Simple omnivariate particle swarm optimization. This is a semi-automatic tool to find points-of-interest (PoI) within a function.
- No Libraries: Clone this project
git clone https://github.com/irreq/n-dimensional-psoand start optimizing! - Dimensional Independent: Higher dimensions do however require more computational power.
- Simplicity: Just feed the name of the function to optimize, and out comes a solution.
In computational science, particle swarm optimization (PSO) is a computational method that optimizes a problem by iteratively trying to improve a candidate solution with regard to a given measure of quality. It solves a problem by having a population of candidate solutions, here dubbed particles, and moving these particles around in the search-space according to simple mathematical formulae over the particle's position and velocity. Each particle's movement is influenced by its local best known position, but is also guided toward the best known positions in the search-space, which are updated as better positions are found by other particles. This is expected to move the swarm toward the best solutions. (https://en.wikipedia.org/wiki/Particle_swarm_optimization)
Suppose we want to find √2. This could be done by finding what value x is when the function power_2 (also known as x^2) returns 2 for x. Since we know the real answer is 1<x<2 we can specify the search domain for increased performance. Using particle swarm optimization:
import pso
# The function to optimize
def power_2(x):
return x**2
# Auto optimization, with as few hyper-parameters as possible
best, coordinates = pso.optimize(power_2, target=2, domain=[1, 2])
# [1.414211357351861] 1.9999937632629934Suppose we want to find the minima of f(x) = sin(x) in the domain: π ≤ x ≤ 2π.
The current known solution is x = 3π/2 where sin(3π/2) = -1.
Using particle swarm optimization:
import pso
import numpy as np
# Sinusoidal function
def sin(x):
return np.sin(x)
# Auto optimization, with as few hyper-parameters as possible
best, coordinates = pso.optimize(sin, target='minimum', domain=[np.pi, 2*np.pi])During this run, best is -0.99999, which is very close to -1.
coordinates is returned as the list: [4.7123] which is close to 3π/2
Suppose we want to find the what combination values that comes closest to 4.3 of f(a,b,c,d,e) = a^b+c/2-d/e in the chosen domain -2.3 ≤ a,b,c,d,e ≤ 8 using 35 particles for 80 iterations.
Using particle swarm optimization:
import pso
# The function to optimize
def foo(a, b, c, d, e):
return a**b + c/2 - d/e
# Initiate the pso with 35 particles for 80 iterations
best, coordinates = pso.optimize(foo, target=4.3, domain=[-2.3, 8], n=35, iters=80)