import random
import numpy as np
import matplotlib.pyplot as plt
import math
def randpath(tt):
b=[]
bb=[]
b.append(0)
bb.append(0)
b2=[]
for i in range(tt):
c=random.random()
bb.append(i+1)
b.append(b[-1]-1+2*c)
for j in range(len(b)):
b2.append(b[j])
return b,bb,b2
a,b,c=randpath(1000)
a1,b1,c1=randpath(1000)
for k in range(len(b)):
plt.scatter([b[k],],[c[k],], 7, color ='red')
plt.scatter([b1[k],],[c1[k],], 7, color ='blue')
plt.xlim(0,1000)
plt.xlabel('time/step number')
plt.ylabel('X')
plt.title('random walk in one dimesion')
plt.show()
"""
c22=[]
c11=[0]*101
for i in range(100000):
a1,b1,c1=randpath(100)
for j in range(len(a1)):
c11[j]=c11[j]+c1[j]/100000.0
for k in range(len(b1)):
plt.scatter([b1[k],],[c11[k],],7,color='blue')
plt.scatter([b1[k],],[a1[k],], 3, color ='orange')
print len(b1),len(c11),len(a1)
z1=np.polyfit(b1, c11,1)
for i in range(len(b1)):
c22.append(z1[0]*b1[i]+z1[1])
plt.plot(b1,c22,color='red',label='y=0.3354*x+0.0102')
plt.xlim(0,100)
plt.ylim(0,)
plt.xlabel('time/step number')
plt.ylabel('the average square distance')
plt.title('random walk in one dimesion')
plt.legend(loc='upper left', frameon=True)
print z1
plt.show()
"""
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