# Numerical errors : absolute error and absolute relative error?

I would like to understand how absolute and relative errors work with an example. I will need later an algorithm so I'd appreciate your help.

Suppose, we have `x1*=4.54 x2*=3.00` and `x3*=15.0` with accuracy of 3 digits.
What is a.the absolute error of `x1*-x2*+x3*` and
b.the absolute relative error of `x1*x2*/x3*`?

What is the accuracy in both examples ?

My thoughts : a.

``````|e1|<=0.5*10^(-3)

|e2|<=0.5*10^(-3)

|e3|<=0.5*10^(-3)
``````

or

``````|e1|<=0.5*10^(-2)

|e2|<=0.5*10^(-2)

|e3|<=0.5*10^(-1)
``````

and then `|e|<=|e1|+|e2|+|e3|=(15+4+3)*0.5*10^(-3)`

b. `|r|<=|r1|+|r2|+|r3|=|e1/x1*|+|e2/x2*|+|e3/x3*|`

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There's an absolute error and a relative error. What is an "absolute relative error"? O_O –  Eitan T Dec 2 '12 at 12:50
what do you mean by the stars at the end of x1, x2 and x3? –  Barnabas Szabolcs Dec 2 '12 at 14:09
Relative error : |(x-x*)/x| , absolute error : |x-x*| maybe my mistake ..Any help ? –  i z Dec 3 '12 at 13:39

You're on the right track. Of course you can't find the actual error because you don't know the actual values. Thus you want to constrain the error. First note that we're talking about rounding error (as you've done), thus the maximum that each variable can be off by is 0.5 of its precision, i.e.

|e1| <= 0.005

|e2| <= 0.005

|e3| <= 0.05

For the absolute error of x1-x2+x3, the worst case is that all of the errors add together linearly, I.e.:

|e123| <= 0.005+0.005+0.05 = 0.06.

Because it's absolute error, you don't have to rescale by what the actual values of x1... are.

For the relative error of (x1x2)/x3, it's a little more complicated--you have to actually propogate (multiply) out the error. But, if you assume that the error is much smaller than the value, i.e. |e1| << x1 (which is a good approximation for this case), then you get the equation that you used in 'b':

|r| = |r123 / (x1x2/x3) | ~< |e1/x1| + |e2/x2| + |e3/x3|

Because this is relative error, you do have to rescale the errors by the actual values.

So, overall, you just about had it right --- just a little trouble with the `absolute error`.

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