AbstractWe present two individual based models of disease systems using PEPA (Performance Evaluation Process Algebra). The models explore contrasting mechanisms of disease transmission: direct transmission (e.g. measles) and indirect transmission (e.g. malaria, via mosquitos). We extract ordinary differential equations (ODEs) as a continuous approximation to the PEPA models using the Hillston method and compare these with the traditionally used ODE disease models and with the results of stochastic simulation. Improvements to the Hillston method of ODE extraction for this context are proposed, and the new results compare favourably with stochastic simulation results and to ODEs derived for equivalent models in WSCCS (Weighted Synchronous Cal...
In this paper we show how the powerful ODE-based fluid-analysis technique for the stochastic process...
The performance modelling of large-scale systems using discrete-state approaches is fundamentally h...
Is it possible to symbolically express and analyse an individual-based model of disease spread, incl...
We present two individual based models of disease systems using PEPA (Performance Evaluation Process...
Modelling is a powerful method for understanding complex systems, which works by simplifying them to...
AbstractMany models have been defined in order to describe the evolution of a disease in a populatio...
We demonstrate the use of the process algebra PEPA for realistic models of epidemiology. The results...
Changing scale, for example the ability to move seamlessly from an individual-based model to a popul...
We present preliminary work on modelling aspects of the immune system using process algebra. The pro...
Is it possible to symbolically express and analyse an individual-based model of disease spread, incl...
Stochastic process algebras such as PEPA have enjoyed considerable success as CTMC-based system desc...
The problem of changing scale in models of a system is relevant in many different fields. In this th...
Changing scale, for example, the ability to move seamlessly from an individual-based model to a popu...
It is well understood that populations cannot grow without bound and that it is competition between ...
Process algebras are an effective method for defining models of complex interacting biological proce...
In this paper we show how the powerful ODE-based fluid-analysis technique for the stochastic process...
The performance modelling of large-scale systems using discrete-state approaches is fundamentally h...
Is it possible to symbolically express and analyse an individual-based model of disease spread, incl...
We present two individual based models of disease systems using PEPA (Performance Evaluation Process...
Modelling is a powerful method for understanding complex systems, which works by simplifying them to...
AbstractMany models have been defined in order to describe the evolution of a disease in a populatio...
We demonstrate the use of the process algebra PEPA for realistic models of epidemiology. The results...
Changing scale, for example the ability to move seamlessly from an individual-based model to a popul...
We present preliminary work on modelling aspects of the immune system using process algebra. The pro...
Is it possible to symbolically express and analyse an individual-based model of disease spread, incl...
Stochastic process algebras such as PEPA have enjoyed considerable success as CTMC-based system desc...
The problem of changing scale in models of a system is relevant in many different fields. In this th...
Changing scale, for example, the ability to move seamlessly from an individual-based model to a popu...
It is well understood that populations cannot grow without bound and that it is competition between ...
Process algebras are an effective method for defining models of complex interacting biological proce...
In this paper we show how the powerful ODE-based fluid-analysis technique for the stochastic process...
The performance modelling of large-scale systems using discrete-state approaches is fundamentally h...
Is it possible to symbolically express and analyse an individual-based model of disease spread, incl...