ACM Transactions on Programming Languages and Systems (TOPLAS)
Parallel discrete event simulation
Communications of the ACM - Special issue on simulation
An evaluation of the Chandy-Misra-Bryant algorithm for digital logic simulation
ACM Transactions on Modeling and Computer Simulation (TOMACS) - Special issue on parallel and distributed systems performance
Efficient algorithms for distributed snapshots and global virtual time approximation
Journal of Parallel and Distributed Computing - Special issue on parallel and discrete event simulation
Behavioral simulation for analog system design verification
IEEE Transactions on Very Large Scale Integration (VLSI) Systems
Mixed-Mode Simulation and Analog Multilevel Simulation
Mixed-Mode Simulation and Analog Multilevel Simulation
Formal Specification and Verification of the pGVT Algorithm
FME '96 Proceedings of the Third International Symposium of Formal Methods Europe on Industrial Benefit and Advances in Formal Methods
WARPED: A Time Warp Simulation Kernel for Analysis and Application Development
HICSS '96 Proceedings of the 29th Hawaii International Conference on System Sciences Volume 1: Software Technology and Architecture
Dynamically switching between lazy and aggressive cancellation in a Time Warp parallel simulator
SS '95 Proceedings of the 28th Annual Simulation Symposium
Analysis of performance and convergence issues for circuit simulation
Analysis of performance and convergence issues for circuit simulation
Generalized Discrete Event Abstraction of Continuous Systems: Application to an Integrator
Journal of Intelligent and Robotic Systems
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Mixed-Mode simulation has been generating considerable interest in the simulation community and has continued to grow as an active research area. Traditional mixed-mode simulation involves the merging of digital and analog simulators in various ways. However, efficient methods for the synchronization between the two time domains remains elusive. This is due to the fact that the analog simulator uses dynamic time step control whereas the digital simulator uses the event driven paradigm. This paper proposes two new synchronization methods and presents their capabilities using a component-based continuous-time simulator integrated with an optimistic parallel discrete event simulator. The results of the performance evaluation leads us to believe that while both synchronization methods are functionally viable, one has superior performance.