Abstract
This paper proposes: 1) a traffic flow management policy, which allocates and organizes machine type communication (MTC) traffic flows network resources sharing within evolved packet system (EPS); 2) an access element as a wireless sensor network gateway for providing an overlaying access channel between the machine type devices and EPS; and 3) it addresses the effect and interaction in the heterogeneity of applications, services and terminal devices, and the related quality of service (QoS) issues among them. This paper overcomes the problems of network resource starvation by preventing deterioration of network performance. The scheme is validated through simulation, which indicates the proposed traffic flow management policy outperforms the current traffic management policy. Specifically, simulation results show that the proposed model achieves an enhancement in QoS performance for the MTC traffic flows, including a decrease of 99.45% in packet loss rate (PLR), a decrease of 99.89% in packet end to end (E2E) delay, a decrease of 99.21% in packet delay variation (PDV). Furthermore, it retains the perceived quality of experience of the real time application users within high satisfaction levels, such as the voice over long term evolution service possessing a mean opinion score (MOS) of 4.349 and enhancing the QoS of a video conference service within the standardized values of a 3GPP body, with a decrease of 85.28% in PLR, a decrease of 85% in packet E2E delay and a decrease of 88.5% in PDV.
Highlights
AND RELATED WORKM TC introduces the concept of enabling networked devices, electronic devices, dubbed machine type communication (MTC) devices and/or communication from MTC devices to a central MTC server or a set of MTC servers, for exchanging data or control without human interference
End device applications service request and call setup supports the use of session initiation protocol (SIP), which is configured among the UEs, WSN gateways, applications servers, and IP and multimedia subsystem (IMS) server
This paper has addressed the challenges of heterogeneity by integrating human type communication (HTC) and Internet of Things (IoT) traffic through their mutual interaction within network elements, in terms of the resultant and distinct E2E network QoS (NQoS) metrics
Summary
AND RELATED WORKM TC (or M2M communication) introduces the concept of enabling networked devices (wireless and/or wired), electronic devices, dubbed MTC devices and/or communication from MTC devices to a central MTC server or a set of MTC servers, for exchanging data or control without human interference. MTC developments are driven by the unlimited potential of IoT everyday applications, as a result from the connected objects to grow more intelligent. These applications presented in the form of smart grids, healthcare systems, smart cities, building automation, and many other. MTC terminals or SN can communicate with one or many servers and their traffic characteristics have been discussed in detail in [17] They can be considered as data centric communication for sending constant size packets toward server [18], [19]. This can be transferred at a specific data rate, which matches the applications needs
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
