GPSR: greedy perimeter stateless routing for wireless networks
MobiCom '00 Proceedings of the 6th annual international conference on Mobile computing and networking
Ad-hoc On-Demand Distance Vector Routing
WMCSA '99 Proceedings of the Second IEEE Workshop on Mobile Computer Systems and Applications
Ad Hoc Wireless Networks
Common Gateway Architecture for Mobile Ad-Hoc Networks
WONS '05 Proceedings of the Second Annual Conference on Wireless On-demand Network Systems and Services
Multi-hop delay performance in wireless mesh networks
Mobile Networks and Applications
Distributed potential field based routing and autonomous load balancing for wireless mesh networks
IEEE Communications Letters
A collision-free MAC scheme for multimedia wireless mesh backbone
IEEE Transactions on Wireless Communications
A novel routing algorithm in distributed IEEE 802.16 mesh networks
IEEE Communications Letters
Wireless LAN design alternatives
IEEE Network: The Magazine of Global Internetworking
| Hi-index | 0.00 |
Wide band mesh or star oriented networks have recently become a subject of greater interest. Providing wideband multimedia access for a variety of applications has led to the inception of mesh networks. Classic access techniques such as FDMA and TDMA have been the norm for such networks. CDMA maximum transmitter power is much less than TDMA and FDMA counter parts, which is an important asset for mobile operation. In this paper we introduce a code division multiple access/time division duplex technique CDMA/TDD for such networks. The CDMA approach is an almost play and plug technology for wireless access, making it amenable for implementation by the mesh network service station, SS. Further it inherently allows mesh network service stations to use a combination of turbo coding and dynamic parallel orthogonal transmission to improve network efficiency. We outline briefly the new transmitter and receiver structures then evaluate the efficiency, delay and delay jitter. By analysis we show the advantages over classic counter parts with respect to the total network efficiency achievable especially for larger number of hops.