2.42 problem 40

Internal problem ID [5790]
Internal file name [OUTPUT/5038_Sunday_June_05_2022_03_18_32_PM_90959887/index.tex]

Book: Ordinary differential equations and calculus of variations. Makarets and Reshetnyak. Wold Scientific. Singapore. 1995
Section: Chapter 1. First order differential equations. Section 1.2 Homogeneous equations problems. page 12
Problem number: 40.
ODE order: 1.
ODE degree: 1.

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

Maple gives the following as the ode type

[[_homogeneous, `class C`], _rational, [_Abel, `2nd type`, `class A`]]

\[ \boxed {y^{\prime }-\frac {x -2 y+5}{y-2 x -4}=0} \]

2.42.1 Solving as polynomial ode

This is ODE of type polynomial. Where the RHS of the ode is ratio of equations of two lines. Writing the ODE in the form \[ y^{\prime }= \frac {a_1 x + b_1 y + c_1}{ a_2 x + b_2 y + c_3 } \] Where \(a_1=-1, b_1=2, c_1 =-5, a_2=2, b_2=-1, c_2=4\). There are now two possible solution methods. The first case is when the two lines \(a_1 x + b_1 y + c_1\),\( a_2 x + b_2 y + c_3\) are not parallel and the second case is if they are parallel. If they are not parallel, then the transformation \(X=x-x_0\), \(Y=y-y_0\) converts the ODE to a homogeneous ODE. The values \( x_0,y_0\) have to be determined. If they are parallel then a transformation \(U(x)=a_1 x + b_1 y\) converts the given ODE in \(y\) to a separable ODE in \(U(x)\). The first case is when \(\frac {a_1}{b_1} \neq \frac {a_2}{b_2}\) and the second case when \(\frac {a_1}{b_1} = \frac {a_2}{b_2}\). From the above we see that \(\frac {a_1}{b_1}\neq \frac {a_2}{b_2}\). Hence this is case one where lines are not parallel. Using the transformation \begin {align*} X &=x-x_0 \\ Y &=y-y_0 \end {align*}

Where the constants \(x_0,y_0\) are obtained by solving the following two linear algebraic equations \begin {align*} a_1 x_0 + b_1 y_0 + c_1 &= 0\\ a_2 x_0 + b_2 y_0 + c_2 &= 0 \end {align*}

Substituting the values for \(a_1,b_1,c_1,a_2,b_2,c_2\) gives \begin {align*} -x_{0} +2 y_{0} -5 &= 0 \\ 2 x_{0} -y_{0} +4 &= 0 \\ \end {align*}

Solving for \(x_0,y_0\) from the above gives \begin {align*} x_0 &= -1 \\ y_0 &= 2 \end {align*}

Therefore the transformation becomes \begin {align*} X &=x+1 \\ Y &=y-2 \end {align*}

Using this transformation in \(y^{\prime }-\frac {x -2 y+5}{y-2 x -4} = 0\) result in \begin {align*} \frac {dY}{dX} &= \frac {-X +2 Y}{-Y +2 X} \end {align*}

This is now a homogeneous ODE which will now be solved for \(Y(X)\). In canonical form, the ODE is \begin {align*} Y' &= F(X,Y)\\ &= -\frac {-X +2 Y}{Y -2 X}\tag {1} \end {align*}

An ode of the form \(Y' = \frac {M(X,Y)}{N(X,Y)}\) is called homogeneous if the functions \(M(X,Y)\) and \(N(X,Y)\) are both homogeneous functions and of the same order. Recall that a function \(f(X,Y)\) is homogeneous of order \(n\) if \[ f(t^n X, t^n Y)= t^n f(X,Y) \] In this case, it can be seen that both \(M=-X +2 Y\) and \(N=-Y +2 X\) are both homogeneous and of the same order \(n=1\). Therefore this is a homogeneous ode. Since this ode is homogeneous, it is converted to separable ODE using the substitution \(u=\frac {Y}{X}\), or \(Y=uX\). Hence \[ \frac { \mathop {\mathrm {d}Y}}{\mathop {\mathrm {d}X}}= \frac { \mathop {\mathrm {d}u}}{\mathop {\mathrm {d}X}}X + u \] Applying the transformation \(Y=uX\) to the above ODE in (1) gives \begin {align*} \frac { \mathop {\mathrm {d}u}}{\mathop {\mathrm {d}X}}X + u &= \frac {-2 u +1}{u -2}\\ \frac { \mathop {\mathrm {d}u}}{\mathop {\mathrm {d}X}} &= \frac {\frac {-2 u \left (X \right )+1}{u \left (X \right )-2}-u \left (X \right )}{X} \end {align*}

Or \[ \frac {d}{d X}u \left (X \right )-\frac {\frac {-2 u \left (X \right )+1}{u \left (X \right )-2}-u \left (X \right )}{X} = 0 \] Or \[ \left (\frac {d}{d X}u \left (X \right )\right ) X u \left (X \right )-2 \left (\frac {d}{d X}u \left (X \right )\right ) X +u \left (X \right )^{2}-1 = 0 \] Or \[ X \left (u \left (X \right )-2\right ) \left (\frac {d}{d X}u \left (X \right )\right )+u \left (X \right )^{2}-1 = 0 \] Which is now solved as separable in \(u \left (X \right )\). Which is now solved in \(u \left (X \right )\). In canonical form the ODE is \begin {align*} u' &= F(X,u)\\ &= f( X) g(u)\\ &= -\frac {u^{2}-1}{X \left (u -2\right )} \end {align*}

Where \(f(X)=-\frac {1}{X}\) and \(g(u)=\frac {u^{2}-1}{u -2}\). Integrating both sides gives \begin{align*} \frac {1}{\frac {u^{2}-1}{u -2}} \,du &= -\frac {1}{X} \,d X \\ \int { \frac {1}{\frac {u^{2}-1}{u -2}} \,du} &= \int {-\frac {1}{X} \,d X} \\ -\frac {\ln \left (u -1\right )}{2}+\frac {3 \ln \left (u +1\right )}{2}&=-\ln \left (X \right )+c_{3} \\ \end{align*} The above can be written as \begin {align*} \frac {-\ln \left (u -1\right )+3 \ln \left (u +1\right )}{2} &= -\ln \left (X \right )+c_{3}\\ -\ln \left (u -1\right )+3 \ln \left (u +1\right ) &= \left (2\right ) \left (-\ln \left (X \right )+c_{3}\right ) \\ &= -2 \ln \left (X \right )+2 c_{3} \end {align*}

Raising both side to exponential gives \begin {align*} {\mathrm e}^{-\ln \left (u -1\right )+3 \ln \left (u +1\right )} &= {\mathrm e}^{-2 \ln \left (X \right )+2 c_{3}} \end {align*}

Which simplifies to \begin {align*} \frac {\left (u +1\right )^{3}}{u -1} &= \frac {2 c_{3}}{X^{2}}\\ &= \frac {c_{4}}{X^{2}} \end {align*}

Which simplifies to \[ \frac {\left (u \left (X \right )+1\right )^{3}}{u \left (X \right )-1} = \frac {c_{4} {\mathrm e}^{2 c_{3}}}{X^{2}} \] The solution is \[ \frac {\left (u \left (X \right )+1\right )^{3}}{u \left (X \right )-1} = \frac {c_{4} {\mathrm e}^{2 c_{3}}}{X^{2}} \] Now \(u\) in the above solution is replaced back by \(Y\) using \(u=\frac {Y}{X}\) which results in the solution \[ \frac {\left (\frac {Y \left (X \right )}{X}+1\right )^{3}}{\frac {Y \left (X \right )}{X}-1} = \frac {c_{4} {\mathrm e}^{2 c_{3}}}{X^{2}} \] Which simplifies to \begin {align*} -\frac {\left (Y \left (X \right )+X \right )^{3}}{-Y \left (X \right )+X} = c_{4} {\mathrm e}^{2 c_{3}} \end {align*}

The solution is implicit \(-\frac {\left (Y \left (X \right )+X \right )^{3}}{-Y \left (X \right )+X} = c_{4} {\mathrm e}^{2 c_{3}}\). Replacing \(Y=y-y_0, X=x-x_0\) gives \[ -\frac {\left (-1+y+x \right )^{3}}{3+x -y} = c_{4} {\mathrm e}^{2 c_{3}} \]

2.42.2 Maple step by step solution

\[ \begin {array}{lll} & {} & \textrm {Let's solve}\hspace {3pt} \\ {} & {} & y^{\prime }-\frac {x -2 y+5}{y-2 x -4}=0 \\ \bullet & {} & \textrm {Highest derivative means the order of the ODE is}\hspace {3pt} 1 \\ {} & {} & y^{\prime } \\ \bullet & {} & \textrm {Solve for the highest derivative}\hspace {3pt} \\ {} & {} & y^{\prime }=\frac {x -2 y+5}{y-2 x -4} \end {array} \]

`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 homogeneous C 
trying homogeneous types: 
trying homogeneous D 
<- homogeneous successful 
<- homogeneous successful`
 

✓ Solution by Maple

Time used: 0.375 (sec). Leaf size: 117

dsolve(diff(y(x),x)=(x-2*y(x)+5)/(y(x)-2*x-4),y(x), singsol=all)
 

\[ y \left (x \right ) = \frac {\frac {1}{2}+\frac {\left (1-i \sqrt {3}\right ) \left (27 \left (x +1\right ) c_{1} +3 \sqrt {3}\, \sqrt {27 \left (x +1\right )^{2} c_{1}^{2}-1}\right )^{\frac {2}{3}}}{6}+\frac {i \sqrt {3}}{2}-\left (3 \sqrt {3}\, \sqrt {27 \left (x +1\right )^{2} c_{1}^{2}-1}+27 c_{1} x +27 c_{1} \right )^{\frac {1}{3}} \left (x -1\right ) c_{1}}{\left (27 \left (x +1\right ) c_{1} +3 \sqrt {3}\, \sqrt {27 \left (x +1\right )^{2} c_{1}^{2}-1}\right )^{\frac {1}{3}} c_{1}} \]

✓ Solution by Mathematica

Time used: 60.297 (sec). Leaf size: 1601

DSolve[y'[x]==(x-2*y[x]+5)/(y[x]-2*x-4),y[x],x,IncludeSingularSolutions -> True]
 

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