N-th Order Linear Differential Equations 183Since y(x) satisfies the DE (26) and contains no arbitrary constant, y(x) is a
particular solution of (26).
REPRESENTATION THEOREM FOR N-TH ORDER NON-
HOMOGENEOUS LINEAR DIFFERENTIAL EQUATIONSIf Yp ( x) is any particular solution on the interval I of the nonhomogeneous
linear differential equation
(24)
an(x)y(n)(x) + an-1(x)y(n-l)(x) + · · · + a1(x)yCll(x) + ao(x)y(x) = b(x),and ify 1 (x),y2(x), ... ,yn(x) are n linearly independent solutions on I of
the associated homogeneous equationthen every solution of the DE (24) on the interval I has the formwhere c 1 , c 2 , ... , Cn are suitably chosen constants.Proof: Let Yc(x) = C1Y1(x) + c2y2(x) + · · · + CnYn(x) where the Ci a re
arbitrary constants and let z(x) be any solution of the nonhomogeneous
linear DE (24) on I. In order to prove this theorem, we must show that
it is possible to choose the Ci so that z(x) = Yc(x ) + yp(x). Since z(x)
and Yp(x) are both solutions on the interval I of the nonhomogeneousDE (24), w(x) = z(x) - yp(x) is a solut ion on I of the associated homoge-
neous DE (25). By the representation t heorem for n-th order homogeneouslinear differential equations there exist constants c1, c2, ... , Cn such that
Hence, z(x) = Yc(x) + yp(x) for suitably chosen constants c 1 , c2, ... , Cn.
DEFINITIONS Complementary Solution and General SolutionLet y 1 (x),y 2 (x),... , yn(x) be n linearly independent solutions on I of
the homogeneous DE (25) associated with the nonhomogeneous DE (24).
The linear combination Ye ( x) = C1 Y1 ( x ) + c2y2 ( x ) + · · · + CnYn ( x) wh ere