theorem
for
n1,
n2,
n3,
n4,
n5 being
Element of
NAT for
S being
Gene-Set for
p1,
p2 being
Individual of
S holds
( (
n1 >= len p1 &
n2 >= len p1 &
n3 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n4,
n5) ) & (
n1 >= len p1 &
n2 >= len p1 &
n4 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n3,
n5) ) & (
n1 >= len p1 &
n2 >= len p1 &
n5 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n3,
n4) ) & (
n1 >= len p1 &
n3 >= len p1 &
n4 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n2,
n5) ) & (
n1 >= len p1 &
n3 >= len p1 &
n5 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n2,
n4) ) & (
n1 >= len p1 &
n4 >= len p1 &
n5 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n2,
n3) ) & (
n2 >= len p1 &
n3 >= len p1 &
n4 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n1,
n5) ) & (
n2 >= len p1 &
n3 >= len p1 &
n5 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n1,
n4) ) & (
n2 >= len p1 &
n4 >= len p1 &
n5 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n1,
n3) ) & (
n3 >= len p1 &
n4 >= len p1 &
n5 >= len p1 implies
crossover (
p1,
p2,
n1,
n2,
n3,
n4,
n5)
= crossover (
p1,
p2,
n1,
n2) ) )