# algorithm to find derivative

I'm writing program in Python and I need to find the derivative of a function (a function expressed as string).

• For example: `x^2+3*x`
• Its derivative is: `2*x+3`

Are there any scripts available, or is there something helpful you can tell me?

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Do you mean "Derivative" of a function? –  gn22 Nov 22 '09 at 20:26
@Gurdas Nijor: Derivative is an equation often used in Calculus to determine the tangent of a given point in a function. en.wikipedia.org/wiki/Derivative –  Spoike Nov 22 '09 at 21:04
your talking about the same. The derivative of a funtion, for any given value x will yield the tangents slope. Transforming that into a tangent function is trivial. –  Johannes Rudolph Nov 22 '09 at 21:55

sympy does it well.

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If you are limited to polynomials (which appears to be the case), there would basically be three steps:

1. Parse the input string into a list of coefficients to x^n
2. Take that list of coefficients and convert them into a new list of coefficients according to the rules for deriving a polynomial.
3. Take the list of coefficients for the derivative and create a nice string describing the derivative polynomial function.

If you need to handle polynomials like `a*x^15125 + x^2 + c`, using a `dict` for the list of coefficients may make sense, but require a little more attention when doing the iterations through this list.

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Symbolic Differentiation is an impressive introduction to the subject-at least for non-specialist like me :) The code is written in C++ btw.

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Look up automatic differentiation. There are tools for Python. Also, this.

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You may find what you are looking for in the answers already provided. I, however, would like to give a short explanation on how to compute symbolic derivatives.

The business is based on operator overloading and the chain rule of derivatives. For instance, the derivative of `v^n` is `n*v^(n-1)dv/dx`, right? So, if you have `v=3*x` and `n=3`, what would the derivative be? The answer: if `f(x)=(3*x)^3`, then the derivative is:

``````f'(x)=3*(3*x)^2*(d/dx(3*x))=3*(3*x)^2*(3)=3^4*x^2
``````

The chain rule allows you to "chain" the operation: each individual derivative is simple, and you just "chain" the complexity. Another example, the derivative of `u*v` is `v*du/dx+u*dv/dx`, right? If you get a complicated function, you just chain it, say:

``````d/dx(x^3*sin(x))
u=x^3; v=sin(x)
du/dx=3*x^2; dv/dx=cos(x)
d/dx=v*du+u*dv
``````

As you can see, differentiation is only a chain of simple operations.

If you can write a parser (try Pyparsing) then you can request it to evaluate both the function and derivative! I've done this (using Flex/Bison) just for fun, and it is quite powerful. For you to get the idea, the derivative is computed recursively by overloading the corresponding operator, and recursively applying the chain rule, so the evaluation of `"*"` would correspond to u*v for function value and `u*der(v)+v*der(u)` for derivative value (try it in C++, it is also fun).

So there you go, I know you don't mean to write your own parser - by all means use existing code (visit www.autodiff.org for automatic differentiation of Fortran and C/C++ code). But it is always interesting to know how this stuff works.

Cheers,

Juan

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Here is an article about derivative calculation I found useful.

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Unless any already made library deriving it's quite complex because you need to parse and handle functions and expressions.

Deriving by itself it's an easy task, since it's mechanical and can be done algorithmically but you need a basic structure to store a function.

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You can try creating a class that will represent a limit rigorously and then evaluate it for (f(x)-f(a))/(x-a) as x approaches a. That should give a pretty accurate value of the limit.

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