Implementation of beehive method (particle swarm optimization) for global optimization of multidimentional functions
Project description
Beehive method
pip install BeeHiveOptimization
Implementation of beehive method (particle swarm optimization) for global optimization of multidimentional functions. It's rewrite of my C#-implementation
Steps of algorithm
0 step: creating a function
Your target function should get a numpy array and return float number.
f1 = lambda arr: arr[0]+arr[1]/(1+arr[0])+arr[2]*arr[3]
# convertion to numpy->float function
def target(x,y,z,q):
return x**2+y**2*z/q
f2 = lambda arr: target(arr[0], arr[1], arr[2], arr[3])
The method seeks the global minimum of target function. If u want to find global maximum, use this idea:
f_tmp = lambda arr: -target(arr)
#
# ... find global min
#
tagret_result = -global_min
1st step: creating bees
U should create random bees (points) on the scope of the function definition. There are several ways:
from BeeHiveOptimization import Bees, Hive, BeeHive, TestFunctions, RandomPuts
import numpy as np
# 1st step is to create bees
np.random.seed(1)
# it's just numpy array with shape bees_count_x_dim
arr = np.random.uniform(low = -3, high = 5, size = (10,3))
# width parameter means the maximum range of random begging speeds
bees = Bees(arr, width = 0.2)
bees.show()
#Current bees' positions:
#[[ 0.33617604 2.76259595 -2.999085 ]
# [-0.58133942 -1.82595287 -2.26129124]
# [-1.50991831 -0.23551418 0.17413979]
# [ 1.31053387 0.35355612 2.481756 ]
# [-1.364382 4.02493949 -2.78089925]
# [ 2.36374008 0.33843842 1.46951863]
# [-1.87690449 -1.41518809 3.40595655]
# [ 4.74609261 -0.49260657 2.53858093]
# [ 4.01111322 4.15685331 -2.31964631]
# [-2.68756173 -1.64135664 4.02514003]]
#
#Current bees' speeds:
#[[-0.08033063 -0.01577847 0.09157791]
# [ 0.00663306 0.03837542 -0.03689687]
# [ 0.03730019 0.06692513 -0.09634234]
# [ 0.05002886 0.09777222 0.04963313]
# [-0.0439112 0.05785587 -0.0793548 ]
# [-0.01042129 0.0817191 -0.04127717]
# [-0.04244493 -0.07399429 -0.09612661]
# [ 0.03576711 -0.05767438 -0.04689067]
# [-0.00168537 -0.08932749 0.01482352]
# [-0.07065429 0.01786111 0.03995167]]
# u aslo can create bees by random generator like () --> random numpy array (point)
bees = Bees.get_Bees_from_randomputs(count = 10, random_gen = RandomPuts.Normal(mean = 1, std = 0.1, size = 2), width = 0.3)
bees.show()
#Current bees' positions:
#[[0.98081644 0.9112371 ]
# [0.92528417 1.16924546]
# [1.00508078 0.93630044]
# [1.01909155 1.21002551]
# [1.0120159 1.06172031]
# [1.03001703 0.96477502]
# [0.88574818 0.96506573]
# [0.97911058 1.05866232]
# [1.08389834 1.09311021]
# [1.02855873 1.08851412]]
#
#Current bees' speeds:
#[[ 0.07528273 -0.0453305 ]
# [-0.06902163 0.11876587]
# [-0.02157264 0.13945201]
# [ 0.04903245 0.03650872]
# [-0.11557621 0.13484678]
# [-0.01502636 0.02351688]
# [-0.02755896 -0.07889191]
# [ 0.12101386 0.02210385]
# [-0.1491389 0.03514347]
# [-0.05200653 0.00811743]]
2nd step: create hive and get result
bees = Bees(np.random.normal(loc = 2, scale = 2, size = (100,3)), width = 3)
func = lambda arr: TestFunctions.Parabol(arr-3)
hive = Hive(bees,
func,
parallel = False, # use parallel evaluating of functions values for each bee? (recommented for heavy functions, f. e. integtals)
verbose = True) # show info about hive
#total bees: 100
#best value (at beggining): 0.45406041997965585
# getting result
best_result, best_position = hive.get_result(max_step_count = 25, # maximun count of iteraions
max_fall_count = 6, # maximum count of continious iterations without better result
w = 0.3, fp = 2, fg = 5, # parameters of algorithm
latency = 1e-9, # if new_result/old_result > 1-latency then it was the iteration without better result
verbose = True, # show the progress
max_time_seconds = None # max seconds of working
)
#new best value = 0.22369081290807669 after 4 iteration
#new best value = 0.20481778141411794 after 5 iteration
#new best value = 0.2036698385729661 after 6 iteration
#new best value = 0.15570778532180615 after 7 iteration
#new best value = 0.06772538042802272 after 8 iteration
#new best value = 0.06060365350244633 after 9 iteration
#new best value = 0.048967304902866424 after 10 iteration
#new best value = 0.035531597911666886 after 11 iteration
#new best value = 0.018238258030885895 after 12 iteration
#new best value = 0.007999184438461721 after 13 iteration
#new best value = 0.007095161331114254 after 14 iteration
#new best value = 0.006010424290536399 after 15 iteration
#new best value = 0.0054592185233458875 after 16 iteration
#new best value = 0.003526411943370142 after 17 iteration
#new best value = 0.003212115031845861 after 18 iteration
#new best value = 0.001246361699255375 after 19 iteration
#new best value = 0.0011705559906451679 after 20 iteration
#new best value = 0.0010476941319986334 after 21 iteration
#new best value = 0.0006265651258711051 after 22 iteration
#new best value = 0.00041912821521993736 after 23 iteration
#new best value = 0.0003037094325696652 after 24 iteration
#new best value = 0.0002523002561426299 after 25 iteration
# u also can use this code (without creating a hive)
best_result, best_position = BeeHive.Minimize(func, bees,
max_step_count = 100, max_fall_count = 30,
w = 0.3, fp = 2, fg = 5, latency = 1e-9,
verbose = False, parallel = False)
Ways to get best solution
To get real global minimum u should use this algorithm with more bees, bigger max_step_count, bigger max_fall_count several parameters w, fp, fg:
# to get best solution
func = lambda arr: TestFunctions.Rastrigin(arr) + TestFunctions.Shvel(arr) + 1 / (1 + np.sum(np.abs(arr)))
for w in (0.1,0.3,0.5,0.8):
for fp in (1, 2, 3, 4.5):
for fg in (3, 5, 8, 15):
# 200 bees, 10 dimentions
bees = Bees(np.random.uniform(low = -100, high = 100, size = (200, 10) ))
best_val, _ = BeeHive.Minimize(func, bees,
max_step_count = 200, max_fall_count = 70,
w = 2, fp = fp, fg = fg, latency = 1e-9,
verbose = False, parallel = False)
print(f'best val by w = {w}, fp = {fp}, fg = {fg} is {best_val}')
#best val by w = 0.1, fp = 1, fg = 3 is 6428.695769232477
#best val by w = 0.1, fp = 1, fg = 5 is 32.52712233771301
#best val by w = 0.1, fp = 1, fg = 8 is 160.08392341144406
#best val by w = 0.1, fp = 1, fg = 15 is 687.6266727861189
#best val by w = 0.1, fp = 2, fg = 3 is 24.21891968781912
#best val by w = 0.1, fp = 2, fg = 5 is 49.44330907798958
#best val by w = 0.1, fp = 2, fg = 8 is 184.83187118199487
#best val by w = 0.1, fp = 2, fg = 15 is 185.51770584709303
#best val by w = 0.1, fp = 3, fg = 3 is 79.76934143653314
#best val by w = 0.1, fp = 3, fg = 5 is 47.26493469211696
#best val by w = 0.1, fp = 3, fg = 8 is 184.8646381092168
#best val by w = 0.1, fp = 3, fg = 15 is 160.27503370261758
#best val by w = 0.1, fp = 4.5, fg = 3 is 85.60089227083901
#best val by w = 0.1, fp = 4.5, fg = 5 is 108.62418480388155
#best val by w = 0.1, fp = 4.5, fg = 8 is 171.2798284181892
#best val by w = 0.1, fp = 4.5, fg = 15 is 551.7224618400166
#best val by w = 0.3, fp = 1, fg = 3 is 6483.765801924292
#best val by w = 0.3, fp = 1, fg = 5 is 8.002321991449135
#best val by w = 0.3, fp = 1, fg = 8 is 108.94659371003644
#best val by w = 0.3, fp = 1, fg = 15 is 47.079602126734684
#best val by w = 0.3, fp = 2, fg = 3 is 26.014123389174156
#best val by w = 0.3, fp = 2, fg = 5 is 18.29385998055267
#best val by w = 0.3, fp = 2, fg = 8 is 166.411456895688
#best val by w = 0.3, fp = 2, fg = 15 is 250.8512847429756
#best val by w = 0.3, fp = 3, fg = 3 is 212.89122853639924
#best val by w = 0.3, fp = 3, fg = 5 is 282.19775766847954
#best val by w = 0.3, fp = 3, fg = 8 is 78.26449685551408
#best val by w = 0.3, fp = 3, fg = 15 is 201.77855256657307
#best val by w = 0.3, fp = 4.5, fg = 3 is 101.7205867717656
#best val by w = 0.3, fp = 4.5, fg = 5 is 39.181243373144405
#best val by w = 0.3, fp = 4.5, fg = 8 is 31.339807579184082
#best val by w = 0.3, fp = 4.5, fg = 15 is 136.71496136204559
#best val by w = 0.5, fp = 1, fg = 3 is 7966.104488676415
#best val by w = 0.5, fp = 1, fg = 5 is 31.85174765332643
#best val by w = 0.5, fp = 1, fg = 8 is 119.51737439099381
#best val by w = 0.5, fp = 1, fg = 15 is 343.21190707573186
#best val by w = 0.5, fp = 2, fg = 3 is 19.69118760870259
#best val by w = 0.5, fp = 2, fg = 5 is 355.5573149722314
#best val by w = 0.5, fp = 2, fg = 8 is 124.35986298683065
#best val by w = 0.5, fp = 2, fg = 15 is 159.73058691572118
#best val by w = 0.5, fp = 3, fg = 3 is 91.73431812681028
#best val by w = 0.5, fp = 3, fg = 5 is 348.8643367168582
#best val by w = 0.5, fp = 3, fg = 8 is 103.67897134960793
#best val by w = 0.5, fp = 3, fg = 15 is 239.28420706187788
#best val by w = 0.5, fp = 4.5, fg = 3 is 128.31342837632542
#best val by w = 0.5, fp = 4.5, fg = 5 is 184.85393346379036
#best val by w = 0.5, fp = 4.5, fg = 8 is 24.808161917042987
#best val by w = 0.5, fp = 4.5, fg = 15 is 151.67171420308466
#best val by w = 0.8, fp = 1, fg = 3 is 11473.562212656598
#best val by w = 0.8, fp = 1, fg = 5 is 60.83786609973994
#best val by w = 0.8, fp = 1, fg = 8 is 136.37066252443586
#best val by w = 0.8, fp = 1, fg = 15 is 384.96175871884816
#best val by w = 0.8, fp = 2, fg = 3 is 12.05219722035246
#best val by w = 0.8, fp = 2, fg = 5 is 157.38773631834732
#best val by w = 0.8, fp = 2, fg = 8 is 480.3721790650163
#best val by w = 0.8, fp = 2, fg = 15 is 122.24297005195243
#best val by w = 0.8, fp = 3, fg = 3 is 94.49827014281807
#best val by w = 0.8, fp = 3, fg = 5 is 227.97483895242695
#best val by w = 0.8, fp = 3, fg = 8 is 155.60665206056973
#best val by w = 0.8, fp = 3, fg = 15 is 253.34803362736002
#best val by w = 0.8, fp = 4.5, fg = 3 is 64.920748391647
#best val by w = 0.8, fp = 4.5, fg = 5 is 73.96529195451255
#best val by w = 0.8, fp = 4.5, fg = 8 is 28.47149810229648
#best val by w = 0.8, fp = 4.5, fg = 15 is 130.0584088063038
Animations of working
See also
It can be very useful to use also:
- OppOpPopInit package for initialize population and using opposition learning strategy
- OptimizationTestFunctions package for handle several classic test functions
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