Zhu Han

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Archive | 2015

Lingyang Song; Dusit Niyato; Zhu Han; Ekram Hossain

Modern day’s vehicles require advanced communication system on board to enable passengers benefit the most from available services. IEEE 802.11p is the new extension of IEEE 802.11 standards; especially proposed for the high vehicular environment. The WAVE documentation represents enhancements to the Media Access Control (MAC) and Physical (PHY) layer of IEEE 802.11 standards to work efficiently in high vehicular environment. In this research work, the main emphasis is on the new IEEE 802.11p enhancement of MAC and PHY layers. More specifically, the target of this research is to setup a simulation environment which will allow us to investigate the use of real time voice application, using IEEE 802.11p (WAVE) enhance setting, in a single hop and multi-hop environment where nodes are not directly connected. Also, the evaluation of transmission between moving nodes are tested by simply sending and receiving FTP file between them with varying speed of the moving nodes.

Archive | 2015

Lingyang Song; Dusit Niyato; Zhu Han; Ekram Hossain

Introduction Wireless connectivity is rapidly expanding beyond traditional mobile devices used by humans. In the near future, many wireless devices (e.g., sensors and actuators) will be connected in the framework of the Internet-of-Things (IoT) [363]. In cellular networks, hundreds or thousands of devices can exist in one cell. Therefore, the concept of machine-to-machine (M2M) communications has been introduced to handle the transmission of a number of devices in the network. M2M communication, also known as machine-type communications (MTC), refers to mobile nodes communicating over a network without (or with minimal) human intervention. M2M communication enables ubiquitous connectivity among autonomous devices and/or Internet connectivity of MTC devices (i.e., communications between an MTC device and an M2M server or between two MTC devices). M2M communication is different from human-to-human (H2H) communication, which mainly involves voice calls, messaging, and web browsing. The goal of M2M communications is to increase the level of system automation by allowing the devices and systems to exchange and share data. Therefore, the protocol and data format are the major issues in M2M communications owing to the need to ensure seamless data and control flows. D2D communication can be considered as a type of M2M communication when the D2D user equipments UEs are in close proximity and have small amounts of data to transmit among themselves (e.g., in application scenarios relating to the control of appliances in the home). In this chapter, we provide an overview of M2M communications in Section 11.2. Specifically, we focus on MTC in Long Term Evolution (LTE) and LTE-Advanced (LTE-A). Section 11.3 presents the mechanisms to support MTC, i.e., a random-access (RA) procedure and random-access-channel (RACH)-overload control mechanisms. Section 11.4 introduces a performance-modeling technique based on queueing theory to analyze the performance of the RA mechanism for M2M communications. Finally, Section 11.5 gives a summary of the chapter and lists some important research directions. Machine-to-machine (M2M) communications M2M communication, which is undergoing the process of standardization by the Third Generation Partnership Project (3GPP), can support a wide range of applications (e.g., secured access and surveillance, metering and smart grid, and Internet-of-Things).

Archive | 2015

Lingyang Song; Dusit Niyato; Zhu Han; Ekram Hossain

As one of the next-generation wireless communication systems, the Third Generation Partnership Project (3GPP) Long Term Evolution (LTE) is committed to providing technologies for high data rates and system capacity. Further, LTE-Advanced (LTE-A) was defined to support new components for LTE to meet higher communication demands [1]. In particular, the performance and quality of service (QoS) of local area services need to be improved significantly by reusing the spectrum resources. However, reuse of the unlicensed spectrum might not provide a stable controlled environment [2]. Therefore, the approach of exploiting the licensed spectrum for local area services has attracted much attention. In this chapter, we present the basic concepts of device-to-device (D2D) communications in the licensed spectrum bands. We first provide an overview of D2D communications underlaying the cellular network. We then discuss access methods, device synchronization, and discovery mechanisms. Next, mode selection, spectrum sharing, power control, and multiple-input-multiple-output (MIMO) techniques are briefly introduced. The concepts of D2D direct and D2D local area networks (LANs) are proposed, a simulation scenario for D2D direct is given as an example, and, finally, the issues and challenges in D2D communications are outlined. Overview of D2D communications The term D2D communications commonly refers to the techniques that enable devices to communicate directly without an infrastructure of access points or base stations. D2D communications amount to a technology component for LTE-A, where user equipments (UEs) transmit data signals to each other over a direct link/connection using the cellular resources instead of through the eNB (i.e., a base station). As an underlay to the cellular network, D2D communications allow one to increase the spectral efficiency [1, 3, 4, 5, 6, 7, 8, 9]. While D2D communications is considered as an add-on component in the 4G systems, it is expected to be a native feature supported by the next-generation (e.g., fifth-generation [5G]) cellular networks.

Archive | 2012