HP 48g Graphing Calculator User Manual

20

The Accuracy Factor and the Uncertainty of Numerical

Integration

Numeric integration calculates the integral of a function f{x) by

computing a weighted average of the function’s values at many values

of X (sample points) within the interval of integration. The accuracy

of the result depends on the number of sample points considered:

generally, more sample points provide greater accuracy. There are two
reasons why you might want to limit the accuracy of the integral:

■ The length of time to calculate the integral increases as the number

of sample points increases.

m There are inherent inaccuracies in each calculated value of f{x):

□ Experimentally derived constants in f(x) may be inaccurate.

For example, if f(x) contains experimentally derived constants
that are accurate to only two decimal places, it is of little value

to calculate the integral to the full (T2-digit) precision of the
calculator.

□ If f(x) models a physical system, there may be inaccuracies in the

model.

n The calculator itself introduces round-off error into each

computation of f{x).

To indirectly limit the accuracy of the integral, you specify the

accuracy factor of the integrand f(x), defined as:

accuracy factor <

true value of f{x) — computed value of f(x)

computed value of f(x)

The accuracy factor is your estimation in decimal form of the error

in each computed value of/(*). You specify the accuracy factor by

setting the Display mode to n Fix. For example, if you set the display

mode to 2 Fix, the accuracy factor is 0.01, or 1%. If you set the
display mode to 5 Fix, the accuracy factor is 0.00001, or .001%.

The accuracy factor is related to the uncertainty of 'integration (a
measurement of the accuracy of the integral) by:

uncertainty of integration < accuracy factor x / \f{x)\d.x

20-6 Calculus and Symbolic Manipulation