Linear Systems of First-Order Differential Equations 375(.707107) (-.707107) (0)
y(x) = C1e^3 x 0.000000 + c2ex 0.000000 + c3ex 1
.707107 .707107 0where c1, c2, and c3 are arbitrary constants.
You may find it more appealing to write the general solution in the formwhere k1, k2, and k3 are arbitrary constants. This representation was ac-
complished by multiplying the eigenvectors v 1 and v 2 by the scalar constant
1/.707107 to obtain the eigenvectorsIn part 4 of example 5 of section 8.2, we ran the computer program EI GEN
and found that the eigenvalues of the matrixA=(~ -~)are > 11 = 2 + i, .A 2 = 2 - i and the associated eigenvectors are
Z1 -(-1-i) - i
Therefore, the general solution of the homogeneous linear system y' = Ay
may be written as
where c 1 and c 2 are arbitrary constants. The function y(x) of equation (17)
is a complex-valued function of the real variable x. Since the original system
of differential equations, y' = Ay, is a real system (that is, since all of the
entries of the matrix A are all real numbers), it is desirable to write the general
solution of the system as a real-valued function of x, if possible. The following
theorem specifies conditions under which we can write two real-valued, linearly
independent solutions for y' = Ay when A has a pair of complex conjugate
eigenvalues.