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Julien Mazars edited this page Jan 15, 2016 · 14 revisions

Mirror species

A mirror species is a species whose population is automatically managed with respect to another species. Whenever an agent is created or destroyed from the other species, an instance of the mirror species is created or destroyed. Each of these 'mirror agents' has access to its reference agent (called its target). Mirror species can be used in different situations but the one we describe here is more oriented towards visualization purposes.

Index

Declaration

A mirror species can be defined using the mirrors keyword as following:

species B mirrors: A{
}

In this case the species B mirrors the species A. By default the location of the species B will be random but in many cases, once want to place the mirror agent at the same location of the reference species. This can be achieve by simply adding the following lines in the mirror species

species B mirrors: A{
    point location <- target.location update: target.location;
}

In the same spirit any attribute of a reference species can be reach using the same syntax. For instance if the species A has an attribute called attribute1 of type int is is possible to get this attribute from the mirror species B using the following syntax:

int value <- target.attribute1;

Example

To practice a bit with the mirror notion, we will now build a simple model displaying a species A (aspect: white circle) moving randomly, and another species B (aspect: blue sphere) with the species A location on x and y, with an upper value for the z axis.

images/mirror_model.png

Here is an example of implementation for this model:

model Mirror

global {
  init{
    create A number:100;    
  }
}

species A skills:[moving]{
    reflex update{
        do wander;
    }
    aspect base{
        draw circle(1) color: #white;
    }
}
species B mirrors: A{
    point location <- target.location update: point(target.location.x,target.location.y,target.location.z+5);
    aspect base {
        draw sphere(2) color: #blue;
    }
}

experiment mirroExp type: gui {
    output {
        display superposedView type: opengl{ 
          species A aspect: base;
          species B aspect: base transparency:0.5;
        }
    }
}

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