trirep.py

#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
trirep.py
Created on Thu May  9 16:23:30 2019

@author: nolte
Introduction to Modern Dynamics, 2nd edition (Oxford University Press, 2019)

Population dynamics
"""

import numpy as np
from scipy import integrate
from matplotlib import pyplot as plt

plt.close('all')

def tripartite(x,y,z):

    sm = x + y + z
    xp = x/sm
    yp = y/sm

    f = np.sqrt(3)/2

    y0 = f*xp
    x0 = -0.5*xp - yp + 1;

    plt.figure(2)
    lines = plt.plot(x0,y0)
    plt.setp(lines, linewidth=0.5)
    plt.plot([0, 1],[0, 0],'k',linewidth=1)
    plt.plot([0, 0.5],[0, f],'k',linewidth=1)
    plt.plot([1, 0.5],[0, f],'k',linewidth=1)
    plt.show()


def solve_flow(y,tspan):
    def flow_deriv(y, t0):
    #"""Compute the time-derivative ."""

        f = np.zeros(shape=(N,))
        for iloop in range(N):
            ftemp = 0
            for jloop in range(N):
                ftemp = ftemp + A[iloop,jloop]*y[jloop]
            f[iloop] = ftemp

        phitemp = phi0          # Can adjust this from 0 to 1 to stabilize (but Nth population is no longer independent)
        for loop in range(N):
            phitemp = phitemp + f[loop]*y[loop]
        phi = phitemp

        yd = np.zeros(shape=(N,))
        for loop in range(N-1):
            yd[loop] = y[loop]*(f[loop] - phi);

        if np.abs(phi0) < 0.01:             # average fitness maintained at zero
            yd[N-1] = y[N-1]*(f[N-1]-phi);
        else:                                     # non-zero average fitness
            ydtemp = 0
            for loop in range(N-1):
                ydtemp = ydtemp - yd[loop]
            yd[N-1] = ydtemp

        return yd

    # Solve for the trajectories
    t = np.linspace(0, tspan, 701)
    x_t = integrate.odeint(flow_deriv,y,t)
    return t, x_t

# model_case 1 = zero diagonal
# model_case 2 = zero trace
# model_case 3 = asymmetric (zero trace)
print(' ')
print('trirep.py')
print('Case: 1 = antisymm zero diagonal')
print('Case: 2 = antisymm zero trace')
print('Case: 3 = random')
model_case = int(input('Enter the Model Case (1-3)'))

N = 3
asymm = 3      # 1 = zero diag (replicator eqn)   2 = zero trace (autocatylitic model)  3 = random (but zero trace)
phi0 = 0.001            # average fitness (positive number) damps oscillations
T = 100;


if model_case == 1:
    Atemp = np.zeros(shape=(N,N))
    for yloop in range(N):
        for xloop in range(yloop+1,N):
            Atemp[yloop,xloop] = 2*(0.5 - np.random.random(1))
            Atemp[xloop,yloop] = -Atemp[yloop,xloop]

if model_case == 2:
    Atemp = np.zeros(shape=(N,N))
    for yloop in range(N):
        for xloop in range(yloop+1,N):
            Atemp[yloop,xloop] = 2*(0.5 - np.random.random(1))
            Atemp[xloop,yloop] = -Atemp[yloop,xloop]
        Atemp[yloop,yloop] = 2*(0.5 - np.random.random(1))

    tr = np.trace(Atemp)
    A = Atemp
    for yloop in range(N):
        A[yloop,yloop] = Atemp[yloop,yloop] - tr/N

else:
    Atemp = np.zeros(shape=(N,N))
    for yloop in range(N):
        for xloop in range(N):
            Atemp[yloop,xloop] = 2*(0.5 - np.random.random(1))

    tr = np.trace(Atemp)
    A = Atemp
    for yloop in range(N):
        A[yloop,yloop] = Atemp[yloop,yloop] - tr/N

plt.figure(3)
im = plt.matshow(A,3,cmap=plt.cm.get_cmap('seismic'))  # hsv, seismic, bwr
cbar = im.figure.colorbar(im)

M = 20
delt = 1/M
ep = 0.01;

tempx = np.zeros(shape = (3,))
for xloop in range(M):
    tempx[0] = delt*(xloop)+ep;
    for yloop in range(M-xloop):
        tempx[1] = delt*yloop+ep
        tempx[2] = 1 - tempx[0] - tempx[1]

        x0 = tempx/np.sum(tempx);          # initial populations

        tspan = 70
        t, x_t = solve_flow(x0,tspan)

        y1 = x_t[:,0]
        y2 = x_t[:,1]
        y3 = x_t[:,2]

        plt.figure(1)
        lines = plt.plot(t,y1,t,y2,t,y3)
        plt.setp(lines, linewidth=0.5)
        plt.show()
        plt.ylabel('X Position')
        plt.xlabel('Time')

        tripartite(y1,y2,y3)
	#!/usr/bin/env python3
	# -- coding: utf-8 --
	"""
	trirep.py
	Created on Thu May 9 16:23:30 2019

	@author: nolte
	Introduction to Modern Dynamics, 2nd edition (Oxford University Press, 2019)

	Population dynamics
	"""

	import numpy as np
	from scipy import integrate
	from matplotlib import pyplot as plt

	plt.close('all')

	def tripartite(x,y,z):

	sm = x + y + z
	xp = x/sm
	yp = y/sm

	f = np.sqrt(3)/2

	y0 = f*xp
	x0 = -0.5*xp - yp + 1;

	plt.figure(2)
	lines = plt.plot(x0,y0)
	plt.setp(lines, linewidth=0.5)
	plt.plot([0, 1],[0, 0],'k',linewidth=1)
	plt.plot([0, 0.5],[0, f],'k',linewidth=1)
	plt.plot([1, 0.5],[0, f],'k',linewidth=1)
	plt.show()


	def solve_flow(y,tspan):
	def flow_deriv(y, t0):
	#"""Compute the time-derivative ."""

	f = np.zeros(shape=(N,))
	for iloop in range(N):
	ftemp = 0
	for jloop in range(N):
	ftemp = ftemp + A[iloop,jloop]*y[jloop]
	f[iloop] = ftemp

	phitemp = phi0 # Can adjust this from 0 to 1 to stabilize (but Nth population is no longer independent)
	for loop in range(N):
	phitemp = phitemp + f[loop]*y[loop]
	phi = phitemp

	yd = np.zeros(shape=(N,))
	for loop in range(N-1):
	yd[loop] = y[loop]*(f[loop] - phi);

	if np.abs(phi0) < 0.01: # average fitness maintained at zero
	yd[N-1] = y[N-1]*(f[N-1]-phi);
	else: # non-zero average fitness
	ydtemp = 0
	for loop in range(N-1):
	ydtemp = ydtemp - yd[loop]
	yd[N-1] = ydtemp

	return yd

	# Solve for the trajectories
	t = np.linspace(0, tspan, 701)
	x_t = integrate.odeint(flow_deriv,y,t)
	return t, x_t

	# model_case 1 = zero diagonal
	# model_case 2 = zero trace
	# model_case 3 = asymmetric (zero trace)
	print(' ')
	print('trirep.py')
	print('Case: 1 = antisymm zero diagonal')
	print('Case: 2 = antisymm zero trace')
	print('Case: 3 = random')
	model_case = int(input('Enter the Model Case (1-3)'))

	N = 3
	asymm = 3 # 1 = zero diag (replicator eqn) 2 = zero trace (autocatylitic model) 3 = random (but zero trace)
	phi0 = 0.001 # average fitness (positive number) damps oscillations
	T = 100;


	if model_case == 1:
	Atemp = np.zeros(shape=(N,N))
	for yloop in range(N):
	for xloop in range(yloop+1,N):
	Atemp[yloop,xloop] = 2*(0.5 - np.random.random(1))
	Atemp[xloop,yloop] = -Atemp[yloop,xloop]

	if model_case == 2:
	Atemp = np.zeros(shape=(N,N))
	for yloop in range(N):
	for xloop in range(yloop+1,N):
	Atemp[yloop,xloop] = 2*(0.5 - np.random.random(1))
	Atemp[xloop,yloop] = -Atemp[yloop,xloop]
	Atemp[yloop,yloop] = 2*(0.5 - np.random.random(1))

	tr = np.trace(Atemp)
	A = Atemp
	for yloop in range(N):
	A[yloop,yloop] = Atemp[yloop,yloop] - tr/N

	else:
	Atemp = np.zeros(shape=(N,N))
	for yloop in range(N):
	for xloop in range(N):
	Atemp[yloop,xloop] = 2*(0.5 - np.random.random(1))

	tr = np.trace(Atemp)
	A = Atemp
	for yloop in range(N):
	A[yloop,yloop] = Atemp[yloop,yloop] - tr/N

	plt.figure(3)
	im = plt.matshow(A,3,cmap=plt.cm.get_cmap('seismic')) # hsv, seismic, bwr
	cbar = im.figure.colorbar(im)

	M = 20
	delt = 1/M
	ep = 0.01;

	tempx = np.zeros(shape = (3,))
	for xloop in range(M):
	tempx[0] = delt*(xloop)+ep;
	for yloop in range(M-xloop):
	tempx[1] = delt*yloop+ep
	tempx[2] = 1 - tempx[0] - tempx[1]

	x0 = tempx/np.sum(tempx); # initial populations

	tspan = 70
	t, x_t = solve_flow(x0,tspan)

	y1 = x_t[:,0]
	y2 = x_t[:,1]
	y3 = x_t[:,2]

	plt.figure(1)
	lines = plt.plot(t,y1,t,y2,t,y3)
	plt.setp(lines, linewidth=0.5)
	plt.show()
	plt.ylabel('X Position')
	plt.xlabel('Time')

	tripartite(y1,y2,y3)