20 Ordinary Differential Equations
b. Show that
y(x) = -x^2 /4
is a singular solution of the DE (8).SOLUTION
a. Differentiating y(x) = ex+ e^2 , we get y' = e. Substituting for y and y'
in (8), yields
(y')^2 + xy' - y = e^2 + xe - (ex+ e^2 ) = 0.
Thus, (7) is a one-parameter family of solutions of the DE (8).b. The function y(x) = - x^2 /4 cannot be obtained from the one-parameter
family y( x) = ex + e^2 by any choice of the constant e. Differentiatingy(x) = - x^2 /4, we find y' = -x/2. Substituting for y and y' in (8), we
find
/ 2 / X 2 X X^2 1 1 1 2(y) +xy -y=(-2) +x(-2)-(-4)=(4-2+4)x =O.
Thus, y(x) = -x^2 /4 is a solution of the DE (8) and it is not a member
of the one-parameter family (7). So by definition y(x) = - x^2 /4 is a
singular solution of (8). A graph of the singular solution y(x) = -x^2 /4
and members of the one-parameter family of solutions y(x) = ex+ c^2
obtained by choosing c = -2, c = -1, c = 0, c = 1, and c = 2
are displayed in Figure 1.3. Observe that the one-parameter family of
lines y(x) =ex+ c^2 are tangent to the singular solution (the parabola)
y(x) = -x^2 /4.Figure 1.3 A One-Parameter Family of Solutions and
the Singular Solution of (y')^2 + xy' - y = 0