7 research outputs found
Handover in Mobile Wireless Communication Network - A Review
Mobility is the characteristics of mobile communication that makes it irresistible by all and sundry. The whole world is now engaging in wireless communication as it provides users\u27 ability to communicate on-the-go. This is achieved by transferring users from a radio network to another. This process is called handover. Handover occurs either by cell crossing or by deterioration in signal quality of the current channel. The continuation of an active call is a critical characteristic in cellular systems. Brief overview of handover, handover type, commonly used handover parameters, some methods employed in the literature and we present the convergent point for furtherance in the area of mobile wireless communication Handover
SATELLITE BASED DATA COMMUNICATION: A SURVEY
ABSTRACT Satellite communication is well known in providing best services where broadcasting is essential, where terrain is hostile and very sparsely populated. It also has niche where rapid deployment is very critical and important. In Global Network Infrastructure satellite is considered as an inseparable component of the communication infrastructure. A variety of research work has been explored and published for satellite based data communication & networking. It is utmost important to conduct a survey on different aspects and research issues of satellite based communication with a focus on the latest development. In this paper, we summarize, compare & comments on the approaches proposed for the satellite based data communication with keeping in view the parameters like Quality of service, Interplanetary Internet, Mobility management, explicit load balancing and packet reordering issue
A Novel Approach for Implementing Worldwide Interoperability for Microwave Access for Video Surveillance
Video surveillance applications have experienced an increase in demand over the last decade. Surveillance
systems can easily be found in places such as commercial offices, banks and traffic intersections, parks and
recreational areas. Surveillance applications have the potential to be implemented on a WiMAX (Worldwide
Interoperability for Microwave Access) network. Moreover, WiMAX devices have been used widely in the
market and WiMAX-based video surveillance products have also been available. As a radio technology,
WiMAX is a wireless broadband system that offers greater capacity than WiFi networks and wider coverage
than cellular networks.
The acceptance of WiMAX in the market, the availability of WiMAX products and its technology excellence,
contribute to the possibility of implementing it for surveillance application. However, since WiMAX is designed
to accommodate various applications with different quality of service (QoS) requirements, dedicated surveillance
network implementation of WiMAX may not achieve optimum performance, as all Subscriber Stations (SSs)
generate the same QoS requirements.
In the medium access (MAC) layer, this thesis proposes a bandwidth allocation scheme that considers the QoS
uniformity of the traffic sources. The proposed bandwidth allocation scheme comprises a simplified bandwidth
allocation architecture, a packet-aware bandwidth request mechanism and packet-aware scheduling algorithms.
The simplified architecture maximizes resources in the Base Station (BS), deactivates unnecessary services and
minimizes the processing delay. The proposed bandwidth request mechanism reduces bandwidth grant and
transmission delays. The proposed scheduling algorithms prioritize bandwidth granting access to a request that
contains important packet(s). The proposed methods in the MAC layer are designed to be applied to existing
devices in the market, without the necessity to change hardware.
The transport protocol should be able to deliver video with sufficient quality while maintaining low delay
connectivity. The proposed transport layer protocol is therefore designed to improve the existing user datagram
protocol (UDP) performance by retransmitting packet loss selectively to increase the received video quality, and
utilizing MAC support to achieve low delay connectivity.
In order to overcome the limitations of the lower layers, this thesis employs a rateless code instead of transport
layer redundancy in the application layer. Moreover, this thesis proposes post-decoding error concealment
techniques as the last means to overcome packet loss.
To evaluate the performances of the proposed methods, simulations are carried out using NS-2 simulator on
Linux platform. The proposed methods are compared to existing works to measure their effectiveness. To
facilitate the implementation of the transport layer protocols in practical scenarios, UDP packet modification is
applied for each transport layer protocol.Indonesian Directorate General of Higher Education (DGHE/DIKTI
Acesso banda larga sem fios em ambientes heterogéneos de próxima geração
Doutoramento em Engenharia InformáticaO acesso ubíquo à Internet é um dos principais desafios para os operadores
de telecomunicações na próxima década. O número de utilizadores da Internet
está a crescer exponencialmente e o paradigma de acesso "always connected,
anytime, anywhere" é um requisito fundamental para as redes móveis de
próxima geração. A tecnologia WiMAX, juntamente com o LTE, foi
recentemente reconhecida pelo ITU como uma das tecnologias de acesso
compatíveis com os requisitos do 4G. Ainda assim, esta tecnologia de acesso
não está completamente preparada para ambientes de próxima geração,
principalmente devido à falta de mecanismos de cross-layer para integração de
QoS e mobilidade. Adicionalmente, para além das tecnologias WiMAX e LTE,
as tecnologias de acesso rádio UMTS/HSPA e Wi-Fi continuarão a ter um
impacto significativo nas comunicações móveis durante os próximos anos.
Deste modo, é fundamental garantir a coexistência das várias tecnologias de
acesso rádio em termos de QoS e mobilidade, permitindo assim a entrega de
serviços multimédia de tempo real em redes móveis.
Para garantir a entrega de serviços multimédia a utilizadores WiMAX, esta
Tese propõe um gestor cross-layer WiMAX integrado com uma arquitectura de
QoS fim-a-fim. A arquitectura apresentada permite o controlo de QoS e a
comunicação bidireccional entre o sistema WiMAX e as entidades das
camadas superiores. Para além disso, o gestor de cross-layer proposto é
estendido com eventos e comandos genéricos e independentes da tecnologia
para optimizar os procedimentos de mobilidade em ambientes WiMAX. Foram
realizados testes para avaliar o desempenho dos procedimentos de QoS e
mobilidade da arquitectura WiMAX definida, demonstrando que esta é
perfeitamente capaz de entregar serviços de tempo real sem introduzir custos
excessivos na rede.
No seguimento das extensões de QoS e mobilidade apresentadas para a
tecnologia WiMAX, o âmbito desta Tese foi alargado para ambientes de
acesso sem-fios heterogéneos. Neste sentido, é proposta uma arquitectura de
mobilidade transparente com suporte de QoS para redes de acesso multitecnologia.
A arquitectura apresentada integra uma versão estendida do IEEE
802.21 com suporte de QoS, bem como um gestor de mobilidade avançado
integrado com os protocolos de gestão de mobilidade do nível IP. Finalmente,
para completar o trabalho desenvolvido no âmbito desta Tese, é proposta uma
extensão aos procedimentos de decisão de mobilidade em ambientes
heterogéneos para incorporar a informação de contexto da rede e do terminal.
Para validar e avaliar as optimizações propostas, foram desenvolvidos testes
de desempenho num demonstrador inter-tecnologia, composta pelas redes de
acesso WiMAX, Wi-Fi e UMTS/HSPA.Ubiquitous Internet access is one of the main challenges for the
telecommunications industry in the next decade. The number of users
accessing the Internet is growing exponentially and the network access
paradigm of “always connected, anytime, anywhere” is a central requirement
for the so-called Next Generation Mobile Networks (NGMN). WiMAX, together
with LTE, was recently recognized by ITU as one of the compliant access
technologies for 4G. Nevertheless, WiMAX is not yet fully prepared for next
generation environments, mainly due to the lack of QoS and mobility crosslayer
procedures to support real-time multimedia services delivery.
Furthermore, besides the 4G compliant WiMAX and LTE radio access
technologies, UMTS/HSPA and Wi-Fi will also have a significant impact in the
mobile communications during the next years. Therefore, it is fundamental to
ensure the coexistence of multiple radio access technologies in what QoS and
mobility procedures are concerned, thereby allowing the delivery of real-time
services in mobile networks.
In order to provide the WiMAX mobile users with the demanded multimedia
services, it is proposed in this Thesis a WiMAX cross-layer manager integrated
in an end-to-end all-IP QoS enabled architecture. The presented framework
enables the QoS control and bidirectional communication between WiMAX and
the upper layer network entities. Furthermore, the proposed cross-layer
framework is extended with media independent events and commands to
optimize the mobility procedures in WiMAX environments. Tests were made to
evaluate the QoS and mobility performance of the defined architecture,
demonstrating that it is perfectly capable of handling and supporting real time
services without introducing an excessive cost in the network.
Following the QoS and mobility extensions provided for WiMAX, the scope of
this Thesis is broaden and a seamless mobility architecture with QoS support in
heterogeneous wireless access environments is proposed. The presented
architecture integrates an extended version of the IEEE 802.21 framework with
QoS support, as well as an advanced mobility manager integrated with the IP
level mobility management protocols. Finally, to complete the work within the
framework of this Thesis, it is proposed an extension to the handover decisionmaking
processes in heterogeneous access environments through the
integration of context information from both the network entities and the enduser.
Performance tests were developed in a real testbed to validate the
proposed optimizations in an inter-technology handover scenario involving
WiMAX, Wi-Fi and UMTS/HSPA