Of course, and I hope that you can understand my scruples, I prefer to leave my answer as generic as possible while trying to help you.
If you cannot use Numpy1, you have to use the math module and old good lists.
You start importing math
from the standard library and the pyplot
module from Matplotlib:
import math
import matplotlib.pyplot as plt
You decide the interval in which you plot your function and how many points you need for your plot
x_0, x_N = 0, 12
N =120
N
is best intended as the number of intervals between N+1 points, so that we write
dx = (x_N-x_0)/N
Now we can say x_i = x_0 + dx × i
but we have to store our results so that they are reusable. It's now that we have to use a list and we have two options, ① start with an empty list and append
to it all the x_i
using a for
loop
xs = []
for i in range(N+1): xs.append(x_0+dx*i)
and ② a list comprehension
xs = [ x_0+dx*i for i in range(N+1) ]
(the result is identical).
You now have fixed the problem of the abscissae, it's the turn of the ordinates; again, we can use the append
or the list comprehension
ys = []
for i in range(N+1):
x = xs[i]
y = math.sin(x/3.805)
ys.append(y)
or
ys = [ math.sin(xs[i]/3.805) for i in range(N+1) ]
Now you can plot the function
plt.plot(xs, ys, label='sin(%.3fx)'%(1/3.805))
plt.legend()
plt.grid()
plt.show()
(1) You cannot use Numpy but, but Matplotlib will use Numpy behind the scenes...
The lists that you pass to plt.plot
are immediately converted to Numpy arrays! and only later are processed by the complex machinery of the plotting module.
x
of N+1 x points, evenly spaced between 0 and x* ...dx = x_last/N
etc etca, b, delta
with some real numbers.a, b, d and x*
suitable for testing.