346 Ordinary Differential Equations
linearly independent on an interval, it may or may not be linearly independent
at each point in the interval. For example, the two vector functions
are linearly independent on any interval [a, b], but these two vectors are lin-
early dependent at every point p E [a, b]. The vectors are linearly dependent
at any nonzero p, since for c 1 = p and c2 = -1
The vectors are linearly dependent at p = 0, since for any c1 and c2
C1Y1(0) + C2Y2(0) = C1 (~) + C2 (~) = (~).
Thus, the set {y 1 (x), y 2 (x)} is linearly independent on the interval (-oo, oo ),
yet it is linearly dependent at every point in ( -oo, oo)!
We state the following theorem regarding linear independence for vector
functions.
THEOREM A SUFFICIENT CONDITION FOR LINEAR
INDEPENDENCE OF VECTOR FUNCTIONSLet {y1 (x), Y2(x ), ... , Yn(x)} be a set of n vector functions of size n x 1
and let Y(x) be the matrix with jth column Yj (x ). If det Y(x) f- 0 for any
x E [a, b], then the set {y 1 (x), Y2(x), ... , Yn(x)} is linearly independent on
the interval [a, b].The converse of this theorem is false as the previous example illustrates,
since the set of vector functionsis linearly independent on any interval [a, b]; yet, for this set(x x2det Y = det )
0 0 =^0
for all x E [a, b].