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I have been wrapping my head around this for a while now and I have not found a solution so far. I want to work with an arbitrary number of variables in mathematica and use some built in functions.

To make things more specific for starters I want to do the following:

Define a sum with n summands each containing a new variable x[i] (in the i-th summand):

sum[n_] = Sum[i*x[i], {i, 1, n}]

Then I want to differentiate the expression with respect to some x[i] like:


Mathematica returns 0 instead of 2.

If I supply a specific n like:


everything works fine.

I thought about using Assumptions for n, but with no success so far.

How can I do that right?

share|improve this question
Evaluating D[sum[n], x[2]] is essentially the same as evaluating D[Sum[n, y], x[2]], where y is value-free, which is nothing D recognizes as depending on x[2]. – m_goldberg Dec 15 '12 at 16:10
This question is closely related to and might even be considered a duplicate of this one – m_goldberg Dec 15 '12 at 16:25
Extending Mathematica to allow sums of symbolic length really would require extended it to allow lists of symbolic length; only then could one properly worry about differentiating such objects. But how to make a robust, general design for such an extension is hardly obvious and raises all sorts of issues, e.g.: Should Infinity to an acceptable value for n? What would the effect be upon processing speed for specific-length objects? – murray Dec 15 '12 at 17:41
I've changed your title to something more specific. please change it to something else if you think it's better – acl Dec 15 '12 at 19:39
For formal differentiation, what I've noticed is if it's in a tuxedo it's probably a guy, and if it's in a gown it's usually a gal. But this is only a rough guideline, and anyway times have changed. – Daniel Lichtblau Dec 15 '12 at 22:15
up vote 29 down vote accepted

Here is the simplest answer:

sum[n_] := Sum[i x[i], {i, 1, n}]

x /: D[x[i_], x[j_], NonConstants -> {x}] := 
 KroneckerDelta[i, j]

D[sum[n], x[2], NonConstants -> x]

$\begin{cases} 2 & n>1 \\ 1-n & \text{True} \end{cases}$

The trick here is the use of the NonConstants option of the derivative operator. This then has to be combined with a definition stating that the x[i] are independent variables for the purposes of this differentiation (hence the KroneckerDelta on the second line).

Edit: more discussion

And here is another cool result, completely symbolic:

Assuming[m ∈ Integers, D[sum[n], x[m], NonConstants -> x]]

$\left( \begin{array}{cc} \{ & \begin{array}{cc} m & m\geq 1 \\ 0 & \text{True} \\ \end{array} \\ \end{array} \right)-\left( \begin{array}{cc} \{ & \begin{array}{cc} m & m>2\land m\geq n+1 \\ n+1 & m=2\land n=1 \\ \end{array} \\ \end{array} \right)$

This isn't easy to absorb, but it works if you check it with specific examples by doing

condition = %;

Simplify[condition /. m -> 10]

$\begin{cases} 10 & n>9 \\ 0 & \text{True} \end{cases}$

In summary, it's worth pointing out that a lot of symbolic differentiation tasks can be achieved by using either NonConstants specifications in D or conversely using Constants specifications in Dt.

share|improve this answer
This is really helpful. Thank you very much. – Wizard Dec 22 '12 at 17:03
It might be worth mentioning that when doing this with more than one variable (say $x$ and $y$), it is necessary to have them Sorted in the NonConstants rule for the UpValue of the variables, otherwise it won't find a match when trying to evaluate D (and leave it unevaluated). – Joel Bosveld Jun 17 '15 at 7:44
sorry if this a super newbie question, but why does it say $1-n$ for...true? :/ What does that condition even mean? – Pinocchio Aug 7 '15 at 19:58
@Pinocchio True is the entry that humans would call "otherwise" - it's the default alternative if none of the above holds. – Jens Aug 7 '15 at 20:05
@Jens I see what true means now (weird, the programmer could have just said otherwise in a print statement...). But, how is the derivative wrt x[2] be 1 - n for n < 1? for n<1 the sum doesn't even wouldn't technically it be the derivative of a non-existent sum (so zero), so the derivative of zero is zero? Or am I completely off? – Pinocchio Aug 7 '15 at 20:10

I did some computation of formal derivatives a while back which might be of interest in this context (though keep in mind that this is anything but bullet proof! it does work for the cases I bothered to check though).

Clear[a]; Format[a[k_]] = Subscript[a, k]

Let us say we have an objective function which is formally a function of the vector a[i]

Q = Sum[Log[Sum[a[r] Subscript[B, r][Subscript[x, i]], {r, 1, p}]/
    Sum[a[r] , {r, 1, p}]], {i, 1, n}]

Mathematica graphics

Let us define a couple of rules for formal differentiation as follows

d[Log[x_], a[k_]] := 1/x d[x, a[k]]
d[Sum[x_, y__], a[k_]] := Sum[d[x, a[k]], y]
d[ a[k_] b_., a[k_]] := b /; FreeQ[b, a]
d[ a[q_] b_., a[k_]] := b Subscript[δ, k, q] /; FreeQ[b, a]
d[ c_  b_, a[k_]] := d[c, a[k]] b + d[b, a[k]] c
d[ b_ +  c_, a[k_]] := d[c, a[k]] + d[b, a[k]]
d[Subscript[δ, r_, q_], a[k_]] := 0
d[x_, a[k_]] := 0 /; FreeQ[x, a]
 d[G_^n_, a[k_]] := n G^(n - 1) d[G , a[k]] /; ! FreeQ[G, a]
 d[Exp[G_], a[q_]] := Exp[G] d[G , a[q]] /; ! FreeQ[G, a]

Unprotect[Sum]; Attributes[Sum] = {ReadProtected};Protect[Sum];

And a rule to deal with Kroneckers

ds = {Sum[a_ + b_, {s_, 1, p_}] :> Sum[a, {s, 1, p}] + Sum[b, {s, 1, p}],
      Sum[ y_ Subscript[δ, r_, s_], {s_, 1, p_}] :> (y /. s -> r),
  Sum[ y_ Subscript[δ, s_, r_], {s_, 1, p_}] :> (y /. s -> r),
  Sum[ Subscript[δ, s_, r_], {r_, 1, p_}] :> 1,
  Sum[δ[i_, k_] δ[j_, k_] y_. , {k_, n_}] -> δ[i, j] (y /. k -> i),
  Sum[a_ b_, {r_, 1, p_}] :> a Sum[b, {r, 1, p}] /; NumberQ[a]}

Then, for instance, the gradient of Q with respect to one of the a[k] reads

grad = d[Q, a[k]]  /. ds // Simplify;

Mathematica graphics

Similarly the tensor of second derivatives w.r.t. a[k] and a[s] is given by

hess = d[d[Q, a[k]], a[s]] /. ds // Simplify

Mathematica graphics

As a less trivial example let us consider the 4th order derivatives of Q

 d[d[d[d[Q, a[k]], a[s]], a[m]], a[t]]; /. ds // Simplify

Mathematica graphics

For the problem at hand we check easily that

 Q = Sum[r a[r] , {r, 1, p}];

 grad = d[Q, a[k]] // Simplify;
 grad //. ds

returns k as it should


This process can be made a bit more general, say, on this Objective function

  Q = 1/2 Sum[(Sum[a[r] Subscript[B, r, i][a[q]], {r, 1, p}] - 
      Subscript[y, i])^2, {i, 1, n}]

Mathematica graphics

which depends non linearly on a[k] via B.

All we need is to add a new rule for d

  a[k_]] := (D[H[x] , x] /. x -> a[k] ) Subscript[δ, k, q]

Now we readily have

grad = d[Q, a[k]] // Simplify;
hess = d[d[Q, a[k]], a[s]];

grad //. ds

Mathematica graphics

hess /. ds // Simplify

Mathematica graphics

As a other example, let us look at a parametrized entropy distance,

 Q = -Sum[(Sum[a[r] Subscript[B, r, i], {r, 1, p}]/
  Subscript[y, i]) Log[(Sum[a[r] Subscript[B, r, i], {r, 1, p}]/
   Subscript[y, i])], {i, 1, n}]

Mathematica graphics

we can compute its Hessian while mapping twice the sum rule

 Map[# /. ds &, d[d[Q, a[k]], a[s]] /. ds]

Mathematica graphics

As a final example, consider a Poisson likelihood

 Q = Sum[Log[Exp[-a[k]] a[k]^Subscript[y, k]/Subscript[y, k]!], {k, 1, n}]

Mathematica graphics

so that

 grad = d[Q, a[k]] // Simplify

Mathematica graphics


  hess =d[d[Q, a[k]], a[s]]  /. ds // Simplify

Mathematica graphics

Of course these algebraic rules are not bullet proof but illustrate nicely the way mathematica handles new grammar.

share|improve this answer
@Nasser have you seen this? – Mr.Wizard Dec 15 '12 at 19:51
unfortunately, i can not replicate these results in Mathematica 10.2. I would be appreciative if someone could try to reproduce this and/or suggest edits. – Eric Brown Sep 11 '15 at 1:53

One solution might be ...

Method 1.

Define some variables:

x = Table[Unique[], {5}];

Form the inner product and differentiate:

D[Inner[Times, x, Range@Length@x], x[[2]]]


Or if you prefer it in a functional form:

sum[n_] := Inner[Times, x[[1 ;; n]], Range@n] /; ( Length@x >= n)

D[sum[4], x[[3]]]


Method 2.

You could take a different approach, but you need to be aware that it leaks variables of the form {x1,x2,x3,...} out into the general context:

sum[n_] := Inner[Times, Symbol["x" <> ToString@#] & /@ Range@n, Range@n] 


x1 + 2 x2 + 3 x3 + 4 x4 + 5 x5

D[sum3[4], x3]


share|improve this answer
This is exactly what I was trying to avoid. The exact amount of variables should not have to be specified. – Wizard Dec 22 '12 at 17:04

I like image_doctor's solution better, but how about using Array and looking for the position using that index each time? Like this:

xx = Array[x, 10, 1];
sum[n_] := Times[List @@ xx , Range[10]]

(* {x[1], 2 x[2], 3 x[3], 4 x[4], 5 x[5], 6 x[6], 7 x[7], 8 x[8], 9 x[9], 10 x[10]} *)


sum[n_] := Times[List @@ xx^4, Range[10]]
D[sum[n], xx[[5]]][[5]]
(*  20 x[5]^3 *)


sum[n_] := Times[List @@ xx, Range[10]]
D[sum[n], xx[[2]]][[2]]

(* 2 *)

It is kinda clumsy though. The problem, of course, is that one can't treat

enter image description here

as a single variable as we do on paper. P.S., I tried to see if one can do this in Maple and could not do it directly as you wanted. Had to do a hack as above. (But I do not know Maple much, though.)

share|improve this answer
Nasser, if it matters to you, your "gravatar" is changing along with your I.P. address. You can make it a fixed one by entering an email address in your profile. This email is only visible to moderators and furthermore it doesn't need to be a real one anyway. Also see: – Mr.Wizard Dec 15 '12 at 19:42

A possible solution is to use the fact that Mathematica can easily take the derivative of an actual sum, but has problems with the symbolic one. In order to take the derivative on j-th term of a sum, we extract from the sum few terms centered around j. The number of extracted terms is equal to 2*dj+1. There is one drawback of this solution that you can always differentiate on j-th term. This method works with subscripted variables as well.

s1 = Sum[p[k]*a[k + 1] + p[k + 1]*a[k], {k, 1, nn}];
derivSum[s0_, xj_, dj_] := Block[{k, j}, D[Sum[s0[[1]], {k, j - dj, j + dj}], xj]];
derivSum[s1, p[j], 4]
(* a[-1+j]+a[1+j] *)
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