Information Technology Reference
In-Depth Information
a.
0123456789001234567890012345678012345678
**?b?aa
4701
+/Q?ba?
8536
*0Q-10010/Q-+01111
C = {0.664, 1.703, 1.958, 1.178, 1.258, 2.903, 2.677, 1.761, 0.923, 0.796}
C = {0.588, 2.114, 0.510, 2.359, 1.355, 0.186, 0.070, 2.620, 2.374, 1.710}
0
1
b.
ADF
0
ADF
1
Q
/
1.258
a
b
b
1.761
2.374
c.
Cell
0
Cell
1
/
ADF
0
Q
Q
ADF
0
ADF
1
ADF
1
ADF
0
ADF
1
ADF
1
Figure 6.12.
Expression of a multicellular program with ADFs containing random
numerical constants.
a)
The genome of the individual with two homeotic genes and
two normal genes plus their arrays of random numerical constants (the Dc's are
shown in bold).
b)
The ADFs encoded by each normal gene.
c)
Two different
programs expressed in two different cells.
role in the design of this particular circuit, we are also going to analyze the
performance of the simpler cellular system without RNCs on this problem in
order to compare it with the performance of the cellular system with RNCs
(see Table 6.6 for the complete list of the parameters used per run in both
experiments).
And as expected, the cellular system with RNCs performs considerably
better than the simpler cellular system without RNCs at this task (average
best-of-run fitness of 31.4709 against 13.6953). And taking into account the
considerable increase in complexity, it is not surprising that the cellular
