2.2 INTEGRATION
a bf(x)xFigure 2.7 An integral as the area under a curve.2.2 IntegrationThe notion of an integral as the area under a curve will be familiar to the reader.
In figure 2.7, in which the solid line is a plot of a functionf(x), the shaded area
represents the quantity denoted by
I=∫baf(x)dx. (2.21)This expression is known as thedefinite integraloff(x)betweenthelower limit
x=aand theupper limitx=b,andf(x) is called theintegrand.
2.2.1 Integration from first principlesThe definition of an integral as the area under a curve is not a formal definition,
but one that can be readily visualised. The formal definition ofI involves
subdividing the finite intervala≤x≤binto a large number of subintervals, by
defining intermediate pointsξisuch thata=ξ 0 <ξ 1 <ξ 2 <···<ξn=b,and
then forming the sum
S=∑ni=1f(xi)(ξi−ξi− 1 ), (2.22)wherexiis an arbitrary point that lies in the rangeξi− 1 ≤xi≤ξi(see figure 2.8).
If nownis allowed to tend to infinity in any way whatsoever, subject only to the
restriction that the length of every subintervalξi− 1 toξitends to zero, thenS
might, or might not, tend to a unique limit,I. If it does then the definite integral
off(x) betweenaandbis defined as having the valueI. If no unique limit exists
the integral is undefined. For continuous functions and a finite intervala≤x≤b
the existence of a unique limit is assured and the integral is guaranteed to exist.