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Optimization with Genetic Algorithms

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elseif ceil(assignment(i)/4) == family_info(i,3) % second choice ... building = ceil(assignment(i)/4); occupancy(building) = occupancy(building) family_info(i,1) ... – PowerPoint PPT presentation

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Title: Optimization with Genetic Algorithms


1
Optimization withGenetic Algorithms
  • Walter Reade
  • October 31, 2002
  • TAG Meeting

2
Outline
  • Background on Optimization
  • Introduction to Genetic Algorithms
  • Using GAs to Solve Difficult Problems
  • A MatLab Implementation
  • Summary / Questions

3
How Do We Find the Minimum?
4
Gradient Methods(Steepest Descent)
  • Move in the direction of steepest gradient.
  • Simple to implement, guaranteed convergence.
  • Must know something about the derivative.
  • Can easily get stuck in a local minimum.

5
Stochastic Methods
  • Heuristic
  • Using Rules of Thumb
  • Metaheuristic
  • A framework of heuristics used to update a set of
    solutions during a search.
  • Simulated Annealing
  • Tabu Search
  • Ant Colony Systems

6
Genetic Algorithms
  • Use a population of possible solutions to the
    search space.
  • Each solution is encoded in a string called a
    chromosome (or genome).
  • Chromosomes are evaluated for fitness each
    generation (iteration) chromosomes that are more
    fit have a high probability of surviving.

7
Genetic Algorithms (cont.)
  • Once the surviving population is chosen,
    different parent chromosomes are combined to
    form child chromosomes.
  • Chromosomes may undergo mutation.
  • A new generation is formed, the process is
    repeated.
  • By selection, cross-over, and mutation, GAs
    search the solution space while creating stronger
    solutions over each generation.

8
Fitness and Selection
  • Roulette Wheel
  • Competition
  • Etc.

9
Cross-Over
  • Replaces two parent solutions with two children
    solutions.
  • Mechanism for covering large area of search space.

10
Mutation
  • Operates on a single chromosome.
  • Mechanism to improve local search space.

11
Advantages to using GAs
  • Flexible and adaptive to a wide variety of
    problems.
  • Robust, global search capability.
  • Does not require the solution space to be smooth,
    continuous, or differentiable.
  • Can be used in permutation problems.
  • No practical drawbacks.
  • Slow local convergence
  • Perceived learning overhead

12
Applications
  • Function optimization
  • Job shop scheduling
  • Process planning
  • Assembly line optim.
  • Process control
  • Airplane landing
  • Nested design
  • Keyboard layout
  • Creativity
  • VLSI
  • Traveling Sales Man
  • Chemical kinetics
  • Etc.
  • Etc.
  • Etc.

13
Solving Difficult Problems
14
Difficult Problems
  • Appeared in Jan/Feb 2002 SIAM News in the
    100-Dollar, 100-Digit Challenge.
  • exp(sin(50x)) sin(60exp(y)) sin(70sin(x))
    sin(sin(80y)) - sin(10(xy)) 0.25(x2
    y2)
  • The genetic algorithm was able to solve this to
    10 digits of precision in 2000 generations, which
    took 25 seconds on a P-III 1.0 GHz. (35 success
    rate)

15
Permutation (Order-based) Problems
  • Time-share Example
  • One condo building at a ski resort
  • Four identical condo units
  • 16 week ski season 64 total owners
  • 2nd choice 2 free lift tickets per person, 3rd
    choice 5 free tickets, otherwise and 7 free
    tickets.
  • 5 out of 16 weeks are twice as popular
  • Maximum occupancy 22
  • Possible solutions 1x1067

16
Results of GA
  • A previous published result (using SA) found a
    minimum of 224 after 261 iterations, and no
    improvement after 1,000,000 iterations.
  • The GA found a cost of 200 after 2,150
    iterations, and a minimum of 172 after 250,000
    iterations.
  • (Author of previous work was astonished at the
    new result.)

17
Using GAs in MatLab
  • http//www.ie.ncsu.edu/mirage/GAToolBox/gaot/

18
MatLab Code
  • Bounds on the variables
  • bounds -5 5 -5 5
  • Evaluation Function
  • evalFn 'Four_Eval'
  • evalOps
  • Generate an intialize population of size 80
  • startPopinitializega(80,bounds,evalFn,1e-10
    1)
  • GA Options epsilon float/binary display
  • gaOpts1e-10 1 0
  • Termination Operators -- 500 Generations
  • termFns 'maxGenTerm'
  • termOps 500
  • Selection Function
  • selectFn 'normGeomSelect'
  • selectOps 0.08
  • Crossover Operators
  • xFns 'arithXover heuristicXover simpleXover'
  • xOpts 1 0 1 3 1 0
  • Mutation Operators
  • mFns 'boundaryMutation multiNonUnifMutation
    nonUnifMutation unifMutation'
  • mOpts 2 0 03 200 32 200 32 0 0
  • Apply the genetic algorithm
  • soln endPop bestPop tracega(bounds,evalFn,evalO
    ps,startPop,gaOpts,termFns,termOps,selectFn,select
    Ops,xFns,xOpts,mFns,mOpts)

19
Evaluation Function
  • function x, soln Four_Eval(x, options)
  • soln -(exp(sin(50x(1))) sin(60exp(x(2)))
    sin(70sin(x(1))) ...
  • sin(sin(80x(2))) - sin(10(x(1)x(2)))
    0.25(x(1)2 x(2)2))

20
Time Share Evaluation Function
  • function assignment, soln local_min(assignment
    , options)
  • global family_info
  • cost 0
  • occupancy zeros(16,1)
  • for i 164
  • if ceil(assignment(i)/4) family_info(i,2)
    first choice
  • cost cost 0
  • elseif ceil(assignment(i)/4)
    family_info(i,3) second choice
  • cost cost 2family_info(i,1)
  • elseif ceil(assignment(i)/4)
    family_info(i,4) third choice
  • cost cost 4family_info(i,1)
  • else didn't get any choice
  • cost cost 50 7family_info(i,1)
  • end

21
Summary
  • Genetic Algorithms are
  • Powerful
  • Flexible
  • Easy to use and understand
  • Consider using a GA for your next optimization
    problem!

22
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