Tokyo/Model
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==== To establish a system following Pareto’s principle, the system must satisfy the following three cases. In our model, all nodes have the same genetic circuits and take two states, A (worker) and B (idler), depending on the surrounding circumstances. ==== | ==== To establish a system following Pareto’s principle, the system must satisfy the following three cases. In our model, all nodes have the same genetic circuits and take two states, A (worker) and B (idler), depending on the surrounding circumstances. ==== | ||
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<br>In an unstable state, some node B become A while the others remain B. The system then becomes stable again. | <br>In an unstable state, some node B become A while the others remain B. The system then becomes stable again. | ||
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Revision as of 06:43, 20 October 2007
To establish a system following Pareto’s principle, the system must satisfy the following three cases. In our model, all nodes have the same genetic circuits and take two states, A (worker) and B (idler), depending on the surrounding circumstances.
Condition 1. Bistable state
The system is stable containing nodes A and B at certain ratio.
Condition 2. Unstable state with node A removed
Removed of node A, the system contains only node B and becomes unstable. Node B detects the removal of node A from the system and knows that there is only node B left.
Condition 3. From unstable to stable state
In an unstable state, some node B become A while the others remain B. The system then becomes stable again.
