Note to closers : This is a question about a Programming language (Mathematica), and not about a discipline/science (mathematics).
Why is
N[D[Sin[x], x] /. x -> Pi/4]
(*
Out -> 0.707107
*)
but
N[D[Abs[x], x] /. x -> Pi/4]
(*
Out -> Derivative[1][Abs][0.785398]
*)
?
And what is the better way to force a numerical result?
Abs[z] is not a holomorphic function, so its derivative is not well defined on the complex plane (the default domain that Mathematica works with). This is in contradistinction to, e.g., Sin[z], whose complex derivative (i.e., with respect to its argument) is always defined.
More simply put, Abs[z] depends on both z and z*, so should really be thought as a two argument function. Sin[z] only depends on z, so makes sense with a single argument.
As pointed out by Leonid, once you restrict the domain to the reals, then the derivative is well defined (except maybe at x=0, where they've taken the average of the left and right derivatives)
In[1]:= FullSimplify[Abs'[x],x \[Element] Reals]
Out[1]= Sign[x]
As pointed out by Szabolcs (in a comment), FunctionExpand will simplify the numerical expressions, but "Some transformations used by FunctionExpand are only generically valid".
ComplexExpand also gives numeric results, but I don't trust it. It seems to take the derivative assuming the Abs is in the real domain, then substitutes in the numeric/complex arguments. That said, if you know that everything you're doing is in the reals, then ComplexExpand is your friend.
Abs'[.42] = Limit[(Abs[z+.42] - Abs[.42])/z, z->0] and the limit is not the same in all complex directions. Consider the path z[t_] := 1-Exp[I t] As t->0, z[t]->0 and the limit/derivative in this direction is always zero. (This is basically reiterating my answer... oh well)
Abs[x] isn't analytic, since obviously the Cauchy-Riemann conditions can't be satisfied. My comment was based on believing that mma would pretend only the real line existed if one used reals as arguments in functions other than Abs, so this would be inconsistent. However I just tried Re'[.42] and so on and they also remain unevaluated (while I thought I remembered it being evaluated to 1), so I guess I simply remembered something else...
I refer you to this thread as possibly relevant - this issue has been discussed before. To summarize my answer there, Abs is defined generally on complex numbers. Once you specify that your argument is real, it works:
In[1]:= FullSimplify[Abs'[x], Assumptions -> {Element[x, Reals]}]
Out[1]= Sign[x]
FunctionExpand seems to always work, FullSimplify works on integers but not reals.
Jun 13, 2011 at 13:58
N is applied, it should have given a numeric answer.
Jun 13, 2011 at 14:00
FunctionExpand seems to be making an (almost reasonable) assumption about the domain.
You can use FunctionExpand to force getting a number as a result even when you are using exact quantities:
Abs'[Pi/4] // FunctionExpand
Abs'[-1] // FunctionExpand
I do not know the reason for the following though:
In:= Abs'[0] // FunctionExpand
Out= 0
Sign[x], as long as we agree that Abs'[x] == Sign[x] for real x.
Jun 13, 2011 at 13:49
Abs'[x] is expanded to Sign[x]: FunctionExpand[Abs'[x], Assumptions -> x \[Element] Reals]
EuclideanDistancethat useAbs[ ]