Knowledge Graphs and Big Data Processing

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From「Knowledge Graphs and Big Data Processing」.

Data Analytics involves applying algorithmic processes to derive insights. Nowadays it is used in many industries to allow organizations and companies to make better decisions as well as to verify or disprove existing theories or models. The term data analytics is often used interchangeably with intelligence, statistics, reasoning, data mining, knowledge discovery, and others. Being in the era of big data, Big Data Analytics thus refers to the strategy of analyzing large volumes of data gathered from a wide variety of sources, including social networks, transaction records, videos, digital images, and different kinds of sensors. The goal of this book is to introduce some of the definitions, methods, tools, frameworks, and solutions for big data processing, starting from the process of information extraction and knowledge representation, via knowledge processing and analytics to visualization, sense-making, and practical applications. However, this book is not intended either to cover the whole set of big data analytics methods or to provide a complete collection of references. Each chapter in this book addresses some pertinent aspect of the data processing chain, with a specific focus on understanding Enterprise Knowledge Graphs, Semantic Big Data Architectures, and Smart Data Analytics solutions. Chapter 1’s purpose is to characterize the relevant aspects of the Big Data Ecosystem and to explain the ecosystem with respect to the big data characteristics, the components needed for implementing end-to-end big data processing and the need to use semantics to improve data management, integration, processing, and analytical tasks. Chapter 2 gives an overview of different definitions of the term Knowledge Graphs (KGs). In this chapter, we are going to take the position that precisely in the multitude of definitions lies one of the strengths of the area. We will choose a particular perspective, which we will call the layered perspective, and three views on Knowledge Graphs to guide the reader in a structured way. Chapter 3 introduces the key technologies and business drivers for building big data applications and presents in detail several open-source tools and Big Data Frameworks for handling Big Data. The subsequent chapters discuss the knowledge processing chain from the perspective of Knowledge Graph Creation (Chapter 4), via Federated Query Processing (Chapter 5), to Reasoning in Knowledge Graphs (Chapter 6). Chapter 7 brings to attention the SANSA framework, which combines distributed analytics and semantic technologies into a scalable semantic analytics stack. Chapter 8 elaborates further the semantic data integration problems and presents COMET (COntextualized MoleculE-based matching Technique and framework) for matching contextually equivalent RDF entities from different sources into a set of 1-1 perfect matches between entities. As the goal of the LAMBDA Project is to study the potentials, prospects, and challenges of Big Data Analytics in real-world applications, in addition to Chapter 1 (traffic management example), Chapter 9 discusses the role of big data in different industries. Finally, in Chapter 10, one sector has been selected – the energy domain – and insight is given into some potential applications of big data-oriented tools and analytical technologies for the control and monitoring of electricity production, distribution, and consumption. This book is addressed to graduate students from technical disciplines, to professional audiences following continuous education short courses, and to researchers from diverse areas following self-study courses. Basic skills in computer science, mathematics, and statistics are required.

Foundation

Chapter 1 Ecosystem of Big Data

The rapid development of digital technologies, IoT products and connectivity platforms, social networking applications, video, audio and geolocation services has created opportunities for collecting/accumulating a large amount of data. While in the past corporations used to deal with static, centrally stored data collected from various sources, with the birth of the web and cloud services, cloud computing is rapidly overtaking the traditional in-house system as a reliable, scalable and cost-effective IT solution. The high volumes of structures and unstructured data, stored in a distributed manner, and the wide variety of data sources pose problems related to data/knowledge representation and integration, data querying, business analysis and knowledge discovery. This introductory chapter serves to characterize the relevant aspects of the Big Data Ecosystem with respect to big data characteristics, the components needed for implementing end-to-end big data processing and the need for using semantics for improving the data management, integration, processing, and analytical tasks.

Chapter 2 Knowledge Graphs: The Layered Perspective

Knowledge Graphs (KGs) are one of the key trends among the next wave of technologies. Many definitions exist of what a Knowledge Graph is, and in this chapter, we are going to take the position that precisely in the multitude of definitions lies one of the strengths of the area. We will choose a particular perspective, which we will call the layered perspective, and three views on Knowledge Graphs.

Chapter 3 Big Data Outlook, Tools, and Architectures

Big data is a persistent phenomena, the data is being generated and processed in a myriad of digitised scenarios. This chapter covers the history of ‘big data’ and aims to provide an overview of the existing terms and enablers related to big data. Furthermore, the chapter covers prominent technologies, tools, and architectures developed to handle this large data at scale. At the end, the chapter reviews knowledge graphs that address the challenges (e.g. heterogeneity, interoperability, variety) of big data through their specialised representation. After reading this chapter, the reader can develop an understanding of the broad spectrum of big data ranging from important terms, challenges, handling technologies, and their connection with large scale knowledge graphs.

Chapter 4 Creation of Knowledge Graphs

This chapter introduces how Knowledge Graphs are generated. The goal is to gain an overview of different approaches that were proposed and find out more details about the current prevalent ones. After reading this chapter, the reader should have an understanding of the different solutions available to generate Knowledge Graphs and should be able to choose the mapping language that best suits a certain use case.

Chapter 5 Federated Query Processing

Big data plays a relevant role in promoting both manufacturing and scientific development through industrial digitization and emerging interdisciplinary research. Semantic web technologies have also experienced great progress, and scientific communities and practitioners have contributed to the problem of big data management with ontological models, controlled vocabularies, linked datasets, data models, query languages, as well as tools for transforming big data into knowledge from which decisions can be made. Despite the significant impact of big data and semantic web technologies, we are entering into a new era where domains like genomics are projected to grow very rapidly in the next decade. In this next era, integrating big data demands novel and scalable tools for enabling not only big data ingestion and curation but also efficient large-scale exploration and discovery. Federated query processing techniques provide a solution to scale up to large volumes of data distributed across multiple data sources. Federated query processing techniques resort to source descriptions to identify relevant data sources for a query, as well as to find efficient execution plans that minimize the total execution time of a query and maximize the completeness of the answers. This chapter summarizes the main characteristics of a federated query engine, reviews the current state of the field, and outlines the problems that still remain open and represent grand challenges for the area.

Chapter 6 Reasoning in Knowledge Graphs: An Embeddings Spotlight

In this chapter we introduce the aspect of reasoning in Knowledge Graphs. As in Chap. 2, we will give a broad overview focusing on the multitude of reasoning techniques: spanning logic-based reasoning, embedding-based reasoning, neural network-based reasoning, etc. In particular, we will discuss three dimensions of reasoning in Knowledge Graphs. Complementing these dimensions, we will structure our exploration based on a pragmatic view of reasoning tasks and families of reasoning tasks: reasoning for knowledge integration, knowledge discovery and application services.

Chapter 7 Scalable Knowledge Graph Processing Using SANSA

The size and number of knowledge graphs have increased tremendously in recent years. In the meantime, the distributed data processing technologies have also advanced to deal with big data and large scale knowledge graphs. This chapter introduces Scalable Semantic Analytics Stack (SANSA), that addresses the challenge of dealing with large scale RDF data and provides a unified framework for applications like link prediction, knowledge base completion, querying, and reasoning. We discuss the motivation, background and the architecture of SANSA. SANSA is built using general-purpose processing engines Apache Spark and Apache Flink. After reading this chapter, the reader should have an understanding of the different layers and corresponding APIs available to handle Knowledge Graphs at scale using SANSA.

Chapter 8 Context-Based Entity Matching for Big Data

In the Big Data era, where variety is the most dominant dimension, the RDF data model enables the creation and integration of actionable knowledge from heterogeneous data sources. However, the RDF data model allows for describing entities under various contexts, e.g., people can be described from its demographic context, but as well from their professional contexts. Context-aware description poses challenges during entity matching of RDF datasets—the match might not be valid in every context. To perform a contextually relevant entity matching, the specific context under which a data-driven task, e.g., data integration is performed, must be taken into account. However, existing approaches only consider inter-schema and properties mapping of different data sources and prevent users from selecting contexts and conditions during a data integration process. We devise COMET, an entity matching technique that relies on both the knowledge stated in RDF vocabularies and a context-based similarity metric to map contextually equivalent RDF graphs. COMET follows a two-fold approach to solve the problem of entity matching in RDF graphs in a context-aware manner. In the first step, COMET computes the similarity measures across RDF entities and resorts to the Formal Concept Analysis algorithm to map contextually equivalent RDF entities. Finally, COMET combines the results of the first step and executes a 1-1 perfect matching algorithm for matching RDF entities based on the combined scores. We empirically evaluate the performance of COMET on testbed from DBpedia. The experimental results suggest that COMET accurately matches equivalent RDF graphs in a context-dependent manner.

Chapter 9 Survey on Big Data Applications

The goal of this chapter is to shed light on different types of big data applications needed in various industries including healthcare, transportation, energy, banking and insurance, digital media and e-commerce, environment, safety and security, telecommunications, and manufacturing. In response to the problems of analyzing large-scale data, different tools, techniques, and technologies have bee developed and are available for experimentation. In our analysis, we focused on literature (review articles) accessible via the Elsevier ScienceDirect service and the Springer Link service from more recent years, mainly from the last two decades. For the selected industries, this chapter also discusses challenges that can be addressed and overcome using the semantic processing approaches and knowledge reasoning approaches discussed in this book.

Chapter 10 Case Study from the Energy Domain

Information systems are most often the main focus when considering applications of Big Data technology. However, the energy domain is more than suitable also given the worldwide coverage of electrification. Additionally, the energy sector has been recognized to be in dire need of modernization, which would include tackling (i.e. processing, storing and interpreting) a vast amount of data. The motivation for including a case study on the applications of big data technologies in the energy domain is clear, and is thus the purpose of this chapter. An application of linked data and post-processing energy data has been covered, whilst a special focus has been put on the analytical services involved, concrete methodologies and their exploitation.

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