Theory of Modeling and Simulation
Theory of Modeling and Simulation
CD++: a toolkit to develop DEVS models
Software—Practice & Experience
Principles of Object-Oriented Modeling and Simulation with Modelica 2.1
Principles of Object-Oriented Modeling and Simulation with Modelica 2.1
Optical solutions for system-level interconnect
Proceedings of the 2004 international workshop on System level interconnect prediction
Design and Behavioral Modeling Tools for Optical Network-on-Chip
Proceedings of the conference on Design, automation and test in Europe - Volume 1
A VHDL-AMS library of hierarchical optoelectronic device models
Languages for system specification
Heterogeneous Modelling of an Optical Network-on-Chip with SystemC
RSP '05 Proceedings of the 16th IEEE International Workshop on Rapid System Prototyping
Continuous System Simulation
On the Design of a Photonic Network-on-Chip
NOCS '07 Proceedings of the First International Symposium on Networks-on-Chip
System level assessment of an optical NoC in an MPSoC platform
Proceedings of the conference on Design, automation and test in Europe
Design of Integrated Circuits for Optical Communications
Design of Integrated Circuits for Optical Communications
Integrating Parallel DEVS and equation-based object-oriented modeling
SpringSim '10 Proceedings of the 2010 Spring Simulation Multiconference
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We discuss two implementations of opto-electrical interfaces, their characteristics and functionalities using a hybrid M&S approach. These interfaces consist in a transmitter and a receiver, composed by electrical and optical parts, that translate electrical signals into optical impulses and viceversa. The first implementation, performed using the CD++ modeling environment, represents a discrete-event model of the system following the DEVS formalism. The other implementation uses the Modelica Standard Library to compose the electrical parts as a continuous-time model, and the Modelica DEVSLib library to describe the optical part as a discrete-event system. The obtained simulation results are equivalent in both implementations. They reproduce translation of a continuous-time sinusoid electrical signal into discrete optical impulses in the transmitter, and the opposite process in the receiver. These approaches simplify the development of multidomain hybrid systems and the study of ONoC at a high abstraction level.