2.1.42 Problem 42

Solved as second order linear constant coeff ode

Time used: 0.131 (sec)

Solve

This is second order non-homogeneous ODE. In standard form the ODE is

Where $A=1,B=0,C=1,f(x)=x^3+x^2+x+1$. Let the solution be

Where $y_h$ is the solution to the homogeneous ODE $A{y}^{″}(x)+B{y}^{\prime }(x)+Cy(x)=0$, and $y_p$ is a particular solution to the non-homogeneous ODE $A{y}^{″}(x)+B{y}^{\prime }(x)+Cy(x)=f(x)$. $y_h$ is the solution to

This is second order with constant coefficients homogeneous ODE. In standard form the ODE is

Where in the above $A=1,B=0,C=1$. Let the solution be $y=e^{\lambda x}$. Substituting this into the ODE gives

Since exponential function is never zero, then dividing Eq(2) throughout by $e^{\lambda x}$ gives

Equation (2) is the characteristic equation of the ODE. Its roots determine the general solution form.Using the quadratic formula

Substituting $A=1,B=0,C=1$ into the above gives

Hence

Which simplifies to

Since roots are complex conjugate of each others, then let the roots be

Where $\alpha =0$ and $\beta =1$. Therefore the final solution, when using Euler relation, can be written as

Which becomes

Or

Therefore the homogeneous solution $y_h$ is

The particular solution is now found using the method of undetermined coefficients. Looking at the RHS of the ode, which is

Shows that the corresponding undetermined set of the basis functions (UC_set) for the trial solution is

While the set of the basis functions for the homogeneous solution found earlier is

Since there is no duplication between the basis function in the UC_set and the basis functions of the homogeneous solution, the trial solution is a linear combination of all the basis in the UC_set.

The unknowns $\{A_1,A_2,A_3,A_4\}$ are found by substituting the above trial solution $y_p$ into the ODE and comparing coefficients. Substituting the trial solution into the ODE and simplifying gives

Solving for the unknowns by comparing coefficients results in

Substituting the above back in the above trial solution $y_p$, gives the particular solution

Therefore the general solution is

Will add steps showing solving for IC soon.

Summary of solutions found

Solved as second order ode using Kovacic algorithm

Time used: 0.236 (sec)

Solve

Writing the ode as

Comparing (1) and (2) shows that

Applying the Liouville transformation on the dependent variable gives

Then (2) becomes

Where $r$ is given by

Substituting the values of $A,B,C$ from (3) in the above and simplifying gives

Comparing the above to (5) shows that

Therefore eq. (4) becomes

Equation (7) is now solved. After finding $z(x)$ then $y$ is found using the inverse transformation

The first step is to determine the case of Kovacic algorithm this ode belongs to. There are 3 cases depending on the order of poles of $r$ and the order of $r$ at $\mathrm{\infty }$. The following table summarizes these cases.

The order of $r$ at $\mathrm{\infty }$ is the degree of $t$ minus the degree of $s$. Therefore

There are no poles in $r$. Therefore the set of poles $\mathrm{\Gamma }$ is empty. Since there is no odd order pole larger than $2$ and the order at $\mathrm{\infty }$ is $0$ then the necessary conditions for case one are met. Therefore

Since $r=-1$ is not a function of $x$, then there is no need run Kovacic algorithm to obtain a solution for transformed ode $z^{″}=rz$ as one solution is

Using the above, the solution for the original ode can now be found. The first solution to the original ode in $y$ is found from

Since $B=0$ then the above reduces to

Which simplifies to

The second solution $y_2$ to the original ode is found using reduction of order

Since $B=0$ then the above becomes

Therefore the solution is

This is second order nonhomogeneous ODE. Let the solution be

Where $y_h$ is the solution to the homogeneous ODE $A{y}^{″}(x)+B{y}^{\prime }(x)+Cy(x)=0$, and $y_p$ is a particular solution to the nonhomogeneous ODE $A{y}^{″}(x)+B{y}^{\prime }(x)+Cy(x)=f(x)$. $y_h$ is the solution to

The homogeneous solution is found using the Kovacic algorithm which results in

The particular solution is now found using the method of undetermined coefficients. Looking at the RHS of the ode, which is

Shows that the corresponding undetermined set of the basis functions (UC_set) for the trial solution is

While the set of the basis functions for the homogeneous solution found earlier is

Since there is no duplication between the basis function in the UC_set and the basis functions of the homogeneous solution, the trial solution is a linear combination of all the basis in the UC_set.

The unknowns $\{A_1,A_2,A_3,A_4\}$ are found by substituting the above trial solution $y_p$ into the ODE and comparing coefficients. Substituting the trial solution into the ODE and simplifying gives

Solving for the unknowns by comparing coefficients results in

Substituting the above back in the above trial solution $y_p$, gives the particular solution

Therefore the general solution is

Will add steps showing solving for IC soon.

Summary of solutions found

✓ Maple. Time used: 0.002 (sec). Leaf size: 23

ode:=diff(diff(y(x),x),x)+y(x) = x^3+x^2+x+1; 
dsolve(ode,y(x), singsol=all);
 

Maple trace

Methods for second order ODEs: 
--- Trying classification methods --- 
trying a quadrature 
trying high order exact linear fully integrable 
trying differential order: 2; linear nonhomogeneous with symmetry [0,1] 
trying a double symmetry of the form [xi=0, eta=F(x)] 
-> Try solving first the homogeneous part of the ODE 
   checking if the LODE has constant coefficients 
   <- constant coefficients successful 
<- solving first the homogeneous part of the ODE successful
 

Maple step by step

✓ Mathematica. Time used: 0.014 (sec). Leaf size: 26

ode=D[y[x],{x,2}]+y[x]==1+x+x^2+x^3; 
ic={}; 
DSolve[{ode,ic},y[x],x,IncludeSingularSolutions->True]
 

✓ Sympy. Time used: 0.072 (sec). Leaf size: 24

from sympy import * 
x = symbols("x") 
y = Function("y") 
ode = Eq(-x**3 - x**2 - x + y(x) + Derivative(y(x), (x, 2)) - 1,0) 
ics = {} 
dsolve(ode,func=y(x),ics=ics)