is provided by specific use of cryptographic hash
functions and digital signatures.
Quantum Tech- Manipulation of complex quantum systems at the level of their cryptography, ar-
nologies individual components in order to create powerful and secure tificial intelligence,
quantum computing system. molecular modeling,
etc.
New Industrial Automation and robotization, integration of IT systems, sim- Industrial production
Technologies ulation and modeling, additive manufacturing, alternative en-
ergy, industrial big data and analytics, development of cyber-
physical systems and ”Industry 4.0” concept.
Industrial Inter- Subcategory of the Internet of Things; a concept for build- System integration,
net ing information and communication infrastructures: connect- IT services; transport
ing any non-residential devices, equipment, sensors, control systems, telemetry,
systems to the Internet and integrating the elements among geolocation, etc.
themselves.
Components of Robotic components intensify industrial production. sensors Robotized production
Robotics and in robotics act as receptors through which robots receive in-
Sensorics formation from the outside world and their internal organs.
Wireless Com- Transferring information between points without wired com- Industrial Internet, In-
munication munication ternet of Things, com-
Technologies munication systems
Virtual and Virtual reality is a concept of expanding the physical space informational and
Augmented of human life with objects created with digital devices and educational products;
Reality programs and having the character of an image. Augmented games; product devel-
reality allows placing visualized information around the ob- opment; presentation
jects of the real world. and demonstration
�3 Research in Ufa: current results and next steps
The scientists from the Faculty of Computer Science and Robotics at Ufa State Aviation Technical University
made significant work in the field of fundamental research and in the field of practical research (in collaboration
with customers from the real sector of the economy). Several tens of examples of research projects connected to
key IT may be given. However, due to the limited scope of this article, we will focus only on some results in the
field of big data, artificial intelligence, robotics, and sensorics.
Big data analysis in Geo-technologies are now at thbeing developed at the Department of Geo-Information
Systems (Prof. O. Christodoulo). Geo-information systems (GIS) are becoming one of the main technologies for
analyzing big data for many applications, such as production management, transport, energy, security, etc. Geo-
data are complex, and with the transition to big geo-data complexity increases almost exponentially. It means
processing billions of geographic objects, (lines and polygons). In addition, the calculation of spatial relationships
is often required. Applying technologies like Hadoop to them could help to solve problems that cannot be solved
by traditional methods, or, at least, to get a significant gain in efficiency and speed of computations. The following
research works in processing big geo-data were conducted: development of GIS of trunk oil pipelines and 3D
models of potentially hazardous objects for OJSC ”Uralsibnefteprovod”, development of an automated system
for the formation and maintenance of a regional waste cadastre in the Republic of Bashkortostan, development
and implementation of the GIS for OJSC ”Gaz-Service”, development of the GIS for governing organizations in
the Republic of Bashkortostan, modeling the flood zones during the period of spring floods in the Republic of
Bashkortostan [Chr13].
Research work on BigData at the Department of Computing Technology and Information Security is made
together with Frodex LLC on the research topic: Intelligent analysis of banking transaction data as part of a
antifraud system [Sap17] (Prof. V. Vasilyev). Within the framework of the project, the system for collecting
and processing user data was developed as part of the antifraud system. The key element of this system is the
data mining module. Analysis algorithms are applicable in the conditions of big data. Hadoop hardware and
software cluster is deployed. It consist of 16 server machines that implements the capabilities of a distributed
transaction banking data processing system based on modern distributed file system technologies, non-relational
DBMS (Cassandra), big data processing technologies (Apache Spark,TensorFlow, Spark-sklearn).
Research on medical applications of Big Data are mainly conducted at the Department of Computational
Mathematics and Cybernetics (Prof. N. Yusupova, Prof. G. Shakhmametova). The most relevant direction of
work is data processing for diagnosis, treatment and prevention of diseases. Taking into account high volume
of input information or implementing a complex data processing algorithm may be really difficult for a decision
maker. Relevance of this task increases with the accumulation of information, which is happening avalanche-like
due to the improvement of information collection and storage technologies. Tasks of medical analytics solved
via BigData technology may be divided into descriptive analytics (What happened?), diagnostic analytics (Why
did it happen?), predictive analytics (What will happen?), and preventive analytics (What should be done in
order NOT to happen?). Medical data are obtained from various sources:results of research and testing; medical
records and diagnoses; medical meters; analytical information from medical authorities and pharmacies.
In collaboration with the Department of Internal Medicine Propsy at the Bashkir State Medical University
(Prof. R. Zulkarneev) a technique for complex analysis of toxicologic data was developed and implemented
[Sha18]. This technique includes three main stages: exploratory data analysis using visual analysits, non-
parametric analysis, data mining. The developed technique is applied to the analysis of data on acute poisoning
in the Republic of Bashkortostan in 2015-2016. The results obtained during the analysis can assist the managers
of medical institutions and chief specialists of the governing bodies in analyzing the indicators characterizing
the dynamics of trends in public health, planning the allocation of health care resources in the region, and
managing specialized medical services. Additionally software complex for non-parametric medical data analysis
methods was developed. Future plans include descriptive and diagnostic analytics of medical data; study of the
effectiveness o f treatment based on analysis of medical records and diagnoses; expense forecasting based on the
analysis of data such as the number of repeated visits, the prevalence of pathologies, the number of patients with
chronic diseases, etc.
Intelligent analysis of big social and economic data is also performed at the Department of Computational
Mathematics and Cybernetics (Prof. N. Yusupova, Prof. O. Smetanina). Solutions are based on text analysis,
pattern recognition, machine learning [Guz14, Yus18]. Main instruments are data quality assessment, factor
analysis, dimensionality reduction, cluster analysis. One example task is odentification of similar educational
programs in different countries with preliminary processing of semi-structured and structured data. Another
�one is identification of hidden patterns in personal data, including the data from Internet-resources. Results are
used for the selection of job-applicants, for assessing the loyalty of customers (including students as customers
of educational services), for assessing the correct choice of a professional path, etc. Analysis of natural language
text was applied for review-based decision making. Pattern recognition as a mix of classification and identifica
tion methods was applied for person recognition based on voice and images.
Research in the sphere of intelligent robotics and sensorics is conducted at the Department of Computer
Technology and Information Security (Dr. Konstantin Mironov). This work is dedicated to the task of object
transportation by robotic throwing and catching [Gay17]. This is a novel possible way of material transportation,
which may replace traditional conveyor belts for transporting small objects in the industrial environment. Catch-
ing is based on tracking and forecasting the trajectory of the thrown object. Proposed tracking system is based
on stereo vision. Novel approach to forecasting the trajectory of the thrown body was proposed. Traditional
approach to this task consist in mathematical modeling of the ballistic trajectory. Learning-based approach
is less popular. Proposed predictor was applied based on nearest neighbor regression, which does not require
exact physical model of the motion. These two approaches were then mixed in the new one, which is based on
genetic programmi ng. The forecast is made using an equation, which is learned by the procedure of genetic
programming. Results of numerical and throwing experiments showed that accuracy of trajectory forecasting is
enough for successful robotic catching.
4 Conclusion
Global IT industry has great growth potential in the long term with a tendency to increase the share of IT
services in comparison with software and hardware. The key information technologies of the digital economy
include: big data, neurotechnologies and artificial intelligence, distributed ledger systems, quantum technologies,
new production technologies, industrial Internet, components of robotics and sensorics, wireless communica-
tion technologies, virtual and augmented reality. Research experience at the Faculty of Computer Science and
Robotics (USATU) has a direct relationship to the key areas of information technology, named in official doc-
uments. Further research is related to both fundamental problems and the application of results for real-world
problems.
References
[AEC18] Association of Enterprises on Computer and Information Technologies Web Resource. www.apkit.ru
(vizited on 31.05.2018, in Russian)
[Chr13] S. V. Pavlov, O. I. Christodulo Theorethical Methods for the Developing Geo-Information Systems based
on Integration of Multidimensional Data Models and Geo-information Technologies. Geo-information
technologies in development of corporate information systems, Ufa, 2013, pp. 40 to 46 (in Russian).
[EU16] European Commission sets out path to digitize European Industry. Press Release, Brussels, 2016.
[Gay17] R. C. Gayanov, K. V. Mironov, D. V. Kurennov Estimating the Trajectory of a Thrown Object from
Video Signal with use of Genetic Programming. 2017 IEEE Symposium on Signal Processing and
Information Technology, Bilbao, Spain, pp. 134 to 138.
[Guz14] M. B. Guzairov, N. I. Yusupova, O. N. Smetanina et. al Methodological Aspects of Artificial Intelligence.
Machinery Science, Moscow, 2014, 267 pp.
[PDE17] Program Digital Economy of Russian Federation. Order of the Russian Government #1632-p from
28.07.2017 (in Russian)
[Sap17] M. U. Sapozhnikova, A. V. Nikonov, A. M. Vulfin, M. M. Gayanova, K. V. Mironov, D. V. Kurennov
Anti-fraud system on the basis of data mining technologies. 2017 IEEE International Symposium on
Signal Processing and Information Technology (ISSPIT), Bilbao, Spain, pp. 243 248
[Sha18] G.R. Shakhmametova, N.I. Yusupova, V.V. Mironov, R.Kh. Zulkarneev Statistical and Intelligent
Methods of Medical Data Processing. IT in Industry, vol. 6, no.2, 2018, pp. 13 to 18.
[Yus16] N.I. Yusupova, D.R. Bogdanova, M.V. Boyko Processing Weak-Structured Data Based on Methods of
Artificial Intelligence. Innovative Machinery, Moscow, 2016, 267 pp.
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