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I have implemented a simple randomized, population-based optimization method - Grey Wolf optimizer. I am having some trouble with properly capturing the Matplotlib plots at each iteration using the camera package.

I am running GWO for the objective function f(x,y) = x^2 + y^2. I can only see the candidate solutions converging to the minima, but the contour plot doesn't show up.

Do you have any suggestions, how can I display the contour plot in the background?

enter image description here

GWO Algorithm implementation

%matplotlib notebook
import matplotlib.pyplot as plt
import numpy as np
from celluloid import Camera
import ffmpeg
import pillow

# X : Position vector of the initial population
# n : Initial population size

def gwo(f,max_iterations,LB,UB):
    
    fig = plt.figure()
    camera = Camera(fig)
    
    def random_population_uniform(m,a,b):
        dims = len(a)
        x = [list(a + np.multiply(np.random.rand(dims),b - a)) for i in range(m)]
        return np.array(x)

    def search_agent_fitness(fitness):
        alpha = 0
        if fitness[1] < fitness[alpha]:
            alpha, beta = 1, alpha
        else:
            beta = 1

        if fitness[2] > fitness[alpha] and fitness[2] < fitness[beta]:
            beta, delta = 2, beta
        elif fitness[2] < fitness[alpha]:
            alpha,beta,delta = 2,alpha,beta
        else:
            delta = 2

        for i in range(3,len(fitness)):
            if fitness[i] <= fitness[alpha]:
                alpha, beta,delta = i, alpha, beta
            elif fitness[i] > fitness[alpha] and fitness[i]<= fitness[beta]:
                beta,delta = i,beta
            elif fitness[i] > fitness[beta] and fitness[i]<= fitness[delta]:
                delta = i

        return alpha, beta, delta
    
    
    def plot_search_agent_positions(f,X,alpha,beta,delta,a,b):
        
    
        # Plot the positions of search agents

        x = X[:,0]
        y = X[:,1]
        
        
        s = plt.scatter(x,y,c='gray',zorder=1)
        s = plt.scatter(x[alpha],y[alpha],c='red',zorder=1)
        s = plt.scatter(x[beta],y[beta],c='blue',zorder=1)
        s = plt.scatter(x[delta],y[delta],c='green',zorder=1)
        
        camera.snap()
    

    
    # Initialize the position of the search agents
    X = random_population_uniform(50,np.array(LB),np.array(UB))
    
    n = len(X)

    l = 1
    
    # Plot the first image on screen
    x = np.linspace(LB[0],LB[1],1000)
    y = np.linspace(LB[0],UB[1],1000)

    X1,X2 = np.meshgrid(x,y)


    Z = f(X1,X2)
    cont = plt.contour(X1,X2,Z,20,linewidths=0.75)
    
    while (l < max_iterations):
            # Take the x,y coordinates of the initial population
            x = X[:,0]
            y = X[:,1]

            # Calculate the objective function for each search agent 
            fitness = list(map(f,x,y))

            # Update alpha, beta and delta
            alpha,beta,delta = search_agent_fitness(fitness)
            
            # Plot search agent positions
            plot_search_agent_positions(f,X,alpha,beta,delta,LB,UB)
            
            # a decreases linearly from 2 to 0
            a = 2 - l *(2 / max_iterations)

            # Update the position of search agents including the Omegas
            for i in range(n):
                x_prey = X[alpha]

                r1 = np.random.rand(2) #r1 is a random vector in [0,1] x [0,1]
                r2 = np.random.rand(2) #r2 is a random vector in [0,1] x [0,1]
                A1 = 2*a*r1 - a
                C1 = 2*r2

                D_alpha = np.abs(C1 * x_prey - X[i])
                X_1 = x_prey - A1*D_alpha
                
                x_prey = X[beta]
                r1 = np.random.rand(2) 
                r2 = np.random.rand(2) 
                A2 = 2*a*r1 - a
                C2 = 2*r2

                D_beta = np.abs(C2 * x_prey - X[i])
                X_2 = x_prey - A2*D_beta

                x_prey = X[delta]
                r1 = np.random.rand(2) 
                r2 = np.random.rand(2) 
                A3 = 2*a*r1 - a
                C3 = 2*r2

                D_delta = np.abs(C3 * x_prey - X[i])
                X_3 = x_prey - A3*D_delta

                X[i] = (X_1 + X_2 + X_3)/3

            l = l + 1
            

    return X[alpha],camera

Function call

# define the objective function
def f(x,y):
    return x**2 + y**2

minimizer,camera = gwo(f,7,[-10,-10],[10,10])

animation = camera.animate(interval = 1000, repeat = True,
                           repeat_delay = 500)

1 Answer 1

4

Is it possible that the line x = np.linspace(LB[0],LB[1],1000) should be x = np.linspace(LB[0],UB[1],1000) instead? With your current definition of x, x is an array only filled with the value -10 which means that you are unlikely to find a contour. Another thing that you might want to do is to move the cont = plt.contour(X1,X2,Z,20,linewidths=0.75) line inside of your plot_search_agent_positions function to ensure that the contour is plotted at each iteration of the animation. Once you make those changes, the code looks like that:

import matplotlib.pyplot as plt
import numpy as np
from celluloid import Camera
import ffmpeg
import PIL
from matplotlib import animation, rc
from IPython.display import HTML, Image # For GIF
from scipy.interpolate import griddata

rc('animation', html='html5')

# X : Position vector of the initial population
# n : Initial population size

def gwo(f,max_iterations,LB,UB):
    
    fig = plt.figure()
    fig.gca(aspect='equal')
    camera = Camera(fig)
    
    def random_population_uniform(m,a,b):
        dims = len(a)
        x = [list(a + np.multiply(np.random.rand(dims),b - a)) for i in range(m)]
        return np.array(x)

    def search_agent_fitness(fitness):
        alpha = 0
        if fitness[1] < fitness[alpha]:
            alpha, beta = 1, alpha
        else:
            beta = 1

        if fitness[2] > fitness[alpha] and fitness[2] < fitness[beta]:
            beta, delta = 2, beta
        elif fitness[2] < fitness[alpha]:
            alpha,beta,delta = 2,alpha,beta
        else:
            delta = 2

        for i in range(3,len(fitness)):
            if fitness[i] <= fitness[alpha]:
                alpha, beta,delta = i, alpha, beta
            elif fitness[i] > fitness[alpha] and fitness[i]<= fitness[beta]:
                beta,delta = i,beta
            elif fitness[i] > fitness[beta] and fitness[i]<= fitness[delta]:
                delta = i

        return alpha, beta, delta
    
    
    def plot_search_agent_positions(f,X,alpha,beta,delta,a,b,X1,X2,Z):
        
    
        # Plot the positions of search agents

        x = X[:,0]
        y = X[:,1]
        
        
        s = plt.scatter(x,y,c='gray',zorder=1)
        s = plt.scatter(x[alpha],y[alpha],c='red',zorder=1)
        s = plt.scatter(x[beta],y[beta],c='blue',zorder=1)
        s = plt.scatter(x[delta],y[delta],c='green',zorder=1)
        Z=f(X1,X2)
        cont=plt.contour(X1,X2,Z,levels=20,colors='k',norm=True)
        plt.clabel(cont, cont.levels, inline=True, fontsize=10)
        camera.snap()
    

    
    # Initialize the position of the search agents
    X = random_population_uniform(50,np.array(LB),np.array(UB))
    
    n = len(X)

    l = 1
    
    # Plot the first image on screen
    x = np.linspace(LB[0],UB[1],1000)
    y = np.linspace(LB[0],UB[1],1000)

    X1,X2 = np.meshgrid(x,y)
    Z=f(X1,X2)

    while (l < max_iterations):
            # Take the x,y coordinates of the initial population
            x = X[:,0]
            y = X[:,1]

            # Calculate the objective function for each search agent 
            fitness = list(map(f,x,y))

            # Update alpha, beta and delta
            alpha,beta,delta = search_agent_fitness(fitness)
            
            # Plot search agent positions
            plot_search_agent_positions(f,X,alpha,beta,delta,LB,UB,X1,X2,Z)
            
            # a decreases linearly from 2 to 0
            a = 2 - l *(2 / max_iterations)

            # Update the position of search agents including the Omegas
            for i in range(n):
                x_prey = X[alpha]

                r1 = np.random.rand(2) #r1 is a random vector in [0,1] x [0,1]
                r2 = np.random.rand(2) #r2 is a random vector in [0,1] x [0,1]
                A1 = 2*a*r1 - a
                C1 = 2*r2

                D_alpha = np.abs(C1 * x_prey - X[i])
                X_1 = x_prey - A1*D_alpha
                
                x_prey = X[beta]
                r1 = np.random.rand(2) 
                r2 = np.random.rand(2) 
                A2 = 2*a*r1 - a
                C2 = 2*r2

                D_beta = np.abs(C2 * x_prey - X[i])
                X_2 = x_prey - A2*D_beta

                x_prey = X[delta]
                r1 = np.random.rand(2) 
                r2 = np.random.rand(2) 
                A3 = 2*a*r1 - a
                C3 = 2*r2

                D_delta = np.abs(C3 * x_prey - X[i])
                X_3 = x_prey - A3*D_delta

                X[i] = (X_1 + X_2 + X_3)/3

            l = l + 1
            

    return X[alpha],camera
    # define the objective function
def f(x,y):
    return x**2 + y**2

minimizer,camera = gwo(f,7,[-10,-10],[10,10])

animation = camera.animate(interval = 1000, repeat = True,repeat_delay = 500)

And the output gives:

enter image description here

1
  • 1
    I also added fig.gca(aspect='equal') to fix the aspect ratio of the plot. And I added contour labels with plt.clabel(cont, cont.levels, inline=True, fontsize=10).
    – jylls
    Commented Nov 28, 2021 at 20:51

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