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the application layer with clouds and data centers for analyzing and exploiting cross‐domain data, and developing and managing intelligent IoT services. As IoT devices and their data are growing explosively, this architecture cannot satisfy a series of crucial service requirements on massive simultaneous connections, high bandwidth, low latency, ultra‐reliable under bursty traffic, end‐to‐end security and privacy protections. In order to tackle these challenges and support various IoT application scenarios, a user‐centric flexible service architecture should be implemented, so that feasible micro‐services in the neighborhood can be identified and assembled to meet very sophisticated user requirements¹⁰. This desirable data‐driven approach requires a multi‐tier computing network architecture that not only connects centralized computing resources and AI algorithms in the cloud but, more importantly, utilizes distributed computing resources and algorithms in the network, at the edge, and on IoT devices¹¹. Therefore, most data and IoT services can be efficiently processed and executed by intelligent algorithms using local or regional computing resources at nearby sites, such as empowered edge and distributed cloud¹². In doing so, a large amount of IoT data need not to be transmitted over long distances to the clouds, which means lower communication bandwidth, lower service delay, reliable network connectivity, lower vulnerability to different attacks, and better user satisfaction in all kinds of industrial sectors and application scenarios.

Based on the above analyses, we believe a pyramid model could best describe the fundamental relationships between these three elements, i.e. data (as raw material), computing (as hardware resource) and algorithms (as software resource) jointly constitute the triangular base to support a variety of user‐centric intelligent IoT services at the spire by using different kinds of smart terminals or devices. This book aims at giving a state‐of‐the‐art review of intelligent IoT technologies and applications, as well as the key challenges and opportunities facing the digital world. In particular, from the perspectives of network operators, service providers and typical users, this book tries to answer the following five critical questions.

      1 What is the most feasible network architecture to effectively provide sufficient resources anywhere at any time for intelligent IoT application scenarios?

      2 How can we efficiently discover, allocate and manage computing, communication and caching resources in heterogeneous networks across multiple domains and operators?

      3 How do we agilely achieve adaptive service orchestration and reliable service provisioning to meet dynamic user requirements in real‐time?

      4 How do we effectively protect data privacy in IoT applications, where IoT devices and edge/fog computing nodes only have limited resources and capabilities?

      5 How do we continuously guarantee and maintain the synchronization and reliability of wide‐area IoT systems and applications?

      Specifically, Chapter 1 reviews the traditional IoT system architecture, some well‐known IoT technologies and standards, which are leveraged to improve the perception of the physical world, as well as the efficiency of data collection, transmission and analysis. Further, a pyramid model concentrated on user data, distributed algorithms and computing resources is proposed and discussed. This model is based on the multi‐tier computing network architecture and applies a data‐driven approach to coordinate and allocate most feasible resources and algorithms inside the network for effective processing of user‐centric data in real‐time, thus supporting various intelligent IoT applications and services, such as information extraction, pattern recognition, decision making, behavior analysis and prediction. As 5G communication networks and edge/fog/cloud computing technologies are getting more and more popular in different industrial sectors and business domains, a series of new requirements and key challenges should be carefully addressed for providing more sophisticated, data‐driven and intelligent IoT services with usable resources and AI algorithms in different application scenarios. For instance, in a smart factory, 4G/5G mobile communication networks and wireless terminals are ubiquitous and always connected. A large variety of industrial IoT devices are continuously monitoring the working environment and machines, and generating massive data on temperature, humidity, pressure, state, position, movement, etc. This huge amount of data needs to be quickly analyzed and accurately comprehended with domain‐specific knowledge and experiences. To satisfy the stringent requirements on end‐to‐end service delay, data security, user privacy, as well as accuracy and timeliness in decision making and operation control, the proposed new model and architecture are able to fully utilize dispersive computing resources and intelligent algorithms in the neighborhood for effectively processing massive cross‐domain data, which is collected and shared through intensive but reliable local communications between devices, machines and distributed edge/fog nodes.

Chapter 2 presents the multi‐tier computing network architecture for intelligent IoT applications, which comprises not only computing, communication and caching (3C) resources but also a variety of embedded AI algorithms along the cloud‐to‐things continuum. This architecture advocates active collaborations between cloud, fog and edge computing technologies for intelligent and efficient data processing at different levels and locations. It is strongly underpinned by two important frameworks, i.e. Cost Aware Task Scheduling (CATS) and Fog as a Service Technology (FA²ST). Specifically, CATS is an effective resource sharing framework that utilizes a practical incentive mechanism to motivate efficient collaboration and task scheduling across heterogeneous resources at multiple devices, edge/fog nodes and the cloud, which are probably owned by different individuals and operators. While FA²ST is a flexible service provisioning framework that is able to discover, orchestrate, and manage micro‐services and cross‐layer 3C resources at any time, anywhere close to end users, thus guaranteeing high‐quality services under dynamic network conditions. Further, two intelligent application scenarios and the corresponding technical solutions are described in detail. Firstly, based on edge computing, an on‐site cooperative Deep Neural Network (DNN) inference framework is proposed to execute DNN inference tasks with low latency and high accuracy for industrial IoT applications, thus meeting the strict requirements on service delay and reliability. Secondly, based on fog computing, a three‐tier collaborative computing and service framework is proposed to support dynamic task offloading and service composition in Simultaneous Localization and Mapping (SLAM) for a robot swarm system, which requires timely data sharing and joint processing among multiple moving robots. Both cases are implemented and evaluated in real experiments, and a set of performance metrics demonstrates the effectiveness of the proposed multi‐tier computing network and service architecture in supporting intelligence IoT applications in stationary and mobile scenarios.

      Under this architecture, Chapter 3 investigates cross‐domain resources management and adaptive allocation methods for dynamic task scheduling to meet different application requirements and performance metrics. Specifically, considering a general system model with Multiple Tasks and Multiple Helpers (MTMH), the game theory based analytical frameworks for non‐splittable and splittable tasks are derived to study the overall delay performance under dynamic computing and communication (2C) resources. The existence of a Nash equilibrium for both cases is proven. Two distributed task scheduling algorithms are developed for maximizing the utilization of nearby 2C resources, thus minimizing the overall service delay and maximizing the number of beneficial nodes through device/node collaborations. Further, by taking storage or caching into consideration, a fog‐enabled 3C resource sharing framework is proposed for energy‐critical IoT data processing applications. An energy cost minimization problem under 3C constraints is formulated and an efficient 3C resources management algorithm is then developed by using an iterative task team formation mechanism. This algorithm can greatly reduce energy consumption and converge to a stable system point via utility improving iterations. In addition, based on the fundamental trade‐off relationship between service delay and energy consumption in IoT devices/nodes, an offload forwarding

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