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This book examines the methodological foundations of the Big Data-driven world, formulates its concept within the frameworks of modern control methods and theories, and approaches the peculiarities of Control Technologies as a specific sphere of the Big Data-driven world, distinguished in the modern Digital Economy. The book studies the genesis of mathematical and information methods’ transition from data analysis & processing to knowledge discovery and predictive analytics in the 21st century. In addition, it analyzes the conditions of development and implementation of Big Data analysis approaches in investigative activities and determines the role and meaning of global networks as platforms for the establishment of legislation and regulations in the Big Data-driven world. The book examines that world through the prism of Legislation Issues, substantiate the scientific and methodological approaches to studying modern mechanisms of terrorism and extremism counteraction in the conditions of new challenges of dissemination and accessibility of socially dangerous information. Systematization of successful experience of the Big Data solutions implementation in the different countries and analyze causal connections of the Digital Economy formation from the positions of new technological challenges is performed. The book’s target audience includes scientists, students, PhD and Master students who conduct scientific research on the topic of Big Data not only in the field of IT& data science, but also in connection with legislative regulation aspects of the modern information society. It also includes practitioners and experts, as well as state authorities and representatives of international organizations interested in creating mechanisms for implementing Digital Economy projects in the Big Data-driven world.
This book constitutes the proceedings of the 4th Conference on Creativity in Intellectual Technologies and Data Science, CIT&DS 2021, held in Volgograd, Russia, in September 2021. The 39 full papers, 7 short papers, and 2 keynote papers presented were carefully reviewed and selected from 182 submissions. The papers are organized in the following topical sections: Artificial intelligence and deep learning technologies: knowledge discovery in patent and open sources; open science semantic technologies; IoT and computer vision in knowledge-based control; Cyber-physical systems and big data-driven control: pro-active modeling in intelligent decision making support; design creativity in CASE/CAI/CAD/PDM; intelligent technologies in urban design and computing; Intelligent technologies in social engineering: data science in social networks analysis and cyber security; educational creativity and game-based learning; intelligent assistive technologies: software design and application.
This book discusses the basic principles of sustainable development in a smart city ecosystem to better serve the life of citizens. It examines smart city systems driven by emerging IoT-powered technologies and the other dependent platforms. Smart Cities: AI, IoT Technologies, Big Data Solutions, Cloud Platforms, and Cybersecurity Techniques discusses the design and implementation of the core components of the smart city ecosystem. The editors discuss the effective management and development of smart city infrastructures, starting with planning and integrating complex models and diverse frameworks into an ecosystem. Specifically the chapters examine the core infrastructure elements, including activities of the public and private services as well as innovative ICT solutions, computer vision, IoT technologies, data tools, cloud services, AR/VR technologies, cybersecurity techniques, treatment solution of the environmental water pollution, and other intelligent devices for supporting sustainable living in the smart environment. The chapters also discuss machine vision models and implementation as well as real-time robotic applications. Upon reading the book, users will be able to handle the challenges and improvements of security for smart systems, and will have the know-how to analyze and visualize data using big data tools and visualization applications. The book will provide the technologies, solutions as well as designs of smart cities with advanced tools and techniques for students, researchers, engineers, and academics.
This book presents key advances in intelligent information technologies for industry. This book of Lecture Notes in Networks and Systems contains the papers presented in the main track of IITI 2021, the Fifth International Scientific Conference on Intelligent Information Technologies for Industry held on September 30 – October 4, 2021 in Sirius, Russia. The conference was jointly co-organized by Rostov State Transport University (Russia) and VŠB–Technical University of Ostrava (Czech Republic) with the participation of Russian Association for Artificial Intelligence (RAAI) and Sirius University (Russia). IITI 2021 was devoted to practical models and industrial applications related to intelligent information systems. It was considered as a meeting point for researchers and practitioners to enable the implementation of advanced information technologies into various industries. Nevertheless, some theoretical talks concerning the state of the art in intelligent systems and soft computing were also included into proceedings. There were 180 paper submissions from 14 countries. Each submission was reviewed by at least three chairs or PC members. We accepted 69 regular papers (38\%). Unfortunately, due to limitations of conference topics and edited volumes, the Program Committee was forced to reject some interesting papers, which did not satisfy these topics or publisher requirements. We would like to thank all authors and reviewers for their work and valuable contributions. The friendly and welcoming attitude of conference supporters and contributors made this event a success!
In this book readers will find technological discussions on the existing and emerging technologies across the different stages of the big data value chain. They will learn about legal aspects of big data, the social impact, and about education needs and requirements. And they will discover the business perspective and how big data technology can be exploited to deliver value within different sectors of the economy. The book is structured in four parts: Part I “The Big Data Opportunity” explores the value potential of big data with a particular focus on the European context. It also describes the legal, business and social dimensions that need to be addressed, and briefly introduces the European Commission’s BIG project. Part II “The Big Data Value Chain” details the complete big data lifecycle from a technical point of view, ranging from data acquisition, analysis, curation and storage, to data usage and exploitation. Next, Part III “Usage and Exploitation of Big Data” illustrates the value creation possibilities of big data applications in various sectors, including industry, healthcare, finance, energy, media and public services. Finally, Part IV “A Roadmap for Big Data Research” identifies and prioritizes the cross-sectorial requirements for big data research, and outlines the most urgent and challenging technological, economic, political and societal issues for big data in Europe. This compendium summarizes more than two years of work performed by a leading group of major European research centers and industries in the context of the BIG project. It brings together research findings, forecasts and estimates related to this challenging technological context that is becoming the major axis of the new digitally transformed business environment.
This book presents new findings in industrial cyber-physical system design and control for various domains, as well as their social and economic impacts on society. Industry 4.0 requires new approaches in the context of secure connections, control, and maintenance of cyber-physical systems as well as enhancing their interaction with humans. The book focuses on open issues of cyber-physical system control and its usage, discussing implemented breakthrough systems, models, programs, and methods that could be used in industrial processes for the control, condition assessment, diagnostics, prognostication, and proactive maintenance of cyber-physical systems. Further, it addresses the topic of ensuring the cybersecurity of industrial cyber-physical systems and proposes new, reliable solutions. The authors also examine the impact of university courses on the performance of industrial complexes, and the organization of education for the development of cyber-physical systems. The book is intended for practitioners, enterprise representatives, scientists, students, and Ph.D. and master’s students conducting research in the area of cyber-physical system development and implementation in various domains.
This book focuses on open issues of Society 5.0, a new paradigm of a society that balances a human-centred approach and technologies based on cyber-physical systems and artificial intelligence. The book contains results of how intelligent or cyber-physical systems help to improve the quality of life in society despite new challenges. Discusses implemented breakthrough systems, models, programs, and methods that cover the following topics: biomedicine and healthcare, innovations in socio-economic systems, intelligent energetics, advances in transport systems, human-centric technologies. These approaches help to improve human society using cyber-physical systems in a dramatically changing environment. The target audience of the book are practitioners, enterprises representatives, scientists, PhD and Master students who perform scientific research on the application of cyber-physical systems towards Society 5.0.
In the modern world, most gross product is created within Enterprise firms, project programs, state agencies, transnational corporations and their divisions, as well as various associations and compositions of the above entities. Enterprises, being, on the one hand, complex, and, on the other hand, widespread systems, are the subject matter of cybernetics, system theory, operations research, management sciences and many other fields of knowledge. However, the complexity of the system obstructs the development of mathematically rigorous foundations for Enterprise control. Moreover, methods of operations research and related sciences, which are widely used in practice, provide optimization of the constituents of an Enterprise, without modeling it as a whole system. But the optimization of parts does not lead to the optimality of the whole, and, also, the absence of top-down and holistic mathematical models of Enterprise contradicts the principle of holism and the system approach. The approach in this book looks first at Enterprise Systems and their essential aspects as complex sociotechnical systems composed of integrated sets of structural and process models (Chapters 1 and 2). A uniform description of all the heterogeneous fields of the modern Enterprise (marketing, sales, manufacturing, HR, finance, etc.) is then made, and the Enterprise Control Problem is posed as a top-down and holistic mathematical optimization problem (Chapter 3). Original models and methods of contract theory (Chapter 4), technology management (Chapter 5), human behavior and human capital (Chapter 6) and complex activity and resource planning (Chapter 7) are developed to solve the problem. Structural processes and mathematical models constitute an Optimal Enterprise Control Framework (Chapter 8) that provides a practical solution to the Enterprise Control Problem. This book is a resource for postgraduate and doctoral students, postdoctoral researchers and professors with research interests in the following fields of science: Fundamental Complex Systems study, Complex Systems Engineering, Enterprise Systems Engineering Applications of Operations Research, Optimization, Probability and Stochastic processes to Management Science, Economics and Business Theory of the Firm Business and Management – general, strategy/leadership, organization management, operations management and management information systems Theory of Business Processes, Business Processes Improvement and Reengineering
Financial technologies are understood as ICT-based financial innovations and business entities based on these innovations (Lai & Samers, 2021; Langley & Leyshon, 2021; Wójcik, 2021b). Like other technological innovations, Fintech not only influences technical parameters of products and services, but also transforms the economic organization of firms and industries (Baldwin, 2020; Sanchez & Mahoney, 2013). ICT solutions in the financial sector complement the existing services (e.g., payment platforms), substitute human work and tangible assets (e.g., robo-advisers), and generate new solutions (e.g., mobile wallets). Furthermore, Fintech transcends borders and geographical frontiers, as exemplified by crowdfunding in financial centers accessible to start-ups and growth firms from peripheral locations (Bonini & Capizzi, 2019; Spigel, 2022). However, the ongoing digital transformation of financial services has a strong spatial and multiscalar dimension and takes various forms and outcomes, depending on the socioeconomic and institutional specifics (Leyshon, 2020; Baranauskas, 2021; Coe, 2021). The financial sector has recently been conceptualized as a financial ecosystem to reflect its exposition to dynamics and occasional disruptive change (Leyshon, 2020). Within a broadly defined financial ecosystem, two interrelated structures can be identified according to spatial characteristics (Gancarczyk, Łasak, & Gancarczyk, 2022; Lai, 2020). The first comprises global networks of financial centers and large investment banks, that is, global financial networks (GFNs), largely spanning over the borders of countries and regions (Coe, Lai, & Wójcik, 2014; Coe, 2021). The other forms are financial ecologies as segments of the financial ecosystem that are delimited by particular territories (Lai, 2016; Leyshon et al., 2004; Leyshon et al., 2006; Langley & Leyshon, 2020). Being subunits of the financial ecosystem, FEs represent interrelated financial intermediaries and other economic agents, focused on the provision and access to financial services in particular territories (Beaverstock et al., 2013; DawnBurton, 2020; Lai, 2016; Leyshon et al., 2004; Leyshon, 2020). In this vein, FEs can be considered as governance modes comprising private and public entities, such as banks, Fintech, BigTech, public agencies, enterprises, and customers, and relationships among these entities. The actors and relationships are delimited by a given location, such as a region or city (Langley, 2016; DawnBurton, 2020; Chen & Hassink, 2021; Appleyard, 2020). The relevance of the FE concept is based on the disproportionate outcomes that small ecologies may raise for comprehensive systems, as evidenced by the subprime market failure in the USA, affecting the subsequent financial and economic crisis of 2007-2009 (Leyshon, 2020), with relevant effects on many economies such as the European economy (Rodil-Marzábal & Menezes-Ferreira-Junior, 2016). Therefore, investigating small but critical points within the larger financial ecosystem is crucial for policy. It is also theoretically justified since the financial ecosystem has been predominantly studied as a general abstraction of the financial sector. Subsystems remain less explored, especially in the granularity of the spatial context. Since FEs are context-specific and undergo co-evolutionary dynamics with this context, they also transform as a phenomenon and a concept (Lai, 2020; Wójcik, 2021a). One of the main influences comes from the recent technological developments raised by Fintech. The growing empirical evidence in this area calls for understanding consequences for the FE construct (Welch, Rumyantseva, & Hewerdine, 2016) and adequate policy responses. Resonating with the said research gaps and an early stage of the development of the FE idea, this article aims to identify how Fintech frames FEs and propose the related conceptual and policy implications. To frame the FE concept, we use the methodological lens of construct clarity principles (Suddaby, 2010; Simsek et al., 2017) and concept reconstruction (Welch et al., 2016). The method includes a systematic literature review, which represents a unique approach, since the existing theorizing of FEs has been either in the form of conceptual papers or narrative reviews (Lund et al., 2016). Our findings raise conceptual and policy-related contributions. First, the article conceptually reframes the understanding of FE as financial services governance enhanced by technological advancements and focused on territorial projects and communities. Second, the concept of FE was clarified according to its main elements and its relationships with other adjacent ideas of spatial networking for socioeconomic development. Third, research propositions and areas for further investigation were proposed. In the following, we present the literature review to justify our aim and research questions. The methodology section presents the conceptual lens for our discussion of the FE as a construct shaped by Fintech; it also specifies the method of a systematic literature review. Results, discussion, and conclusion proceed in the next sections. CONCEPTUAL FOUNDATIONS Financial ecosystems were institutionally introduced to the policy framework and gained widespread recognition in research since the Federal Reserve Bank of New York conference in 2006 (Leyshon, 2020). FEs have become a new theoretical abstraction of the financial services sector as an alternative to the neoclassical equilibrium-based doctrine (Leyshon, 2020). The main difference was in acknowledging radical dynamics within the sector treated as an ecosystem with a diverse and flexible set of financial intermediaries, institutional investors and supporting entities, such as exchanges, data providers, and regulators (Bose, Dong, & Simpson, 2019). The abstraction of complex adaptive systems has often been recalled as a broad framework to understand the functioning and change in the financial sector. Consequently, theoretical perspectives of evolution and coevolution, and in particular, the network governance concept to cope with complex coordination issues, demonstrate explanatory power in studying FEs (Chen & Hassink, 2021; Ponte & Sturgeon, 2014; Chen & Hassink, 2021, 2020; Coe & Yeung, 2019). The lens of the financial ecosystem was intended to provide concepts and methods that would address environmental and regulatory shocks and prepare for future breakthrough changes to the financial system (Leyshon, 2020; Fasnacht, 2018). Furthermore, within this idea, the classical goals set for the financial sector, such as optimizing capital allocation, matching savers and investors, and signaling scarcity and abundance, were expanded by sustainability and social responsibility goals that go beyond purely economizing (Bose et al., 2019; Fasnacht, 2018). The focus on the financial ecosystem as a model or abstraction of the financial sector predominated over what is the core of ecosystems, the interrelated actors embedded in particular socio-economic and institutional environments (Strumeyer & Swammy, 2017; Bose et al., 2019; Lai, 2020; Wojcik, 2021). Although the legal frameworks of financial ecosystems are intensely studied, the remaining context, such as socioeconomic environment and informal institutions, remain much less explored (Gancarczyk et al., 2022). These contextual factors are specific to individual territories within the financial ecosystem (Ponte & Sturgeon, 2014; Chen & Hassink, 2021, 2020; Coe & Yeung, 2019). Since the systemic approach assumes interrelations and mutual influences among its parts, changes or weaknesses in a subsystem affect the whole. A painful recognition for this gap happened just after the indicated 2006 turn to the financial sector as an ecosystem, with the shock of the 2007-2009 crisis. The latter originated in the smaller subunit of the ecosystem of the US subprime market. The following pandemic and political breakthroughs, as well as technological developments, raised new challenges, adaptations, and structural changes to the financial ecosystem (Leyshon, 2020). However, they were implemented differently in different spatial contexts, which stimulated a more granular approach of the financial ecosystem as a collection of place-based subsystems, that is, financial ecologies (Lai, 2016). Another justification for the more place-based perspective is that localized supply chains might require localized financial systems or ecologies (Sarawut & Sangkaew, 2022). Wójcik and Iannou (2020) argue that local and regional financial centers are expected to lose their position, and that the territories outside the core regions and financial centers will have to rely on retail banking and the public sector to fund investment and sustainable development. These smaller ecologies will coexist with global financial networks, which are worldwide networks of financial centers and investment banks (Lai, 2020). The concept of FE originated in the field of economic geography to reflect the spatial specifics and uneven distribution of financial ecosystems, and to address the crucial issues in financing for the particular territorial populations, such as inclusion, financialization, surveillance, and over-indebtedness (DawnBurton, 2020). Consequently, the FE concept recasts the financial system as a coalition of smaller constitutive ecologies, such that distinctive groups of financial knowledge and practices emerge in different places with uneven connectivity and material outcomes (Lai, 2016). The relevance of the FE phenomenon and concept consists of a more fine-grained approach to understanding uneven access to financial services and uneven connectedness to the financial system (DawnBurton, 2020; Leyshon, 2020). Furthermore, research on FEs signals weak and strong points in subsystems that can affect the efficiency of the entire financial system. FEs represent interrelated financial intermediaries and other economic agents focused on the provision of and access to financial services in particular territories (Leyshon, 2020). As systemic phenomena, they comprise both actors and their relationships, in which actors form various configurations of private and public entities, such as banks, public agencies, enterprises, and customers. The actors and relationships are delimited by a given location that forms a spatial context, that is, a set socioeconomic conditions of a territory, be it a region, city, or a country, and acknowledging multiscalar contexts (Langley, 2016; DawnBurton, 2020; Chen & Hassink, 2021; Appleyard, 2020). The context of a particular ecology should also be considered in a wider, multiscalar perspective. Multiscalarity of the context is an idea that advocates a multilevel analysis of a spatial unit (Chen & Hassink, 2021). The example of this approach is a regional financial ecology that should be analyzed in the context of the region, country, and relevant international environments. Due to the multiscalar perspective, spatially focused FEs do not lose a broader framework of the financial system in larger units and globally (Chen & Hassink, 2020). Taking into account the nature of the FE presented above, the main elements of this construct include actors, relationships among actors, outcomes, and contexts. While the scope of actors and contexts has been outlined above, the systemic relationships and outcomes of the FE require further explanation. The FE relationships are often captured as governance, whereby governance represents the sets of institutions (rules, norms) that affect the functioning of a particular socioeconomic system and its efficiency (Colombo, Dagnino, Lehmann, & Salmador, 2019; Ostrom, 1986; Williamson, 2000). In this vein, governance can be described according to the rules of collaboration and competition, and power relations (Lai, 2018). Types of governance range from the firm to hybrids, such as networks, and to markets (Gereffi, Humphrey, & Sturgeon, 2005; Williamson, 2000). The outcomes of FE represent the terms of and access to financing, with a more general effect on financial inclusion or exclusion and on the overall territorial development. With the wider financial systems, FEs share such constitutive elements as actors and their relationships centered around financial services supply and demand (Bose et al., 2019; Fasnacht, 2018; Lai, 2020). Moreover, they similarly focus on the coordination of the system through the lens of governance (DawnBurton, 2020; Langley & Leyshon, 2021). However, FEs also demonstrate some unique characteristics in relation to wider financial ecosystems, such as clear delimitation of a territorial space, be it a city, region, or country, and acknowledgment of an associated socioeconomic and institutional context (DawnBurton, 2020; Leyshon et al., 2004). The focus on a particular territory does not ignore the systemic nature of economic relationships in the globalized world, since FEs are considered in a multiscalar context (Chen & Hassink, 2020; Leyshon, 2020). Connectivity of given populations to a broader financial system becomes one of the major issues to ensure the infusion of external sources (Coe et al., 2014). The focus on relationships between commercial banks and retail customers, as well as underserved and unbanked individuals or enterprises, differentiates FEs from GFNs (Beaverstock et al., 2013; Coe et al., 2014; DawnBurton, 2020). The latter consider global networks of investment banks and financial centers liaising over peripheral and noncore territories (Coe et al., 2014; DawnBurton, 2020; Lai, 2018). This global perspective is also related to the governance approach in the framework of global value chains, which extends to financial activity (Milberg, 2008; Coe et al., 2014; Seabrooke & Wigan, 2017). The emphasis on socioeconomic effects for disadvantaged market segments and particular industries and projects represents an additional feature of FEs as outcome-oriented systems. While financial ecosystems are primarily targeted at economic efficiency and stability of the system itself, FEs emphasize territorial target groups and projects (Langley, 2016; Langley & Leyshon, 2017). Regarding governance, the focus of FEs has been on network governance of a complex and multi-actor adaptive system (Leyshon, 2020). Network governance is considered not only from the perspective of power relations and resource allocation, but also from learning and financial practices (Lai, 2016). As evolutionary and dynamic phenomena, financial ecosystems and FE undergo substantive and conceptual developments. One of the ongoing breakthrough transformations stems from Fintech. Financial ecosystems are increasingly reconceptualized as the ultimate mode of financial services governance transformed by financial technologies (Wójcik & Ioannou, 2020; Łasak & Gancarczyk, 2022; Gancarczyk et al., 2022). Similarly, the intensive development of FEs is closely related to technological changes that enable a flexible establishment of new forms of cooperation between economic entities (Arsanian & Fischer, 2019). Fintech increase efficiency and availability of existing and launch of new financial products (Hill, 2018; Livesey, 2018; Nicoletti et al., 2017; Sabatini, Cucculelli, & Gregori, 2022; Scardovi, 2017). However, negative effects are also reported, such as over-indebtedness of risky customers, Fintech surveillance, and exclusion of some customers due to computer illiteracy (Kong & Loubere, 2021; Łasak & Gancarczyk, 2021; Brooks, 2021). The economic and social outcomes of the emerging FEs transformed by Fintech have not been fully understood and systemized (Langley & Leyshon, 2021; Wójcik, 2021b). Given technological influences, the FE undergoes developments in its core elements, i.e., actors, governance, and outcomes, acknowledging spatial contexts. Despite the increasing stock of empirical findings that describe the impact of Fintech on the functioning of FEs, we lack a synthesis reflection to reconsider FEs from this perspective. Therefore, we formulate the following research questions: RQ1) How does Fintech affect the FE phenomenon in the area of its actors, governance, and outcomes in various spatial contexts? RQ2) What are the conceptual and policy-related implications of Fintech influencing FEs?
This book contains contributions from an international scientific conference, “Smart Nations: Global Trends In The Digital Economy”, which was organized by the State University of Management (Moscow). By presenting international research on the issues of the Smart Nations concept, this book includes topics such as state and legal aspects of digital transformation of management systems, new technologies in the digital environment of the information society and smart economy as a new reality. The conference proceedings cover legal, informational, technological and other aspects of socio-economic development in the context of digital innovations. This work addresses theoretical and practical aspects by studying the phenomenon of Smart Nations that requires understanding the modern information technologies, big data analysis, distributed registry management, new microprocessor technologies and broadband data transmission technologies in terms of their usefulness and accessibility to any representative of humanity.