# Genetic Algorithms

Τεχνίτη Νοημοσύνη και Ρομποτική

24 Οκτ 2013 (πριν από 4 χρόνια και 8 μήνες)

106 εμφανίσεις

Genetic Algorithms

Problem: find an optimal solution.

Solution, so far: search through all possible solutions to find the best one.

Solution with genetic algorithms: start from a set of solutions and keep on evolving the
solutions until the “best fit”
to the real solution is found.

Each solution is a bit string (for example, concatenated values of features). This bit string
is called a chromosome.

Bits that comprise one feature are called a gene.

Bits within a gene are called alleles.

The position
of a bit is called a locus.

For example, let us assume that we have samples 1 and 2 and the task is to find the
optimal value for F2 sample 3 such that the class of that sample is either A or B.

Sample

Feature F1

F2

Class

S
1

1

2

A

S
2

4

5

B

S
3

2

x=?

The

mathematics can use various distances, for example Euclidian distance
and minimum square error. We would start from a solution and somehow keep on
evolving it, for example by slightly moving the sample value. For example, we would
start wi
th x=2,
and
calculate the distance from point
S3
(2,2) to the points in cluster A.
Then we would pick another point, for example x=2.2, and see if the error improves. If
not, we would
try x=1.8. And so on, we would try all points at distances i*δ away from
the original point, where δ is a predetermined step size, and i is a counter.

If the error did
not improve, we could repeat the process for another starting value of x.

Genetic algorithms work
by putting the solution in
to

the form of a binary string.

The

solution is based on a schema. * are don’t cares.

**00**11*

Genetic algorithm:

1.

Generate random population of
n

chromosomes (
i.e.
suitable solutions for the
problem)

2.

Evaluate the fitness

of each chromosome
x

in the population

3.

While the fitness is below

the desired level, c
reate a new populati
on:

1.

Select:

Select two parent chromosomes from a population according to their
fitness (the better fitness, the bigger chance to be selected

it is possible
to be selected several times
)

2.

Crossover:

Using a prespec
ified crossover probability, cross
over the parents to form
new offspring (children). If no crossover was performed, offspring is the
exact copy of parents.

3.

Mutate:

Using a prespecified
mutation probability
,

muta
te new offspring at each
locus
.

4.

Place new o
ffspring in the new population

5.

Evaluate:

Evaluate the fitness

of each chromosome
x

in the population
.

4.

Return

the best

solution in current population.

Variables to be selected are:

1.

type and size of chromosomes

1.

define alleles based on specified minimum pre
cision

2.

number and values of initial chromosomes

3.

crossover probability and strategy

4.

mutation probability

5.

evaluation, i.e. assigning fitness to chromosomes and their offspring

6.

selecting new population

7.

stopping criteria

Type and size of chromosomes

1.
Binary

encoding

Most common way is to have each feature represented as a binary string. The number of
bits is determined from this formula:

(b
-
a) / (2
m

-
1)
≤ required_precision

where [a, b] is the range of values for the feature, m is the number of bits, and
required_precision is assigned by the user.

If we call C = (b
-
a) / (2
m

-
1) for short, t
hen each feature will have
binary
value

binary

=
a + decimal* C

2. Gray Encoding

3. Value Encoding

4.
Permutation encoding

Swap all instances of values to be swapped.

E.g.: in order to swap EB for CD, swap E and C in chromosome 1, and swap B and D in
chromosome 2.

5.
etc.

Crossover

1.
Single point crossover

Pick a point in the chromosomes, and “s
wap”
corresponding

tail
portions of two parent
chromosomes to make up an offspring.

2.
Two point crossover

A D
E B

C

A D
C

B

E

A
B

C
D

E

A E
C D

B

A
C

E

D

B A
C
E
B

D

1 1 1 1 1 1 1 1

1 1 1 1 1

0 0 0

0 0 0 0 0 0 0 0

Same as above except that the split
is not at one point,
but at two, and we swap the
middle.

3.
Arithmetic crossover

4. Uniform crossover

5. etc.

Mutation

Each bit can be mutated
(i.e. inverted)
or not, according to mutation probability.

Example:
problem 10.8

Fitness

Assign some
fitness function.

Selection

H
ow do we select the fittest

chromosomes which will be used for crossover
?

1.
Roulette wheel selection

Probability of selecting this chromosome is proportional to its fitness.

2.
Ranking

Chromosomes are ranked based on fitnes
s.

3. Tournament (
Selecting the fittest
)

1 1 1 1 1 1 1 1

1
0 0 0

0

1 1 1

0 0 0 0 0 0 0 0

Only the fittest are selected for crossover.

4.
Elitism

At each iteration, save the best chromosome and copy it into the new population.

5. etc.

Termination

1. When there is not much difference between iterations

2. When we completed a given number of iterations

3. etc.

Reference
s
:

http://cs.felk.cvut.cz/~xobitko/ga/

http://pangea.stanford.edu/~baris/professional/theoryga.html

http://www.burns
-
stat.com/pages/Tutor/genetic.html

http://members.ao
l.com/btluke/gmovr01.htm

for Aren

http://en.wikipedia.org/wiki/Genetic_algorithm