I am trying to solve this differential equation with the Euler Method using Python3:

According to Wolfram Alpha, that's the plot of the correct equation.

Again, according to Wolfram Alpha, in this case, the classic Euler Method should **not** be stable, as you can see by the end of the interval:

However, on my implementation, Euler method provides a stable result, which **is strange**. I wonder that my implementation is wrong for some reason. Nonetheless, I can't find the error.

I generated some points and a plot comparing my approximation and the analytic output of the function. In blue, the analytic result as control group. In red, the output of my implementation:

That's my code:

```
import math
import numpy as np
from matplotlib import pyplot as plt
import pylab
def f(x):
return (math.e)**(-10*x)
def euler(x):
y_init = 1
x_init = 0
old_dy_dx = -10*y_init
old_y = y_init
new_y = None
new_dy_dx = None
delta_x = 0.001
limite = 0
while x>limite:
#for i in range(1,6):
new_y = delta_x*old_dy_dx + old_y
#print ("new_y", new_y)
new_dy_dx = -10*new_y
#print ("new dy_dx", new_dy_dx)
old_y = new_y
#print ("old_y", old_y)
old_dy_dx = new_dy_dx
#print ("old delta y_delta x", old_dy_dx)
#print ("iterada",i)
limite = limite +delta_x
return new_y
t = np.linspace(-1,5, 80)
lista_outputs = []
for i in t:
lista_outputs.append(euler(i))
print (i)
# red dashes, blue squares and green triangles
plt.plot(t, f(t), 'b-', label='Output resultado analítico')
plt.plot(t , lista_outputs, 'ro', label="Output resultado numérico")
plt.title('Comparação Euler/Analítico - tolerância: 0.3')
pylab.legend(loc='upper left')
plt.show()
```

Thanks for the help.

============================================================

**UPDATE**

With @SourabhBhat help, I was able to see that my implementation was, actually, right. It was, indeed, generating an instability. Besides increasing the step size, I needed to do some zoom in to see it happening.

The picture bellow speaks for itself (step size of 0.22):