Flocks, herds and schools: A distributed behavioral model
SIGGRAPH '87 Proceedings of the 14th annual conference on Computer graphics and interactive techniques
A new kind of science
Roadways, vehicle, and traffic applications: defining models of urban traffic using the TSC tool
Proceedings of the 33nd conference on Winter simulation
Theory of Modeling and Simulation
Theory of Modeling and Simulation
CD++: a toolkit to develop DEVS models
Software—Practice & Experience
A Flow Injection Model Using Cell-DEVS
SS '02 Proceedings of the 35th Annual Simulation Symposium
Methods for special applications: Cell-DEVS quantization techniques in a fire spreading application
Proceedings of the 34th conference on Winter simulation: exploring new frontiers
Design and Implementation of a Library of Network Protocols in CD++
ANSS '05 Proceedings of the 38th annual Symposium on Simulation
Partial-modular DEVS for improving performance of cellular space wildfire spread simulation
Proceedings of the 40th Conference on Winter Simulation
Towards a Formal Semantics of Event-Based Multi-agent Simulations
Multi-Agent-Based Simulation IX
Accelerating large-scale DEVS-based simulation on the cell processor
SpringSim '10 Proceedings of the 2010 Spring Simulation Multiconference
Integrating building information modeling & cell-DEVS simulation
SpringSim '10 Proceedings of the 2010 Spring Simulation Multiconference
Parallel discrete event simulation for DEVS cellular models using a GPU
Proceedings of the 2012 Symposium on High Performance Computing
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Cell-DEVS enables efficient execution of complex cellular models. The goal of Cell-DEVS is to build discrete-event cell spaces, improving their definition by making the timing specification more expressive. Different models built using Cell-DEVS were implemented in a modeling and simulation tool (CD++, crated following the formal specifications of the DEVS formalism). The applications range from biological systems to complex artificial systems. In this tutorial, we will introduce the main characteristics of Cell-DEVS, showing how to model complex cell spaces in an asynchronous environment. We will focus on the application of these techniques to improve model definition, which enables reducing development times of these models. We use a wide variety of previously defined examples in different domains of applications to illustrate the use of the techniques.