class IntegerLocalSearch extends AnyRef
The IntegerLocalSearch
class performs local search to find minima of functions
defined on integer vector domains (z^n).
minimize f(x) subject to g(x) <= 0, x in Z^n
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new
IntegerLocalSearch(f: (VectorI) ⇒ Double, g: (VectorI) ⇒ Double = null, maxStep: Int = 5)
- f
the objective function to be minimize ('f' maps an integer vector to a double)
- g
the constraint function to be satisfied, if any
- maxStep
the maximum/starting step size (make larger for larger domains)
Type Members
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type
Vec_Func = (VectorI, Double)
Pair consisting of an integer vector and its functional value (a double)
Value Members
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def
fg(x: VectorI): Double
The objective function 'f' re-scaled by a weighted penalty, if constrained.
The objective function 'f' re-scaled by a weighted penalty, if constrained.
- x
the coordinate values of the current point
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finalize(): Unit
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isInstanceOf[T0]: Boolean
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def
minNeighbor(x_f0: Vec_Func, i: Int, step: Int = 1): Vec_Func
Find a minimal neighbor of the current point 'x' that is a distance step away.
Find a minimal neighbor of the current point 'x' that is a distance step away. Let 'x' be the current point with 'y' being a step down and 'x' being a step up in dimension 'i'. Recurse to handle all of the dimensions.
- x_f0
the current pair (the point and its functional value)
- i
the 'i'th dimension or coordinate (facilitates recursion)
- step
examine points that are this far away
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def
ne(arg0: AnyRef): Boolean
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def
notify(): Unit
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def
notifyAll(): Unit
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def
solve(x: VectorI): Vec_Func
Solve the minimization problem by repeatedly moving to a minimal neighbor until there is no improvement.
Solve the minimization problem by repeatedly moving to a minimal neighbor until there is no improvement.
- x
the starting point for the search
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wait(arg0: Long): Unit
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