Tokyo/Model
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<br>Fig. 1 The system is stable when it contains both A (worker) and B (idler) at certain ratio. | <br>Fig. 1 The system is stable when it contains both A (worker) and B (idler) at certain ratio. | ||
| - | '''Condition 2. | + | '''Condition 2. The removal of A (worker)'''まだ「node」が残っている! |
[[Image:model2.jpg]] | [[Image:model2.jpg]] | ||
| - | <br>Fig. 2 By removal of A (worker), the system | + | <br>Fig. 2 By removal of A (worker), "stable coexistence" of the system is broken. <!--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''' | '''Condition 3. From unstable to stable state''' | ||
[[Image:model3.jpg]] | [[Image:model3.jpg]] | ||
| - | <br>Fig. 3 | + | <br>Fig. 3 Some B (idler) changes to A (worker) while the others remain B (idler). Then the system regains "stable coexistence". |
<!--[[Image:concepts.jpg]]--> | <!--[[Image:concepts.jpg]]--> | ||
Revision as of 08:33, 25 October 2007
Abstract Concept & Model Requirements Genetic_circuit Works About_our_team
E.coli Follow Pareto's principle!
To follow Pareto’s principle like an ant society, our model system must follow the three conditions shown in Fig. 1 to 3. In our model, all nodes (individual cells) have the same genetic circuits but take two states, A (worker) and B (idler), depending on the surrounding circumstances.
Condition 1. Bistable state
Fig. 1 The system is stable when it contains both A (worker) and B (idler) at certain ratio.
Condition 2. The removal of A (worker)まだ「node」が残っている!
Fig. 2 By removal of A (worker), "stable coexistence" of the system is broken.
Condition 3. From unstable to stable state
Fig. 3 Some B (idler) changes to A (worker) while the others remain B (idler). Then the system regains "stable coexistence".
