Solve # (1+x^2)^2y'' + 2x(1+x^2)y'+4y = 0 #?

1 Answer
Sep 5, 2017

# y = Acos(2arctanx)+Bcos(2arctanx) #

Explanation:

# (1+x^2)^2y'' + 2x(1+x^2)y'+4y = 0 # ..... [A]

Perform a substitution

Let #u = arctanx#

Then:

#(du)/dx = 1/(1+x^2) # and #(d^2u)/(dx^2) = (-2x)/(1+x^2)^2#

For the first derivative, we have:

#dy/dx = dy/(du) * (du)/dx = 1/(1+x^2)dy/(du) #

For the second derivative, we have:

# (d^2y)/(dx^2) = 1/(1+x^2)(d^2y)/(du^2) (du)/dx + (-2x)/(1+x^2)^2dy/(du) #
# \ \ \ \ \ \ \ = 1/(1+x^2)(d^2y)/(du^2) (du)/dx + (-2x)/(1+x^2)^2dy/(du) #

# \ \ \ \ \ \ \ = 1/(1+x^2)^2(d^2y)/(du^2) - (2x)/(1+x^2)^2dy/(du) #

Substituting these expressions into the initial Differential Equation [A] we get:

# (1+x^2)^2{1/(1+x^2)^2(d^2y)/(du^2) - (2x)/(1+x^2)^2dy/(du)} + 2x(1+x^2){1/(1+x^2)dy/(du)}+4y = 0 #

And we can cancel factors of #(1+x^2)# giving:

# (d^2y)/(du^2) - 2x dy/(du) + 2xdy/(du)+4y = 0 #
# :. (d^2y)/(du^2) +4y = 0 # ..... [B]

This is a second order linear Homogeneous Differentiation Equation. The standard approach is to find a solution, #y_c# by looking at the Auxiliary Equation, which is the quadratic equation with the coefficients of the derivatives.

Complementary Function

The Auxiliary equation associated with [B] is:

# m^2 + 4 = 0 #

We can solve this quadratic equation, and we get two complex conjugate solutions:

# m = +-2i #

Thus the Homogeneous equation [B] has the solution:

# y_c = e^(0x)(Acos(2u)+Bcos(2u)) #
# \ \ \ = Acos(2u)+Bcos(2u) #

Now we initially used a change of variable:

#u = arctanx#

So restoring this change of variable we get:

# y = Acos(2arctanx)+Bcos(2arctanx) #