4.3 problem 24

Internal problem ID [10431]
Internal file name [OUTPUT/9379_Monday_June_06_2022_02_20_52_PM_89615702/index.tex]

Book: Handbook of exact solutions for ordinary differential equations. By Polyanin and Zaitsev. Second edition
Section: Chapter 1, section 1.2. Riccati Equation. subsection 1.2.3-2. Equations with power and exponential functions
Problem number: 24.
ODE order: 1.
ODE degree: 1.

The type(s) of ODE detected by this program : "riccati"

Maple gives the following as the ode type

[_Riccati]

\[ \boxed {y^{\prime }-a \,{\mathrm e}^{\lambda x} y^{2}=b n \,x^{-1+n}-a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n}} \]

4.3.1 Solving as riccati ode

In canonical form the ODE is \begin {align*} y' &= F(x,y)\\ &= {\mathrm e}^{\lambda x} a \,y^{2}+b n \,x^{-1+n}-a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n} \end {align*}

This is a Riccati ODE. Comparing the ODE to solve \[ y' = -a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n}+{\mathrm e}^{\lambda x} a \,y^{2}+\frac {b n \,x^{n}}{x} \] With Riccati ODE standard form \[ y' = f_0(x)+ f_1(x)y+f_2(x)y^{2} \] Shows that \(f_0(x)=b n \,x^{-1+n}-a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n}\), \(f_1(x)=0\) and \(f_2(x)={\mathrm e}^{\lambda x} a\). Let \begin {align*} y &= \frac {-u'}{f_2 u} \\ &= \frac {-u'}{{\mathrm e}^{\lambda x} a u} \tag {1} \end {align*}

Using the above substitution in the given ODE results (after some simplification)in a second order ODE to solve for \(u(x)\) which is \begin {align*} f_2 u''(x) -\left ( f_2' + f_1 f_2 \right ) u'(x) + f_2^2 f_0 u(x) &= 0 \tag {2} \end {align*}

But \begin {align*} f_2' &=a \lambda \,{\mathrm e}^{\lambda x}\\ f_1 f_2 &=0\\ f_2^2 f_0 &={\mathrm e}^{2 \lambda x} a^{2} \left (b n \,x^{-1+n}-a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n}\right ) \end {align*}

Substituting the above terms back in equation (2) gives \begin {align*} {\mathrm e}^{\lambda x} a u^{\prime \prime }\left (x \right )-a \lambda \,{\mathrm e}^{\lambda x} u^{\prime }\left (x \right )+{\mathrm e}^{2 \lambda x} a^{2} \left (b n \,x^{-1+n}-a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n}\right ) u \left (x \right ) &=0 \end {align*}

Solving the above ODE (this ode solved using Maple, not this program), gives

\[ u \left (x \right ) = \operatorname {DESol}\left (\left \{-x^{2 n} {\mathrm e}^{2 \lambda x} \textit {\_Y} \left (x \right ) a^{2} b^{2}+{\mathrm e}^{\lambda x} x^{-1+n} \textit {\_Y} \left (x \right ) a b n -\textit {\_Y}^{\prime }\left (x \right ) \lambda +\textit {\_Y}^{\prime \prime }\left (x \right )\right \}, \left \{\textit {\_Y} \left (x \right )\right \}\right ) \] The above shows that \[ u^{\prime }\left (x \right ) = \frac {\partial }{\partial x}\operatorname {DESol}\left (\left \{-x^{2 n} {\mathrm e}^{2 \lambda x} \textit {\_Y} \left (x \right ) a^{2} b^{2}+{\mathrm e}^{\lambda x} x^{-1+n} \textit {\_Y} \left (x \right ) a b n -\textit {\_Y}^{\prime }\left (x \right ) \lambda +\textit {\_Y}^{\prime \prime }\left (x \right )\right \}, \left \{\textit {\_Y} \left (x \right )\right \}\right ) \] Using the above in (1) gives the solution \[ y = -\frac {\left (\frac {\partial }{\partial x}\operatorname {DESol}\left (\left \{-x^{2 n} {\mathrm e}^{2 \lambda x} \textit {\_Y} \left (x \right ) a^{2} b^{2}+{\mathrm e}^{\lambda x} x^{-1+n} \textit {\_Y} \left (x \right ) a b n -\textit {\_Y}^{\prime }\left (x \right ) \lambda +\textit {\_Y}^{\prime \prime }\left (x \right )\right \}, \left \{\textit {\_Y} \left (x \right )\right \}\right )\right ) {\mathrm e}^{-\lambda x}}{a \operatorname {DESol}\left (\left \{-x^{2 n} {\mathrm e}^{2 \lambda x} \textit {\_Y} \left (x \right ) a^{2} b^{2}+{\mathrm e}^{\lambda x} x^{-1+n} \textit {\_Y} \left (x \right ) a b n -\textit {\_Y}^{\prime }\left (x \right ) \lambda +\textit {\_Y}^{\prime \prime }\left (x \right )\right \}, \left \{\textit {\_Y} \left (x \right )\right \}\right )} \] Dividing both numerator and denominator by \(c_{1}\) gives, after renaming the constant \(\frac {c_{2}}{c_{1}}=c_{3}\) the following solution

\[ y = -\frac {\left (\frac {\partial }{\partial x}\operatorname {DESol}\left (\left \{-x^{2 n} {\mathrm e}^{2 \lambda x} \textit {\_Y} \left (x \right ) a^{2} b^{2}+{\mathrm e}^{\lambda x} x^{-1+n} \textit {\_Y} \left (x \right ) a b n -\textit {\_Y}^{\prime }\left (x \right ) \lambda +\textit {\_Y}^{\prime \prime }\left (x \right )\right \}, \left \{\textit {\_Y} \left (x \right )\right \}\right )\right ) {\mathrm e}^{-\lambda x}}{a \operatorname {DESol}\left (\left \{-x^{2 n} {\mathrm e}^{2 \lambda x} \textit {\_Y} \left (x \right ) a^{2} b^{2}+{\mathrm e}^{\lambda x} x^{-1+n} \textit {\_Y} \left (x \right ) a b n -\textit {\_Y}^{\prime }\left (x \right ) \lambda +\textit {\_Y}^{\prime \prime }\left (x \right )\right \}, \left \{\textit {\_Y} \left (x \right )\right \}\right )} \]

4.3.2 Maple step by step solution

\[ \begin {array}{lll} & {} & \textrm {Let's solve}\hspace {3pt} \\ {} & {} & y^{\prime }-a \,{\mathrm e}^{\lambda x} y^{2}=b n \,x^{-1+n}-a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n} \\ \bullet & {} & \textrm {Highest derivative means the order of the ODE is}\hspace {3pt} 1 \\ {} & {} & y^{\prime } \\ \bullet & {} & \textrm {Solve for the highest derivative}\hspace {3pt} \\ {} & {} & y^{\prime }=a \,{\mathrm e}^{\lambda x} y^{2}+b n \,x^{-1+n}-a \,b^{2} {\mathrm e}^{\lambda x} x^{2 n} \end {array} \]

`Methods for first order ODEs: 
--- Trying classification methods --- 
trying a quadrature 
trying 1st order linear 
trying Bernoulli 
trying separable 
trying inverse linear 
trying homogeneous types: 
trying Chini 
differential order: 1; looking for linear symmetries 
trying exact 
Looking for potential symmetries 
trying Riccati 
trying Riccati sub-methods: 
   trying Riccati_symmetries 
   trying Riccati to 2nd Order 
   -> Calling odsolve with the ODE`, diff(diff(y(x), x), x) = (diff(y(x), x))*lambda-exp(lambda*x)*a*b*(-x^(2*n)*exp(lambda*x)*a*b+x 
      Methods for second order ODEs: 
      --- Trying classification methods --- 
      trying a symmetry of the form [xi=0, eta=F(x)] 
      checking if the LODE is missing y 
      -> Heun: Equivalence to the GHE or one of its 4 confluent cases under a power @ Moebius 
      -> trying a solution of the form r0(x) * Y + r1(x) * Y where Y = exp(int(r(x), dx)) * 2F1([a1, a2], [b1], f) 
      -> Trying changes of variables to rationalize or make the ODE simpler 
         trying a symmetry of the form [xi=0, eta=F(x)] 
         checking if the LODE is missing y 
         -> Heun: Equivalence to the GHE or one of its 4 confluent cases under a power @ Moebius 
         -> trying a solution of the form r0(x) * Y + r1(x) * Y where Y = exp(int(r(x), dx)) * 2F1([a1, a2], [b1], f) 
            trying 2nd order exact linear 
            trying symmetries linear in x and y(x) 
            trying to convert to a linear ODE with constant coefficients 
      <- unable to find a useful change of variables 
         trying a symmetry of the form [xi=0, eta=F(x)] 
         trying 2nd order exact linear 
         trying symmetries linear in x and y(x) 
         trying to convert to a linear ODE with constant coefficients 
         trying 2nd order, integrating factor of the form mu(x,y) 
         trying a symmetry of the form [xi=0, eta=F(x)] 
         checking if the LODE is missing y 
         -> Heun: Equivalence to the GHE or one of its 4 confluent cases under a power @ Moebius 
         -> trying a solution of the form r0(x) * Y + r1(x) * Y where Y = exp(int(r(x), dx)) * 2F1([a1, a2], [b1], f) 
         -> Trying changes of variables to rationalize or make the ODE simpler 
            trying a symmetry of the form [xi=0, eta=F(x)] 
            checking if the LODE is missing y 
            -> Heun: Equivalence to the GHE or one of its 4 confluent cases under a power @ Moebius 
            -> trying a solution of the form r0(x) * Y + r1(x) * Y where Y = exp(int(r(x), dx)) * 2F1([a1, a2], [b1], f) 
               trying a symmetry of the form [xi=0, eta=F(x)] 
               trying 2nd order exact linear 
               trying symmetries linear in x and y(x) 
               trying to convert to a linear ODE with constant coefficients 
         <- unable to find a useful change of variables 
            trying a symmetry of the form [xi=0, eta=F(x)] 
         trying to convert to an ODE of Bessel type 
   -> Trying a change of variables to reduce to Bernoulli 
   -> Calling odsolve with the ODE`, diff(y(x), x)-(exp(lambda*x)*a*y(x)^2+y(x)+x^2*(b*x^(n-1)*n-a*b^2*exp(lambda*x)*x^(2*n)))/x, y( 
      Methods for first order ODEs: 
      --- Trying classification methods --- 
      trying a quadrature 
      trying 1st order linear 
      trying Bernoulli 
      trying separable 
      trying inverse linear 
      trying homogeneous types: 
      trying Chini 
      differential order: 1; looking for linear symmetries 
      trying exact 
      Looking for potential symmetries 
      trying Riccati 
      trying Riccati sub-methods: 
         trying Riccati_symmetries 
      trying inverse_Riccati 
      trying 1st order ODE linearizable_by_differentiation 
   -> trying a symmetry pattern of the form [F(x)*G(y), 0] 
   -> trying a symmetry pattern of the form [0, F(x)*G(y)] 
   -> trying a symmetry pattern of the form [F(x),G(x)*y+H(x)] 
trying inverse_Riccati 
trying 1st order ODE linearizable_by_differentiation 
--- Trying Lie symmetry methods, 1st order --- 
`, `-> Computing symmetries using: way = 4 
`, `-> Computing symmetries using: way = 2 
`, `-> Computing symmetries using: way = 6`
 

✗ Solution by Maple

dsolve(diff(y(x),x)=a*exp(lambda*x)*y(x)^2+b*n*x^(n-1)-a*b^2*exp(lambda*x)*x^(2*n),y(x), singsol=all)
 

\[ \text {No solution found} \]

✗ Solution by Mathematica

Time used: 0.0 (sec). Leaf size: 0

DSolve[y'[x]==a*Exp[\[Lambda]*x]*y[x]^2+b*n*x^(n-1)-a*b^2*Exp[\[Lambda]*x]*x^(2*n),y[x],x,IncludeSingularSolutions -> True]
 

Not solved