# Creating a exponential function in python [closed]

I want to write a function that takes a single floating-point parameter x and returns the value of the function e(to the power of x) . Using the Taylor series expansion to compute the return value, using a loop that terminates when the partial sum SN+1 of Eq. (2) is equal to SN.

Dont know how to make to the power of so i'm putting in a link to the Wikipedia article for the Taylor Series.

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## closed as not a real question by Mat, Eitan T, j0k, pad, JunuxxSep 23 '12 at 12:51

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Could you tell us more about what part you are stuck on? Seems to me you just implement this function with a check for when a value is sufficiently close to the previous. upload.wikimedia.org/wikipedia/en/math/c/3/a/… –  Alex A. Aug 20 '12 at 12:37
Welcome to stackoverflow! Please put down your efforts so far into the post, so people could help you. –  Rostyslav Dzinko Aug 20 '12 at 12:39

Constantinius has a good answer, but I thought I would add that the python shortcut for exponentiation is **.

E.g.

`````` >>>2**3
8
``````

Note however that e**x is handled differently than math.exp(x):

`````` >>>math.e**3
20.085536923187664
>>> math.exp(3)
20.085536923187668
``````
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Is either of them (`math.e**x` vs `math.exp(x)`) more correct than the other? Why? Thanks! –  shootingstars Jun 14 '13 at 15:33
I would assume math.exp is the better choice: The pow() function (which is what ** is a shortcut for) converts both items to the same type as its first step, which means that math.e will be rounded to float(2.718281828459045) immediately. This seems like a lot of precision, but the rounding error will become more and more important with higher exponents. I don't know the internals, but I would guess that the math.exp algorithm produces the actual value of e^x and then converts that result into a float. So the difference is probably that one rounds before and the other rounds afterwards. –  blackfedora Jul 9 '13 at 17:19

Imho there is no need to implement what is already there.

``````import math

math.exp(x) # equivalent to e ^ x
``````

but if you insist, there is the `pow` function also:

``````import math

math.pow(x, y) # equivalent to x ^ y
``````
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Which part of this implements the Taylor series? –  Ignacio Vazquez-Abrams Aug 20 '12 at 12:32
the question was where to find the power function. Not how to implement the taylor series. At least thats how I understood the question. –  Constantinius Aug 20 '12 at 12:32
There is a need to reinvent the wheel if doing so is your homework assignment... –  Esoteric Screen Name Aug 20 '12 at 13:56
@EsotericScreenName: There was no mention that the question was in a context of a homework. The tag `homework` was not added by the OP and after I answered the question. From the given information I assumed that the OP was indeed unnecessarily trying to reinvent the wheel. –  Constantinius Aug 20 '12 at 14:05

the taylor series developed at 0 is:

f(x) = exp(0) + exp(0)/1*x + exp(0)/(1*2)*x^2 + exp(0)/(1*2*3)*x^3 + exp(0)/(1*2*3*4)*x^4 + ...

= 1 + x + 1/2*x^2 + 1/6*x^3 + 1/24*x^4 +...

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This doesn't answer the question at all. The OP is clearly familiar with the Taylor series already; the question is about how to code it. –  Esoteric Screen Name Aug 20 '12 at 13:54