Soft Handoff in MC-CDMA Cellular Networks Supporting Multimedia Services

An adaptive resource reservation and handoff priority scheme, which jointly considers the characteristics from the physical, link and network layers, is proposed for a packet switching Multicode (MC)-CDMA cellular network supporting multimedia applications. A call admission region is derived for call admission control (CAC) and handoff management with the satisfaction of quality of service (QoS) requirements for all kinds of multimedia traffic, where the QoS parameters include the wireless transmission bit error rate (BER), the packet loss rate (PLR) and delay requirement. The BER requirement is guaranteed by properly arranging simultaneous packet transmissions, whereas the PLR and delay requirements are guaranteed by the proposed packet scheduling and partial packet integration scheme. To give service priority to handoff calls, a threshold-based adaptive resource reservation scheme is proposed on the basis of a practical user mobility model and a proper handoff request prediction scheme. The resource reservation scheme gives handoff calls a higher admission priority over new calls, and is designed to adjust the reservation-request time threshold adaptively according to the varying traffic load. The individual reservation requests form a common reservation pool, and handoff calls are served on a first-come-first-serve basis. By exploiting the transmission rate adaptability of video calls to the available radio resources, the resources freed from rate-adaptive high-quality video calls by service degradation can be further used to prioritize handoff calls. With the proposed resource reservation and handoff priority scheme, the dynamic properties of the system can be closely captured and a better grade of service (GoS) in terms of new call blocking and handoff call dropping probabilities(rates) can be achieved compared to other schemes in literature. Numerical results are presented to show the improvement of the GoS performance and the efficient utilization of the radio resources

Accepting the challenges of IP-based UMTS radio access network evolution scenarios

The tendency in future mobile Radio Access Networks (RANs) consists in an increase of new and Internet Protocol (IP)-based services with strict requirements regarding bandwidth and Quality of Service (QoS) and in a dominance of packet data traffic in future mobile networks. Existing mobile networks (e.g. Universal Mobile Telecommunications System (UMTS) Release 99 (R99)), which are designed assuming a predominance of circuit switched traffic, are not suitable to efficiently carry IP traffic under consideration of the hierarchical and centralistic network structure of existing mobile networks, the coupling of user and control plane and the strict delay requirements in the RAN. Consequently, an architecture evolution of mobile RANs with regard to their network architecture has to take place. Within the cooperation of Lucent Technologies and the University of Duisburg-Essen in the project IPonAir, funded by the German Ministry for Education and Research (Bundesministerium für Bildung und Forschung (BMBF)), and within the work carried out for this thesis, a flexible, efficient and toolsupported approach was developed that allows for an evaluation of future mobile RANs with regard to signaling performance. This approach provides decision support to the designer of future mobile networks in a very early design phase. The evaluation approach comprises a methodology for eventdriven simulation of signaling sequences, depicted in the form of Message Sequence Charts (MSCs), as well as a toolkit – both, i.e. the simulation methodology as well as the toolkit, enable an optimization as well as an assessment of future mobile RANs with regard to signaling performance as well as a comparison with the UMTS R99 as a reference architecture. In the thesis on hand, the above mentioned evaluation approach is presented in detail. Moreover, the approach is applied to potential evolution scenarios of mobile RANs. On the one hand these RAN evolution scenarios are optimized with regard to signaling performance. On the other hand the RAN evolution scenarios are compared to the UMTS R99 reference architecture with regard to their signaling performance behavior