Linear Systems of First-Order Differential Equations 367The development of the theory for systems of linear first-order differential
equations closely parallels that for n-th order linear differential equations. We
state the following theorems without proof.SUPERPOSITION THEOREM FOR HOMOGENEOUS LINEAR
SYSTEMSIf Y1 and Y2 are any two solutions of the homogeneous linear system
(7) y' = A(x)y, then y3 = C1Y1 + C2Y2 where c1 and c2 are arbitrary scalar
constants is also a solution of (7).The superposition theorem can easily be generalized to show that if y 1 ,
Y2, ... , Ym are any m solutions of (7) y' = A(x)y, then y = C1Y1 + C2Y2 +
· · ·+CmYm where c 1 , c2, ... , Cm are arbitrary scalar constants is also a solution
of the homogeneous system (7).EXISTENCE THEOREM FOR HOMOGENEOUS LINEAR
SYSTEMSIf A(x) is continuous on some interval (a,,B)- that is, if aij(x) is a con-
tinuous function on (a, ,B) for all i, j = 1, 2, ... , n, then there exist n linearly
independent solutions of the homogeneous linear system (7) y' = A(x)y on
the interval (a, ,B).The existence theorem just stated tells us there are n linearly independent
solutions Y1,Y2,... ,yn ofy' = A(x)y on the interval (o:,,B), provided A(x)
is continuous on (o:, ,B).
The following representation theorem tells us how to write every other so-lution in terms of Y1, Y2, ... , Yn·
REPRESENTATION THEOREM FOR HOMOGENEOUS LINEAR
SYSTEMSIf A(x) is continuous on the interval (o:,,B), ify1,y2, ... , y n are linearly
independent solutions of the homogeneous linear system (7) y' = A(x)y on
(o:, ,B), and if y is any other solution of (7) on (o:, ,B), then there exist scalar
constants C1, c2, ... , Cn such thaty(x) = C1Y1 (x) + C2Y2(x) + · · · + CnYn(x) on (o:, ,B).