Effective Radio Resource Management for MBMS in UMTS Networks
Wireless Personal Communications: An International Journal
Power saving techniques in mbms multicast mode
Proceedings of the 3rd ACM workshop on Wireless multimedia networking and performance modeling
MBMS Handover control: A new approach for efficient handover in MBMS enabled 3G cellular networks
Computer Networks: The International Journal of Computer and Telecommunications Networking
Efficient TTI for 3G multimedia applications
Advances in Multimedia
A novel mechanism for radio capacity maximization during MBMS transmissions in B3G networks
Proceedings of the 11th international symposium on Modeling, analysis and simulation of wireless and mobile systems
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As currently specified by 3GPP, Multimedia Broadcast Multicast Service (MBMS) bearer services can be provided within a cell either by Point-to-Point (P-t-P) or Point-to-Multipoint (P-t-M) transmission mode, but not both at the same time. If P-t-P transmission mode is selected for a cell, one Dedicated Channel (DCH) is established for each user within the cell that joined the MBMS service. Otherwise, if P-t-M transmission mode is selected, one Forward Access Channel (FACH) is established covering the whole cell's area and commonly shared by all the UEs within. In this paper, we highlight the inefficiencies that can be caused with the aforementioned approach and introduce the ''Dual Transmission mode cell'' in which P-t-P and P-t-M transmissions (i.e. multiple DCHs and FACH) are allowed to coexist within the same cell. Hence, we propose a new radio resource allocation algorithm and solution to address them. Our proposed algorithm considers the instantaneous distribution and movement of the users within the cell and dynamically decides which users will use FACH and which DCH, in such a way that the requested Quality of Service (QoS) is supported with the least amount of transmission power (i.e. capacity) consumption. Moreover, with the ''Dual Transmission mode cell'', new types of intra-cell handovers are introduced which we also analyse and propose a new handover algorithm to address them. The performance evaluation carried out showed that our proposed ''Dual Transmission mode cell'' approach, provides considerable gains, as well as outperforming all other related approaches, such as ''UE Counting'', ''Power Counting'', ''Rate Splitting'', and ''FACH with dynamic power setting'', in terms of capacity and link performance efficiency.