# encoding=utf8
import logging
import math
import numpy as np
from NiaPy.algorithms.algorithm import Algorithm
logging.basicConfig()
logger = logging.getLogger('NiaPy.algorithms.basic')
logger.setLevel('INFO')
__all__ = ['CatSwarmOptimization']
[docs]class CatSwarmOptimization(Algorithm):
r"""Implementation of Cat swarm optimiization algorithm.
**Algorithm:** Cat swarm optimization
**Date:** 2019
**Author:** Mihael Baketarić
**License:** MIT
**Reference paper:** Chu, S. C., Tsai, P. W., & Pan, J. S. (2006). Cat swarm optimization. In Pacific Rim international conference on artificial intelligence (pp. 854-858). Springer, Berlin, Heidelberg..
"""
Name = ['CatSwarmOptimization', 'CSO']
[docs] @staticmethod
def algorithmInfo():
r"""Get algorithm information.
Returns:
str: Algorithm information.
See Also:
* :func:`NiaPy.algorithms.Algorithm.algorithmInfo`
"""
return r"""Chu, S. C., Tsai, P. W., & Pan, J. S. (2006). Cat swarm optimization. In Pacific Rim international conference on artificial intelligence (pp. 854-858). Springer, Berlin, Heidelberg."""
[docs] @staticmethod
def typeParameters(): return {
'NP': lambda x: isinstance(x, int) and x > 0,
'MR': lambda x: isinstance(x, (int, float)) and 0 <= x <= 1,
'C1': lambda x: isinstance(x, (int, float)) and x >= 0,
'SMP': lambda x: isinstance(x, int) and x > 0,
'SPC': lambda x: isinstance(x, bool),
'CDC': lambda x: isinstance(x, (int, float)) and 0 <= x <= 1,
'SRD': lambda x: isinstance(x, (int, float)) and 0 <= x <= 1,
'vMax': lambda x: isinstance(x, (int, float)) and x > 0
}
[docs] def setParameters(self, NP=30, MR=0.1, C1=2.05, SMP=3, SPC=True, CDC=0.85, SRD=0.2, vMax=1.9, **ukwargs):
r"""Set the algorithm parameters.
Arguments:
NP (int): Number of individuals in population.
MR (float): Mixture ratio.
C1 (float): Constant in tracing mode.
SMP (int): Seeking memory pool.
SPC (bool): Self-position considering.
CDC (float): Decides how many dimensions will be varied.
SRD (float): Seeking range of the selected dimension.
vMax (float): Maximal velocity.
See Also:
* :func:`NiaPy.algorithms.Algorithm.setParameters`
"""
Algorithm.setParameters(self, NP=NP, **ukwargs)
self.MR, self.C1, self.SMP, self.SPC, self.CDC, self.SRD, self.vMax = MR, C1, SMP, SPC, CDC, SRD, vMax
[docs] def initPopulation(self, task):
r"""Initialize population.
Args:
task (Task): Optimization task.
Returns:
Tuple[numpy.ndarray, numpy.ndarray[float], Dict[str, Any]]:
1. Initialized population.
2. Initialized populations fitness/function values.
3. Additional arguments:
* Dictionary of modes (seek or trace) and velocities for each cat
See Also:
* :func:`NiaPy.algorithms.Algorithm.initPopulation`
"""
pop, fpop, d = Algorithm.initPopulation(self, task)
d['modes'] = self.randomSeekTrace()
d['velocities'] = self.uniform(-self.vMax, self.vMax, [len(pop), task.D])
return pop, fpop, d
[docs] def repair(self, x, l, u):
r"""Repair array to range.
Args:
x (numpy.ndarray): Array to repair.
l (numpy.ndarray): Lower limit of allowed range.
u (numpy.ndarray): Upper limit of allowed range.
Returns:
numpy.ndarray: Repaired array.
"""
ir = np.where(x < l)
x[ir] = l[ir]
ir = np.where(x > u)
x[ir] = u[ir]
return x
[docs] def randomSeekTrace(self):
r"""Set cats into seeking/tracing mode.
Returns:
numpy.ndarray: One or zero. One means tracing mode. Zero means seeking mode. Length of list is equal to NP.
"""
lista = np.zeros((self.NP,), dtype=int)
indexes = np.arange(self.NP)
self.Rand.shuffle(indexes)
lista[indexes[:int(self.NP * self.MR)]] = 1
return lista
[docs] def weightedSelection(self, weights):
r"""Random selection considering the weights.
Args:
weights (numpy.ndarray): weight for each potential position.
Returns:
int: index of selected next position.
"""
cumulative_sum = np.cumsum(weights)
return np.argmax(cumulative_sum >= (self.rand() * cumulative_sum[-1]))
[docs] def seekingMode(self, task, cat, fcat, pop, fpop, fxb):
r"""Seeking mode.
Args:
task (Task): Optimization task.
cat (numpy.ndarray): Individual from population.
fcat (float): Current individual's fitness/function value.
pop (numpy.ndarray): Current population.
fpop (numpy.ndarray): Current population fitness/function values.
fxb (float): Current best cat fitness/function value.
Returns:
Tuple[numpy.ndarray, float, numpy.ndarray, float]:
1. Updated individual's position
2. Updated individual's fitness/function value
3. Updated global best position
4. Updated global best fitness/function value
"""
cat_copies = []
cat_copies_fs = []
for j in range(self.SMP - 1 if self.SPC else self.SMP):
cat_copies.append(cat.copy())
indexes = np.arange(task.D)
self.Rand.shuffle(indexes)
to_vary_indexes = indexes[:int(task.D * self.CDC)]
if self.randint(2) == 1:
cat_copies[j][to_vary_indexes] += cat_copies[j][to_vary_indexes] * self.SRD
else:
cat_copies[j][to_vary_indexes] -= cat_copies[j][to_vary_indexes] * self.SRD
cat_copies[j] = task.repair(cat_copies[j])
cat_copies_fs.append(task.eval(cat_copies[j]))
if self.SPC:
cat_copies.append(cat.copy())
cat_copies_fs.append(fcat)
cat_copies_select_probs = np.ones(len(cat_copies))
fmax = np.max(cat_copies_fs)
fmin = np.min(cat_copies_fs)
if any(x != cat_copies_fs[0] for x in cat_copies_fs):
fb = fmax
if math.isinf(fb):
cat_copies_select_probs = np.full(len(cat_copies), fb)
else:
cat_copies_select_probs = np.abs(cat_copies_fs - fb) / (fmax - fmin)
if fmin < fxb:
fxb = fmin
ind = self.randint(self.NP, 1, 0)
pop[ind] = cat_copies[np.where(cat_copies_fs == fmin)[0][0]]
fpop[ind] = fmin
sel_index = self.weightedSelection(cat_copies_select_probs)
return cat_copies[sel_index], cat_copies_fs[sel_index], pop, fpop
[docs] def tracingMode(self, task, cat, velocity, xb):
r"""Tracing mode.
Args:
task (Task): Optimization task.
cat (numpy.ndarray): Individual from population.
velocity (numpy.ndarray): Velocity of individual.
xb (numpy.ndarray): Current best individual.
Returns:
Tuple[numpy.ndarray, float, numpy.ndarray]:
1. Updated individual's position
2. Updated individual's fitness/function value
3. Updated individual's velocity vector
"""
Vnew = self.repair(velocity + (self.uniform(0, 1, len(velocity)) * self.C1 * (xb - cat)), np.full(task.D, -self.vMax), np.full(task.D, self.vMax))
cat_new = task.repair(cat + Vnew)
return cat_new, task.eval(cat_new), Vnew
[docs] def runIteration(self, task, pop, fpop, xb, fxb, velocities, modes, **dparams):
r"""Core function of Cat Swarm Optimization algorithm.
Args:
task (Task): Optimization task.
pop (numpy.ndarray): Current population.
fpop (numpy.ndarray): Current population fitness/function values.
xb (numpy.ndarray): Current best individual.
fxb (float): Current best cat fitness/function value.
velocities (numpy.ndarray): Velocities of individuals.
modes (numpy.ndarray): Flag of each individual.
**dparams (Dict[str, Any]): Additional function arguments.
Returns:
Tuple[numpy.ndarray, numpy.ndarray, numpy.ndarray, float, Dict[str, Any]]:
1. New population.
2. New population fitness/function values.
3. New global best solution.
4. New global best solutions fitness/objective value.
5. Additional arguments:
* Dictionary of modes (seek or trace) and velocities for each cat.
"""
pop_copies = pop.copy()
for k in range(len(pop_copies)):
if modes[k] == 0:
pop_copies[k], fpop[k], pop_copies[:], fpop[:] = self.seekingMode(task, pop_copies[k], fpop[k], pop_copies, fpop, fxb)
else: # if cat in tracing mode
pop_copies[k], fpop[k], velocities[k] = self.tracingMode(task, pop_copies[k], velocities[k], xb)
ib = np.argmin(fpop)
if fpop[ib] < fxb: xb, fxb = pop_copies[ib].copy(), fpop[ib]
return pop_copies, fpop, xb, fxb, {'velocities': velocities, 'modes': self.randomSeekTrace()}
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