The X-Kernel: An Architecture for Implementing Network Protocols
IEEE Transactions on Software Engineering
A unifying framework for distributed simulation
ACM Transactions on Modeling and Computer Simulation (TOMACS) - Special issue on parallel and distributed systems performance
Mobile wireless network system simulation
MobiCom '95 Proceedings of the 1st annual international conference on Mobile computing and networking
Transparent implementation of conservative algorithms in parallel simulation languages
WSC '93 Proceedings of the 25th conference on Winter simulation
Multicluster, mobile, multimedia radio network
Wireless Networks
Maisie: A Language for the Design of Efficient Discrete-Event Simulations
IEEE Transactions on Software Engineering
Parallel simulation environment for mobile wireless networks
WSC '96 Proceedings of the 28th conference on Winter simulation
Mobile wireless network system simulation
Wireless Networks
WiPPET, a virtual testbed for parallel simulations of wireless networks
PADS '98 Proceedings of the twelfth workshop on Parallel and distributed simulation
Applying a modified Chandy-Misra algorithm to the distributed simulation of a cellular network
PADS '98 Proceedings of the twelfth workshop on Parallel and distributed simulation
Network simulations with OPNET
Proceedings of the 31st conference on Winter simulation: Simulation---a bridge to the future - Volume 1
Partitioning WCN models for parallel simulation of radio resource management
Wireless Networks - Special issue: Design and modeling in mobile and wireless systsems
Message ring-based channel reallocation for cellular wireless networks
Computer Communications
Hi-index | 0.00 |
A hierarchical simulator has been designed for multimedia communication protocols in a wireless mobile environment. The hierarchical approach integrates performance evaluation of protocols with their implementation. The approach supports scalability studies of the protocols in an efficient manner using coarse grain models that abstract implementation details of the protocol and its execution environment by a few key parameters. Fine grain, low level models that capture implementation details are used for detailed evaluation of small networks and for automatic implementation on radio platforms. The design, evaluation, and implementation cycle is closed by feeding the measurements from the implementation back into the model to improve its accuracy. The paper describes the use of the environment in the evaluation and implementation of a cluster based multihop protocol for multimedia traffic.