AbstractThe Shape Calculus is a bio-inspired timed and spatial calculus for describing 3D geometrical shapes moving in a space. Shapes, combined with a behaviour, form 3D processes, i.e., individual entities able to bind with other processes on compatible spatial channels and to split over previously established bonds. Due to geometrical space, timed behaviours, a wide degree of freedom in defining motion laws and usual nondeterminism, 3D processes typically exhibits an infinite behaviour that prevents any decidable analysis. Shape Calculus models are currently used only for simulation and, thus, validation of models and hypothesis testing. In this work we introduce a complementary, and synergetic, way of using the calculus for systems biol...
BioShape [1, 2] is a uniform, particle-based, 3D space- and geometry-oriented multiscale modelling a...
In recent years formal methods from concurrency theory and process calculi have gained increasing im...
AbstractWe design BioScape, a concurrent language for the stochastic simulation of biological and bi...
The Shape Calculus is a bio-inspired timed and spatial calculus for describing 3D geometrical shapes...
AbstractThe Shape Calculus is a bio-inspired timed and spatial calculus for describing 3D geometrica...
We present a bio-inspired calculus for describing 3D shapes moving in a space. A shape forms a 3D pr...
The Shape Calculus is a bio-inspired calculus for describing 3D shapes moving in a space. A shape fo...
Extended version, including proofs, of Bartocci, E.; Cacciagrano, D. R.; Di Berardini, M. R.; Merell...
Abstract. We introduce the main concepts of a bio-inspired calculus for describing 3D shapes moving ...
The Shape Calculus is a bio-inspired calculus for describing 3D shapes moving in a space. A shape fo...
We introduce the main concepts of a bio-inspired calculus for describing 3D shapes moving in a space...
The Shape Calculus is a bio-inspired timed and spatial calculus for describing 3D geometrical shapes...
AbstractSpatial dynamics receive increasing attention in Systems Biology and require suitable modeli...
BioShape [1, 2] is a uniform, particle-based, 3D space- and geometry-oriented multiscale modelling a...
In recent years formal methods from concurrency theory and process calculi have gained increasing im...
AbstractWe design BioScape, a concurrent language for the stochastic simulation of biological and bi...
The Shape Calculus is a bio-inspired timed and spatial calculus for describing 3D geometrical shapes...
AbstractThe Shape Calculus is a bio-inspired timed and spatial calculus for describing 3D geometrica...
We present a bio-inspired calculus for describing 3D shapes moving in a space. A shape forms a 3D pr...
The Shape Calculus is a bio-inspired calculus for describing 3D shapes moving in a space. A shape fo...
Extended version, including proofs, of Bartocci, E.; Cacciagrano, D. R.; Di Berardini, M. R.; Merell...
Abstract. We introduce the main concepts of a bio-inspired calculus for describing 3D shapes moving ...
The Shape Calculus is a bio-inspired calculus for describing 3D shapes moving in a space. A shape fo...
We introduce the main concepts of a bio-inspired calculus for describing 3D shapes moving in a space...
The Shape Calculus is a bio-inspired timed and spatial calculus for describing 3D geometrical shapes...
AbstractSpatial dynamics receive increasing attention in Systems Biology and require suitable modeli...
BioShape [1, 2] is a uniform, particle-based, 3D space- and geometry-oriented multiscale modelling a...
In recent years formal methods from concurrency theory and process calculi have gained increasing im...
AbstractWe design BioScape, a concurrent language for the stochastic simulation of biological and bi...