import numpy as np
import matplotlib.pyplot as plt
from plotstyle import *
def hompoisson(rate, trials, duration) :
spikes = []
for k in range(trials) :
times = []
t = 0.0
while t < duration :
t += np.random.exponential(1/rate)
times.append( t )
spikes.append( times )
return spikes
def inhompoisson(rate, trials, dt) :
spikes = []
p = rate*dt
for k in range(trials) :
x = np.random.rand(len(rate))
times = dt*np.nonzero(x<p)[0]
spikes.append( times )
return spikes
def pifspikes(input, trials, dt, D=0.1) :
vreset = 0.0
vthresh = 1.0
tau = 1.0
spikes = []
for k in range(trials) :
times = []
v = vreset
noise = np.sqrt(2.0*D)*np.random.randn(len(input))/np.sqrt(dt)
for k in range(len(noise)) :
v += (input[k]+noise[k])*dt/tau
if v >= vthresh :
v = vreset
times.append(k*dt)
spikes.append( times )
return spikes
def isis( spikes ) :
isi = []
for k in range(len(spikes)) :
isi.extend(np.diff(spikes[k]))
return np.array( isi )
def plotreturnmap(ax, isis, lag=1, max=None) :
ax.set_xlabel(r'ISI$_i$', 'ms')
ax.set_ylabel(r'ISI$_{i+1}$', 'ms')
if max != None :
ax.set_xlim(0.0, 1000.0*max)
ax.set_ylim(0.0, 1000.0*max)
ax.scatter(1000.0*isis[:-lag], 1000.0*isis[lag:], c=colors['blue'])
# parameter:
rate = 20.0
drate = 50.0
trials = 10
duration = 10.0
dt = 0.001
tau = 0.1;
# homogeneous spike trains:
homspikes = hompoisson(rate, trials, duration)
# OU noise:
rng = np.random.RandomState(54637281)
time = np.arange(0.0, duration, dt)
x = np.zeros(time.shape)+rate
n = rng.randn(len(time))*drate*tau/np.sqrt(dt)+rate
for k in range(1,len(x)) :
x[k] = x[k-1] + (n[k]-x[k-1])*dt/tau
x[x<0.0] = 0.0
# pif spike trains:
inhspikes = pifspikes(x, trials, dt, D=0.3)
fig, (ax1, ax2) = plt.subplots(1, 2)
fig.subplots_adjust(**adjust_fs(fig, left=6.5, top=1.5))
ax1.set_title('stationary')
plotreturnmap(ax1, isis(homspikes), 1, 0.3)
ax2.set_title('non-stationary')
plotreturnmap(ax2, isis(inhspikes), 1, 0.3)
plt.savefig('returnmapexamples.pdf')
plt.close()