lookfwd · May 13, 2024 20:08
diff --git a/adex-model-in-python.py b/adex-model-in-python.py
 # This is a draft of a Python version of the code of this video: https://www.youtube.com/watch?v=8lDF0acgRdI&list=PLn0OLiymPak1b2aYULx6hDVU7wSGEUJqw&index=17
 # Disclaimer: The output looks similar-enough to me. Certainly there are off-by-one differences and there might be other differences too
 import math
 import numpy as np
 import matplotlib.pyplot as plt

 # Part 1. Setup

 SIMULATION_DURATION = 500  # Simulation time in ms
 dt = 0.01  # descretization in ms

 IMax = 500  # pA


 def _t(t):
    return int(t / dt)


 timevec = np.arange(0, SIMULATION_DURATION, dt)

 Iinput = np.zeros(_t(SIMULATION_DURATION))
 Iinput[_t(100) : _t(400)] = IMax

 # Part 2. Constants

 C = 200  # Capacitance
 gl = 10  # Leak conductance
 El = -58  # Leak voltage
 vt = -50  # Resting membrane potential
 delT = 2  # Spike width factor
 a = 2  # Resonator/integrator variable
 tauW = 120  # Adaptation decay time
 b = 100  # Adaptation jump (update for w)
 vreset = -46  # Voltage reset

 # Part 3. Simulation

 membPoten = np.zeros(_t(SIMULATION_DURATION))
 vpeak = 0  # spike threshold

 for timei in range(_t(SIMULATION_DURATION)):
    if timei == 0:
        v = vt
        w = 0
    else:
        Iin = Iinput[timei]
        v += dt * (-gl * (v - El) + gl * delT * math.exp((v - vt) / delT) + Iin - w) / C
        w += dt * (a * (membPoten[timei - 1] - El) - w) / tauW

    if v >= vpeak:
        v = vreset
        w = w + b
    else:
        membPoten[timei] = v

 # Part 4. Plot

 fig, ax1 = plt.subplots()

 l2 = ax1.plot(timevec, membPoten, color="b", label="membPoten")
 ax1.set_ylabel("Membrane Voltage (mV)")

 ax2 = ax1.twinx()
 l1 = ax2.plot(timevec, Iinput, color="g", label="Iinput")
 plt.ylim(0, 5000)
 ax2.set_ylabel("Iinput Current (pA)")


 plt.xlabel("Time (ms)")
 plt.title("Iinput vs Time and MembPoten vs Time")

 ax1.legend(handles=l1 + l2)
	# This is a draft of a Python version of the code of this video: https://www.youtube.com/watch?v=8lDF0acgRdI&list=PLn0OLiymPak1b2aYULx6hDVU7wSGEUJqw&index=17
	# Disclaimer: The output looks similar-enough to me. Certainly there are off-by-one differences and there might be other differences too
	import math
	import numpy as np
	import matplotlib.pyplot as plt

	# Part 1. Setup

	SIMULATION_DURATION = 500 # Simulation time in ms
	dt = 0.01 # descretization in ms

	IMax = 500 # pA


	def _t(t):
	return int(t / dt)


	timevec = np.arange(0, SIMULATION_DURATION, dt)

	Iinput = np.zeros(_t(SIMULATION_DURATION))
	Iinput[_t(100) : _t(400)] = IMax

	# Part 2. Constants

	C = 200 # Capacitance
	gl = 10 # Leak conductance
	El = -58 # Leak voltage
	vt = -50 # Resting membrane potential
	delT = 2 # Spike width factor
	a = 2 # Resonator/integrator variable
	tauW = 120 # Adaptation decay time
	b = 100 # Adaptation jump (update for w)
	vreset = -46 # Voltage reset

	# Part 3. Simulation

	membPoten = np.zeros(_t(SIMULATION_DURATION))
	vpeak = 0 # spike threshold

	for timei in range(_t(SIMULATION_DURATION)):
	if timei == 0:
	v = vt
	w = 0
	else:
	Iin = Iinput[timei]
	v += dt * (-gl * (v - El) + gl * delT * math.exp((v - vt) / delT) + Iin - w) / C
	w += dt * (a * (membPoten[timei - 1] - El) - w) / tauW

	if v >= vpeak:
	v = vreset
	w = w + b
	else:
	membPoten[timei] = v

	# Part 4. Plot

	fig, ax1 = plt.subplots()

	l2 = ax1.plot(timevec, membPoten, color="b", label="membPoten")
	ax1.set_ylabel("Membrane Voltage (mV)")

	ax2 = ax1.twinx()
	l1 = ax2.plot(timevec, Iinput, color="g", label="Iinput")
	plt.ylim(0, 5000)
	ax2.set_ylabel("Iinput Current (pA)")


	plt.xlabel("Time (ms)")
	plt.title("Iinput vs Time and MembPoten vs Time")

	ax1.legend(handles=l1 + l2)