Edge Computing for Internet of Things

The Internet-of-Things is becoming an established technology, with devices being deployed in homes, workplaces, and public areas at an increasingly rapid rate. IoT devices are the core technology of smart-homes, smart-cities, intelligent transport systems, and promise to optimise travel, reduce energy usage and improve quality of life. With the IoT prevalence, the problem of how to manage the vast volumes of data, wide variety and type of data generated, and erratic generation patterns is becoming increasingly clear and challenging. This Special Issue focuses on solving this problem through the use of edge computing. Edge computing offers a solution to managing IoT data through the processing of IoT data close to the location where the data is being generated. Edge computing allows computation to be performed locally, thus reducing the volume of data that needs to be transmitted to remote data centres and Cloud storage. It also allows decisions to be made locally without having to wait for Cloud servers to respond

Efficient Learning in Heterogeneous Internet of Things Ecosystems

The Internet of Things (IoT) is a growing network of heterogeneous devices, combining various sensing and computing nodes at different scales, which creates a large volume of data. Many IoT applications use machine learning (ML) algorithms to analyze the data. The high computational complexity of ML workloads poses significant computational challenges to IoT computing platforms, which tend to be less-powerful and resource-constrained devices. Transmitting such large volumes of data to the cloud also have various issues such as scalability, security and privacy. In this dissertation, we propose efficient solutions to perform the ML tasks while decreasing power consumption and improving performance. We first leverage the heterogeneous and interconnected nature of the IoT systems, where IoT applications run on many different architectures (e.g., X86 server or ARM-based edge device) while communicating with each other. We present a cross-platform power and performance prediction technique for intelligent task allocation. The proposed technique estimates the time-variant energy consumption with only 7% error across completely different architectures, enabling the intelligent task allocation that saves the energy consumption of 16.5% for state-of-the-art ML workloads.We next show how to further advance the learning procedures towards real-time and online processing by distributing such learning tasks onto the hierarchy of IoT devices. Our solution leverages brain-inspired high-dimensional (HD) computing to derive a new class oflearning algorithms that can easily run on IoT devices, while providing high accuracy comparable to the state-of-the-arts. We present that the HD-based learning algorithms can cover various real-world problems from conventional classification to other cognitive tasks beyond classical MLs such as DNA pattern matching. We demonstrate that the HD-based learning can enable secure, collaborative learning by efficiently distributing a large volume of learning tasks into heterogeneous computing nodes. We have implemented the proposed learning solution on various platforms while offering superior computing efficiency. For example, our solution achieves 486×and 7× performance improvements for each of the training and inference phases on a low-power ARM processor, as compared to state-of-the-art deep learning

NOMAD: Non-locking, stOchastic Multi-machine algorithm for Asynchronous and Decentralized matrix completion

We develop an efficient parallel distributed algorithm for matrix completion, named NOMAD (Non-locking, stOchastic Multi-machine algorithm for Asynchronous and Decentralized matrix completion). NOMAD is a decentralized algorithm with non-blocking communication between processors. One of the key features of NOMAD is that the ownership of a variable is asynchronously transferred between processors in a decentralized fashion. As a consequence it is a lock-free parallel algorithm. In spite of being an asynchronous algorithm, the variable updates of NOMAD are serializable, that is, there is an equivalent update ordering in a serial implementation. NOMAD outperforms synchronous algorithms which require explicit bulk synchronization after every iteration: our extensive empirical evaluation shows that not only does our algorithm perform well in distributed setting on commodity hardware, but also outperforms state-of-the-art algorithms on a HPC cluster both in multi-core and distributed memory settings

Vehicle as a Service (VaaS): Leverage Vehicles to Build Service Networks and Capabilities for Smart Cities

Smart cities demand resources for rich immersive sensing, ubiquitous communications, powerful computing, large storage, and high intelligence (SCCSI) to support various kinds of applications, such as public safety, connected and autonomous driving, smart and connected health, and smart living. At the same time, it is widely recognized that vehicles such as autonomous cars, equipped with significantly powerful SCCSI capabilities, will become ubiquitous in future smart cities. By observing the convergence of these two trends, this article advocates the use of vehicles to build a cost-effective service network, called the Vehicle as a Service (VaaS) paradigm, where vehicles empowered with SCCSI capability form a web of mobile servers and communicators to provide SCCSI services in smart cities. Towards this direction, we first examine the potential use cases in smart cities and possible upgrades required for the transition from traditional vehicular ad hoc networks (VANETs) to VaaS. Then, we will introduce the system architecture of the VaaS paradigm and discuss how it can provide SCCSI services in future smart cities, respectively. At last, we identify the open problems of this paradigm and future research directions, including architectural design, service provisioning, incentive design, and security & privacy. We expect that this paper paves the way towards developing a cost-effective and sustainable approach for building smart cities.Comment: 32 pages, 11 figure

Unleashing the Power of Edge-Cloud Generative AI in Mobile Networks: A Survey of AIGC Services

Artificial Intelligence-Generated Content (AIGC) is an automated method for generating, manipulating, and modifying valuable and diverse data using AI algorithms creatively. This survey paper focuses on the deployment of AIGC applications, e.g., ChatGPT and Dall-E, at mobile edge networks, namely mobile AIGC networks, that provide personalized and customized AIGC services in real time while maintaining user privacy. We begin by introducing the background and fundamentals of generative models and the lifecycle of AIGC services at mobile AIGC networks, which includes data collection, training, finetuning, inference, and product management. We then discuss the collaborative cloud-edge-mobile infrastructure and technologies required to support AIGC services and enable users to access AIGC at mobile edge networks. Furthermore, we explore AIGCdriven creative applications and use cases for mobile AIGC networks. Additionally, we discuss the implementation, security, and privacy challenges of deploying mobile AIGC networks. Finally, we highlight some future research directions and open issues for the full realization of mobile AIGC networks