# How to get mathematica to carry out a Sum when only part of it is defined?

I'm having a sum like this:

Sum[1 + x[i], {i, 1, n}]

Mathematica doesn't simplify it any more. What would I need to do so it translates it into:

n + Sum[x[i],{i,1,n}]
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I don't believe it will do this automatically. Perhaps if you described why you need this, or post your actual problem, then we could help –  Szabolcs Nov 3 '11 at 9:22
I don't see what the problem with this function. Sum[1,{i,1,N}] evaluates I would expect it to N. In my case I want to calculate error propagation so the specific funtion would be: Sum[sigma+(x[i]-X)^2,{i,1,N}]. –  bdecaf Nov 3 '11 at 9:29
Is the issue that you are using N as the end parameter, which has a special meaning in Mathematica? Try small n instead. –  Verbeia Nov 3 '11 at 11:49
ok - fixed n to small. To be honest I'm very confused now as this transformations seems so easy on the paper and is so complicated in Mathematica. –  bdecaf Nov 3 '11 at 12:54
Mathematica, while capable of quite a lot, is just a giant calculator that happens to be able to do algebra. So, while some things are simple, others can be more complex, often maddeningly so. Try to separate a function into real and imaginary parts, sometime, especially if they have numerical coefficients, like 1 + I. Also, don't be so hasty to simplify, sometimes the simplification can cause you to miss something, and that is why Mathematica is very conservative in the simplifications it employs. –  rcollyer Nov 3 '11 at 16:18

Maybe this?

Distribute[Sum[1 + x[i], {i, 1, n}]]

which returns:

n + Sum[x[i], {i, 1, n}]
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AFAIK Sum simply won't give partial answers. But you can always split off the additive part manually, or semi-automatically. Taking your example,

In[1]:= sigma + (x[i] - X)^2 // Expand

Out[1]= sigma + X^2 - 2 X x[i] + x[i]^2

There's nothing we can do with the parts that contain x[i] without knowing anything about x[i], so we just split off the rest:

In[2]:= Plus @@ Cases[%, e_ /; FreeQ[e, x[i]]]

Out[2]= sigma + X^2

In[3]:= Sum[%, {i, 1, n}]

Out[3]= n (sigma + X^2)

Unrelated: It is a good idea never to use symbols starting with capital letters to avoid conflicts with builtins. N has a meaning already, and you shouldn't use it as a variable.

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A quick and dirty way would be to use Thread, so for example

Thread[Sum[Expand[sigma + (x[i] - X)^2], {i, 1, n}], Plus, 1]
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A simpler way would be

Total[Sum[#, {i, 1, n}] & /@ {sigma, x[i]}]

If your expression is longer, this should give you the answer without having to manually split the terms

expr = sigma + (x[i] + i)^2 + Cos[Sin[i - x[i]]];
Total[Sum[#, {i, 1, n}] & /@ Level[expr, {1}]]

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This can also be done in an easy to understand manner with rules:

sumofsumsrule = Sum[a_+b_,{i_,c_,d_}] :> Sum[a,{i,c,d}]+Sum[b,{i,c,d}];
expandsummandrule = Sum[a_,{i_,c_,d_}] :> Sum[Expand[a],{i,c,d}];
MyRules = {sumofsumsrule, expandsummandrule};

Now, if you are messing around, you can use this (here are some examples):

error = Sum[sigma+(x[i]-X)^2,{i,1,n}]

error /. sumofsumsrule

% /. expandsummandrule

error //. MyRules
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