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Riemann Integral

The Riemann integral is the definite integral normally encountered in calculus texts and used by physicists and engineers. Other types of integrals exist (e.g., the Lebesgue integral), but are unlikely to be encountered outside the confines of advanced mathematics texts. In fact, according to Jeffreys and Jeffreys (1988, p. 29), "it appears that cases where these methods [i.e., generalizations of the Riemann integral] are applicable and Riemann's [definition of the integral] is not are too rare in physics to repay the extra difficulty."

The Riemann integral is based on the Jordan measure, and defined by taking a limit of a Riemann sum,

int_a^bf(x)dx=lim_(maxDeltax_k->0)sum_(k=1)^(n)f(x_k^*)Deltax_k
(1)
intintf(x,y)dA=lim_(maxDeltaA_k->0)sum_(k=1)^(n)f(x_k^*,y_k^*)DeltaA_k
(2)
intintintf(x,y,z)dV=lim_(maxDeltaV_k->0)sum_(k=1)^(n)f(x_k^*,y_k^*,z_k^*)DeltaV_k,
(3)

where a<=x<=b and x_k^*, y_k^*, and z_k^* are arbitrary points in the intervals Deltax_k, Deltay_k, and Deltaz_k, respectively. The value maxDeltax_k is called the mesh size of a partition of the interval [a,b] into subintervals Deltax_k.

As an example of the application of the Riemann integral definition, find the area under the curve y=x^r from 0 to a. Divide (0,a) into n segments, so Deltax_k=a/n=h, then

f(x_1)=f(0)=0
(4)
f(x_2)=f(Deltax_k)=h^r
(5)
f(x_3)=f(2Deltax_k)=(2h)^r.
(6)

By induction

f(x_k)=f([k-1]Deltax_k)=[(k-1)h]^r=h^r(k-1)^r,
(7)

so

f(x_k)Deltax_k=h^(r+1)(k-1)^r
(8)
sum_(k=1)^nf(x_k)Deltax_k=h^(r+1)sum_(k=1)^n(k-1)^r.
(9)

For example, take r=2.

sum_(k=1)^nf(x_k)Deltax_k=h^3sum_(k=1)^n(k-1)^2 =h^3(sum_(k=1)^nk^2-2sum_(k=1)^nk+sum_(k=1)^n1) =h^3[(n(n+1)(2n+1))/6-2(n(n+1))/2+n],
(10)

so

I=lim_(n->infty)sum_(k=1)^(n)f(x_k^*)Deltax_k=lim_(n->infty)sum_(k=1)^(n)f(x_k)Deltax_k
(11)
=lim_(n->infty)h^3[(n(n+1)(2n+1))/6-2(n(n+1))/2+n]
(12)
=a^3lim_(n->infty)[(n(n+1)(2n+1))/(6n^3)-(n(n+1))/(n^3)+n/(n^3)]
(13)
=1/3a^3.
(14)

Riemann integrals can be computed only for proper integrals.

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