Introduction 23At this point, we need to examine a few initial value problems and bound-
ary value problems to determine whether all initial value problems and all
boundary value problems have a solution or not. That is, we need to examine
the question of existence of solutions to initial value problems and the ques-
tion of existence of solutions to boundary value problems. We also need to
discover if any initial value problem or any boundary value problem has more
than one solution. That is, we need to consider the question of uniqueness of
solutions to initial value problems and the question of uniqueness of solutions
to boundary value problems.Let us examine the differential equation(11) xy' -y = 0.
The function y(x) = ex, where e is an arbitrary constant, and its derivative
y'(x) = e are both defined on the interval (-00,00). Substituting y and y'
into the DE (11), we findxy' - y = xe - ex = 0for all x and for all choices of e. Thus, y(x) =ex is a one-parameter family ofsolutions to the DE (11) on ( -oo, oo). This family of functions is the set of
all lines which pass through the origin except for the line x = 0 (the y-axis).
EXAMPLE 3 An Initial Value Problem with No SolutionConsider the initial value problem(12) xy' - y = O; y(O) = l.
For x = 0 the differential equation xy' - y = 0 reduces to -y = 0. Conse-
quently, for x = 0 the differential equation xy' - y = 0 is undefined unless
y(O) = 0 also. Hence, the IVP (12) is an example of an initial value problem
which does not have a solution. Furthermore, there is no solution to anyinitial value problem of the form xy' - y = O; y(O) = d i:-0. In geometric
terms, there is no solution of the differential equation xy' -y = 0 which passes
through any point on the positive or negative y-axis- that is, any point of the
form (0, d) where d i:-0.