Mathematics
functions of
several variables
functions of
several variables
Partial derivatives
Differential
Linear approximation
Error calculation
Extrema of a function
© The scientific sentence. 2010
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Calculus I:
functions of several variables
linear approximation
Error calculation for
single
variable function
Error calculation for
a function of single variable
When we do measurements we make errors
that are due to the precision of the tools we have.
We must therefore make a distinction between exact
value (theoretical) and approximate value (obtained
by practice).
For example, suppose we measure the dimension of
a square.
We obtain by a measure 4.97 meters, and we know that
our measuring devices give a precision of 0.05 meters.
However, the exact measurement is 5 meters.
There is therefore a difference between measured
value and exact value. In our case, this error is
0.03 meters.
Definition 1
In general, x is the measured value, δx is
the error of the made measurement and Δx
the precision of the measuring device.
Thus, the exact value is x + δx.
In addition, w have |δx|≤ Δx.
In our case, we have x = 4.97 and δx =
+ 0.03 and Δx = 0.05.
In practice, only x and Δx are known.
We notice that in practice we do not know δx .
Of course, if we know a measurement and the error
of this measure then we will know the exact value.
Now we want to evaluate the surface of the square.
As in practice , the exact value x + δx, is
unknown, the only thing we can do is to use x, the
measured value.
As our measure gave us a length of 4.97 meters,
we calculate f(4.97), where f (t) = t2.
We have f(4.97) = (4.97)2 = 24.7009.
This value does not match the exact area of the square,
because we have used for the calculations an approximate
value.
We cannot do better more than that. Indeed, in practice
we do not know the exact measure of the dimension !
The only thing we can do is estimate the error made
by taking an approximate value. This error is
f(x) - f(x + δx).
We know the following approximation:
f (x + δx) ≈ f(x) + f'(x)δx
, that gives :
f (x + δx) - f(x) ≈ f'(x)δx
We only know an increase of |δx| which
is Δx = 0.05.
This gives :
|f(x + δx) - f(x)| ≈ |f'(x)|Δx
In our case x = 4.97 and Δx = 0. 05. As
f'(x) = 2.x, we get f'(4.97) = 2 x 4.97 = 9.94,
it comes then:
|f(x + δx) - f(x)| ≈ 9.94 x 0.05 = 0.497.
The error is therefore about 0.497 m2.
This means that in our case, the figures given after
the decimal point in the calculation of f(4.97) have
no significance for the estimation of the measured area.
In order to ease the writing, we will introduce
a notation.
Definition 2
The error |f(x + δx) - f(x)| is noted
δf. This error is also called
absolute error.
Proposition
We denote |δf| by Δf, the order of
magnitude of the absolute error.
So
Δf ≈ |f'(x)| Δx
,
called : the absolute error .
In the foregoing we have studied the error Δf .
We have seen that this error was about 0.5 m2. Has a
good approximation been obtained?
Indeed, there is a significant difference between
an error of 0.5 m2 on a surface of 1.000 m2 and on
a surface of 2 m2 .
To find out if an error is big or not, we look at
what proportion, what percentage it represents with
respect to f (x).
Definition 3
The Relative error is the quotient:
Δf/|f(x)|
.
This number is expressed in %.
In the previous example, the relative error is:
Δf/|f(x)| = 0.497 /|f(4.97)| =
0.497 / 24.7009 = 0.02006 = 2%
Note : Calculate the relative error is to
calculate
(|f'(x)|/|f(x)|)Δx
So we can calculate the relative error from a
logarithmic derivative calculation.
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