What is the general solution of the differential equation? : (d^2y)/(dx^2) + dy/dx - 2y = -6sin2x-18cos2x
1 Answer
y(x) = -e^(-2x) + 3cos(2x)
Explanation:
We have:
(d^2y)/(dx^2) + dy/dx - 2y = -6sin2x-18cos2x ..... [A]
This is a second order linear non-Homogeneous Differentiation Equation. The standard approach is to find a solution,
Complementary Function
The homogeneous equation associated with [A] is
y'' + y' - 2y = 0
And it's associated Auxiliary equation is:
m^2 + m - 2 = 0
(m-1)(m+2) = 0
Which has two real and distinct solutions
Thus the solution of the homogeneous equation is:
y_c = Ae^(-2x)+Be^(1x)
\ \ \ = Ae^(-2x)+Be^(x)
Particular Solution
With this particular equation [A], a probably solution is of the form:
y = acos(2x)+bsin(2x)
Where
Let us assume the above solution works, in which case be differentiating wrt
y' \ \= -2asin(2x)+2bcos(2x)
y'' = -4acos(2x)-4bsin(2x)
Substituting into the initial Differential Equation
-4acos(2x)-4bsin(2x) -2asin(2x)+2bcos(2x) - 2acos(2x) - 2bsin(2x) = -6sin2x-18cos2x
Equating coefficients of
cos(2x): -4a+2b-2a=-18
sin(2x): -4b-2a-2b=-6
Solving simultaneously we get:
a=3 andb=0
And so we form the Particular solution:
y_p = 3cos(2x)
General Solution
Which then leads to the GS of [A}
y(x) = y_c + y_p
\ \ \ \ \ \ \ = Ae^(-2x)+Be^(x) + 3cos(2x) ..... [B]
Initial Conditions
We are given the initial conditions:
y(0)=2, y'(0)=2
Putting
2 = Ae^0+Be^0 + 3cos0 => A+B = -1
Differentiating [B] wrt
y'(x) = -2Ae^(-2x)+Be^(x) -6 sin(2x)
Putting
2 = -2Ae^0+Be^0 -6 sin0 => -2A + B = 2
Solving these two new equations simultaneously we get:
A=-1 andB=0
leading to the specific solution:
y(x) = -e^(-2x) + 3cos(2x)
