4.1 Indefinite integrals 211
Let x be confined to an interval I over which two given functions u and v are
differentiable. The standard formula
(1) d u(x)v(x) = u(x)v'(x) + v(x)u'(x)
then (why?) gives the formula
(2) f[u(x)v'(x) + v(x)u'(x)] dx = u(x)v(x) + c.
In case the separate integrals are cooperative enough to exist, we can (why?)
put (2) in the form
(3) fu(x)v'(x) dx + fv(x)u'(x) dx = u(x)v(x) + c
and transpose to obtain the formula
(4) fu(x)v'(x) dx = u(x)v(x) - fv(x)u'(x) dx,
which is known as the formula for integration by parts. For the particular case
in which u(x) = x and v(x) = ex, show that (4) reduces to
(5) fxex dx = xex - ex + c.
Finally, check (5) by showing that the derivative of the right side actually is the
integrand.
15 Read and work the preceding problem again.
16 With Problem 14 out of sight, start with the formula for the derivative
of a product and construct the formula for integration by parts and give an
application of it.
17 Start with the function fo for which fo(x) = 1 when -1 < x < 1 and
determine the natures of the functions f1, f2, fs, - for which the formulas
fn(x) = f.-1(x), fn(x) = ff.-,(x) dx, (n = 1,2,3,. ..)
are valid. .ns.: There exist constants c1, c2, C3, such that
fi(x) =x+c1
f2(x) = $x2 + clx + C2
f s(x) = -19X' + VCix.2 + c2x + C8
f4(x) = VITX4 + $Clxs + c2x2 + C3X + Ca
etcetera. Remark: These things will appear later.
18 Prove that the first of the formulas
f sgn x dx = jxj + c1, f sgn x dx = Jxl + C2
is correct when x > 0 and the second is correct when x < 0. Prove that there
is no constant c such that the formula
f sgn x dx = lxI + C
is correct when x = 0.
19 This problem contains hundreds of parts, and there is much to be saidfor
spending several hours or days solving a considerable number of them. To