# Simplify a series in Mathematica

I'm having some issues simplifying some functions in mathematica. In a program I wrote I have a few functions calculated with the Sum function, many of the terms end up being multiplied by zero. I want the function to be printed but simplified. I try using FullSimplify, but it takes forever to run. I then tried using Simplify, but it doesn't work. Here is an example of a function I'm getting,

``````2. Sqrt[-(-1+x) x]+
0. Sin[2 ArcCos[-1+2 x]]+
0. Sin[3 ArcCos[-1+2 x]]+
0. Sin[4 ArcCos[-1+2 x]]+
0. Sin[5 ArcCos[-1+2 x]]+
0. Sin[6 ArcCos[-1+2 x]]+
0. Sin[7 ArcCos[-1+2 x]]+
0. Sin[8 ArcCos[-1+2 x]]+
0. Sin[9 ArcCos[-1+2 x]]+
0. Sin[10 ArcCos[-1+2 x]]+
0. Sin[11 ArcCos[-1+2 x]]+
0. Sin[12 ArcCos[-1+2 x]]+
0. Sin[13 ArcCos[-1+2 x]]+
0. Sin[14 ArcCos[-1+2 x]]+
0. Sin[15 ArcCos[-1+2 x]]+
0. Sin[16 ArcCos[-1+2 x]]+
0. Sin[17 ArcCos[-1+2 x]]+
0. Sin[18 ArcCos[-1+2 x]]+
0. Sin[19 ArcCos[-1+2 x]]+
0. Sin[20 ArcCos[-1+2 x]]+
0. Sin[21 ArcCos[-1+2 x]]+
0. Sin[22 ArcCos[-1+2 x]]+
0. Sin[23 ArcCos[-1+2 x]]+
0. Sin[24 ArcCos[-1+2 x]]+
0. Sin[25 ArcCos[-1+2 x]]+
0. Sin[26 ArcCos[-1+2 x]]
``````

So, why wouldn't this simplify to

``````2. Sqrt[-(-1+x) x]
``````

I also have a follow up question that is not exactly as important. But, lets say four of those terms have non-zero coefficients, is it possible to combine them into one term that is a numerical approximation of the original?

Thanks to anyone that replies!

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Could you clarify your second question somewhat? – Sjoerd C. de Vries Jun 29 '11 at 21:35
I think you could simplify your question. Try `0.+x` – belisarius has settled Jun 29 '11 at 21:35
@Sjoerd Take a look at stackoverflow.com/questions/6459872/… – belisarius has settled Jun 29 '11 at 21:37
@Silmaril89: You say "approximate" but don't tell use how well it should approximate (i.e. to what order). You can always expand each term in terms of its Taylor series (use `Series[]`) and keep say the first `n` terms from each, and combine them all into one giant term with a humungous numerator and denominator (use `Together[]`). Again, this is stretching the meaning of the word "term" :) – abcd Jun 29 '11 at 23:36
@Silmaril89: Also look into `TrigExpand`, which uses trigonometric identities to expand the functions. For e.g., `Sin[2 ArcSin[x]]` is `2 x Sqrt[1 - x^2]`, `Sin[3 ArcSin[x]]` is `3 x - 4 x^3` – abcd Jun 29 '11 at 23:41

Say hello to machine precision.

``````(* exact *)
0 Sin[x]
Out[1]= 0

(* machine precision *)
0. Sin[x]
Out[2]= 0. Sin[x]
``````

Use `Chop` to set numbers absurdly close to zero, to 0 exactly.

``````expr = 2. Sqrt[-(-1 + x) x] + 0. Sin[2 ArcCos[-1 + 2 x]] +
0. Sin[3 ArcCos[-1 + 2 x]] + 0. Sin[4 ArcCos[-1 + 2 x]] +
0. Sin[5 ArcCos[-1 + 2 x]] + 0. Sin[6 ArcCos[-1 + 2 x]] +
0. Sin[7 ArcCos[-1 + 2 x]] + 0. Sin[8 ArcCos[-1 + 2 x]] +
0. Sin[9 ArcCos[-1 + 2 x]] + 0. Sin[10 ArcCos[-1 + 2 x]] +
0. Sin[11 ArcCos[-1 + 2 x]] + 0. Sin[12 ArcCos[-1 + 2 x]] +
0. Sin[13 ArcCos[-1 + 2 x]] + 0. Sin[14 ArcCos[-1 + 2 x]] +
0. Sin[15 ArcCos[-1 + 2 x]] + 0. Sin[16 ArcCos[-1 + 2 x]] +
0. Sin[17 ArcCos[-1 + 2 x]];

Chop[expr]
Out[4]= 2. Sqrt[(1 - x) x]
``````
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Welcome to the 10K club! – belisarius has settled Jul 1 '11 at 17:43
@belisarius: Thanks :) – abcd Jul 1 '11 at 17:47
An interesting "trick" is to take a 10 digit calculator and enter 1E12 + 1 - 1E12. If the 1 is any position, but the last one, it will return 0. You can do the same with mma, although its precision is higher. On my machine, `1.*10^16 + 1. - 1.*10^16` gives 0. Note the decimal points, if all of them are removed, mma reverts to exact arithmetic and gives 1. Also, if the first terms in an expression are large, mma will sometimes ignore the small terms: see the last example here. – rcollyer Jul 12 '11 at 14:04

Behind those "0." terms there are hidden some very tiny (but non-zero) numbers. You can slash them using `Chop`.

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Thanks for the reply, makes perfect sense. You deserve the check mark just as much as yoda, but I have to choose one of you. – Silmaril89 Jun 29 '11 at 21:51
Yoda was the better one here. I don't think my phrasing here was even technically correct. – Sjoerd C. de Vries Jun 29 '11 at 21:54