Internal problem ID [8604]
Internal file name [OUTPUT/7537_Sunday_June_05_2022_11_04_03_PM_13029280/index.tex
]
Book: Differential Gleichungen, E. Kamke, 3rd ed. Chelsea Pub. NY, 1948
Section: Chapter 1, linear first order
Problem number: 268.
ODE order: 1.
ODE degree: 1.
The type(s) of ODE detected by this program : "bernoulli", "exactWithIntegrationFactor", "first_order_ode_lie_symmetry_lookup"
Maple gives the following as the ode type
[_Bernoulli]
\[ \boxed {f \left (x \right ) y y^{\prime }+g \left (x \right ) y^{2}=-h \left (x \right )} \]
Writing the ode as \begin {align*} y^{\prime }&=-\frac {g \left (x \right ) y^{2}+h \left (x \right )}{f \left (x \right ) y}\\ y^{\prime }&= \omega \left ( x,y\right ) \end {align*}
The condition of Lie symmetry is the linearized PDE given by \begin {align*} \eta _{x}+\omega \left ( \eta _{y}-\xi _{x}\right ) -\omega ^{2}\xi _{y}-\omega _{x}\xi -\omega _{y}\eta =0\tag {A} \end {align*}
The type of this ode is known. It is of type Bernoulli
. Therefore we do not need
to solve the PDE (A), and can just use the lookup table shown below to find \(\xi ,\eta \)
ODE class |
Form |
\(\xi \) |
\(\eta \) |
linear ode |
\(y'=f(x) y(x) +g(x)\) |
\(0\) |
\(e^{\int fdx}\) |
separable ode |
\(y^{\prime }=f\left ( x\right ) g\left ( y\right ) \) |
\(\frac {1}{f}\) |
\(0\) |
quadrature ode |
\(y^{\prime }=f\left ( x\right ) \) |
\(0\) |
\(1\) |
quadrature ode |
\(y^{\prime }=g\left ( y\right ) \) |
\(1\) |
\(0\) |
homogeneous ODEs of Class A |
\(y^{\prime }=f\left ( \frac {y}{x}\right ) \) |
\(x\) |
\(y\) |
homogeneous ODEs of Class C |
\(y^{\prime }=\left ( a+bx+cy\right ) ^{\frac {n}{m}}\) |
\(1\) |
\(-\frac {b}{c}\) |
homogeneous class D |
\(y^{\prime }=\frac {y}{x}+g\left ( x\right ) F\left (\frac {y}{x}\right ) \) |
\(x^{2}\) |
\(xy\) |
First order special form ID 1 |
\(y^{\prime }=g\left ( x\right ) e^{h\left (x\right ) +by}+f\left ( x\right ) \) |
\(\frac {e^{-\int bf\left ( x\right )dx-h\left ( x\right ) }}{g\left ( x\right ) }\) |
\(\frac {f\left ( x\right )e^{-\int bf\left ( x\right ) dx-h\left ( x\right ) }}{g\left ( x\right ) }\) |
polynomial type ode |
\(y^{\prime }=\frac {a_{1}x+b_{1}y+c_{1}}{a_{2}x+b_{2}y+c_{2}}\) |
\(\frac {a_{1}b_{2}x-a_{2}b_{1}x-b_{1}c_{2}+b_{2}c_{1}}{a_{1}b_{2}-a_{2}b_{1}}\) |
\(\frac {a_{1}b_{2}y-a_{2}b_{1}y-a_{1}c_{2}-a_{2}c_{1}}{a_{1}b_{2}-a_{2}b_{1}}\) |
Bernoulli ode |
\(y^{\prime }=f\left ( x\right ) y+g\left ( x\right ) y^{n}\) |
\(0\) |
\(e^{-\int \left ( n-1\right ) f\left ( x\right ) dx}y^{n}\) |
Reduced Riccati |
\(y^{\prime }=f_{1}\left ( x\right ) y+f_{2}\left ( x\right )y^{2}\) |
\(0\) |
\(e^{-\int f_{1}dx}\) |
The above table shows that \begin {align*} \xi \left (x,y\right ) &=0\\ \tag {A1} \eta \left (x,y\right ) &=\frac {{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )}}{y} \end {align*}
The next step is to determine the canonical coordinates \(R,S\). The canonical coordinates map \(\left ( x,y\right ) \to \left ( R,S \right )\) where \(\left ( R,S \right )\) are the canonical coordinates which make the original ode become a quadrature and hence solved by integration.
The characteristic pde which is used to find the canonical coordinates is \begin {align*} \frac {d x}{\xi } &= \frac {d y}{\eta } = dS \tag {1} \end {align*}
The above comes from the requirements that \(\left ( \xi \frac {\partial }{\partial x} + \eta \frac {\partial }{\partial y}\right ) S(x,y) = 1\). Starting with the first pair of ode’s in (1) gives an ode to solve for the independent variable \(R\) in the canonical coordinates, where \(S(R)\). Since \(\xi =0\) then in this special case \begin {align*} R = x \end {align*}
\(S\) is found from \begin {align*} S &= \int { \frac {1}{\eta }} dy\\ &= \int { \frac {1}{\frac {{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )}}{y}}} dy \end {align*}
In canonical form, the ODE is \begin {align*} y' &= F(x,y)\\ &= -\frac {g \left (x \right ) y^{2}+h \left (x \right )}{f \left (x \right ) y} \end {align*}
This is a Bernoulli ODE. \[ y' = -\frac {g \left (x \right )}{f \left (x \right )} y -\frac {h \left (x \right )}{f \left (x \right )} \frac {1}{y} \tag {1} \] The standard Bernoulli ODE has the form \[ y' = f_0(x)y+f_1(x)y^n \tag {2} \] The first step is to divide the above equation by \(y^n \) which gives \[ \frac {y'}{y^n} = f_0(x) y^{1-n} +f_1(x) \tag {3} \] The next step is use the substitution \(w = y^{1-n}\) in equation (3) which generates a new ODE in \(w \left (x \right )\) which will be linear and can be easily solved using an integrating factor. Backsubstitution then gives the solution \(y(x)\) which is what we want.
This method is now applied to the ODE at hand. Comparing the ODE (1) With (2) Shows that \begin {align*} f_0(x)&=-\frac {g \left (x \right )}{f \left (x \right )}\\ f_1(x)&=-\frac {h \left (x \right )}{f \left (x \right )}\\ n &=-1 \end {align*}
Dividing both sides of ODE (1) by \(y^n=\frac {1}{y}\) gives \begin {align*} y'y &= -\frac {g \left (x \right ) y^{2}}{f \left (x \right )} -\frac {h \left (x \right )}{f \left (x \right )} \tag {4} \end {align*}
Let \begin {align*} w &= y^{1-n} \\ &= y^{2} \tag {5} \end {align*}
Taking derivative of equation (5) w.r.t \(x\) gives \begin {align*} w' &= 2 yy' \tag {6} \end {align*}
Substituting equations (5) and (6) into equation (4) gives \begin {align*} \frac {w^{\prime }\left (x \right )}{2}&= -\frac {g \left (x \right ) w \left (x \right )}{f \left (x \right )}-\frac {h \left (x \right )}{f \left (x \right )}\\ w' &= -\frac {2 g \left (x \right ) w}{f \left (x \right )}-\frac {2 h \left (x \right )}{f \left (x \right )} \tag {7} \end {align*}
The above now is a linear ODE in \(w \left (x \right )\) which is now solved.
Entering Linear first order ODE solver. In canonical form a linear first order is \begin {align*} w^{\prime }\left (x \right ) + p(x)w \left (x \right ) &= q(x) \end {align*}
Where here \begin {align*} p(x) &=\frac {2 g \left (x \right )}{f \left (x \right )}\\ q(x) &=-\frac {2 h \left (x \right )}{f \left (x \right )} \end {align*}
Hence the ode is \begin {align*} w^{\prime }\left (x \right )+\frac {2 g \left (x \right ) w \left (x \right )}{f \left (x \right )} = -\frac {2 h \left (x \right )}{f \left (x \right )} \end {align*}
The integrating factor \(\mu \) is \[ \mu = {\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} \] The ode becomes \begin {align*} \frac {\mathop {\mathrm {d}}}{ \mathop {\mathrm {d}x}}\left ( \mu w\right ) &= \left (\mu \right ) \left (-\frac {2 h \left (x \right )}{f \left (x \right )}\right ) \\ \frac {\mathop {\mathrm {d}}}{ \mathop {\mathrm {d}x}} \left ({\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} w\right ) &= \left ({\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x}\right ) \left (-\frac {2 h \left (x \right )}{f \left (x \right )}\right )\\ \mathrm {d} \left ({\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} w\right ) &= \left (-\frac {2 \,{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}\right )\, \mathrm {d} x \end {align*}
Integrating gives \begin {align*} {\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} w &= \int {-\frac {2 \,{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}\,\mathrm {d} x}\\ {\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} w &= \int -\frac {2 \,{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x + c_{1} \end {align*}
Dividing both sides by the integrating factor \(\mu ={\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x}\) results in \begin {align*} w \left (x \right ) &= {\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (\int -\frac {2 \,{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} {\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \end {align*}
which simplifies to \begin {align*} w \left (x \right ) &= {\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (-2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} \right ) \end {align*}
Replacing \(w\) in the above by \(y^{2}\) using equation (5) gives the final solution. \begin {align*} y^{2} = {\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (-2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} \right ) \end {align*}
Solving for \(y\) gives \begin {align*} y(x) &=\sqrt {-{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )-c_{1} \right )}\\ y(x) &=-\sqrt {{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (-2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} \right )}\\ \end {align*}
Summary
The solution(s) found are the following \begin{align*} \tag{1} y &= \sqrt {-{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )-c_{1} \right )} \\ \tag{2} y &= -\sqrt {{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (-2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} \right )} \\ \end{align*}
Verification of solutions
\[ y = \sqrt {-{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )-c_{1} \right )} \] Verified OK.
\[ y = -\sqrt {{\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \left (-2 \left (\int \frac {{\mathrm e}^{2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} \right )} \] Verified OK.
Entering Exact first order ODE solver. (Form one type)
To solve an ode of the form\begin {equation} M\left ( x,y\right ) +N\left ( x,y\right ) \frac {dy}{dx}=0\tag {A} \end {equation} We assume there exists a function \(\phi \left ( x,y\right ) =c\) where \(c\) is constant, that satisfies the ode. Taking derivative of \(\phi \) w.r.t. \(x\) gives\[ \frac {d}{dx}\phi \left ( x,y\right ) =0 \] Hence\begin {equation} \frac {\partial \phi }{\partial x}+\frac {\partial \phi }{\partial y}\frac {dy}{dx}=0\tag {B} \end {equation} Comparing (A,B) shows that\begin {align*} \frac {\partial \phi }{\partial x} & =M\\ \frac {\partial \phi }{\partial y} & =N \end {align*}
But since \(\frac {\partial ^{2}\phi }{\partial x\partial y}=\frac {\partial ^{2}\phi }{\partial y\partial x}\) then for the above to be valid, we require that\[ \frac {\partial M}{\partial y}=\frac {\partial N}{\partial x}\] If the above condition is satisfied, then the original ode is called exact. We still need to determine \(\phi \left ( x,y\right ) \) but at least we know now that we can do that since the condition \(\frac {\partial ^{2}\phi }{\partial x\partial y}=\frac {\partial ^{2}\phi }{\partial y\partial x}\) is satisfied. If this condition is not satisfied then this method will not work and we have to now look for an integrating factor to force this condition, which might or might not exist. The first step is to write the ODE in standard form to check for exactness, which is \[ M(x,y) \mathop {\mathrm {d}x}+ N(x,y) \mathop {\mathrm {d}y}=0 \tag {1A} \] Therefore \begin {align*} \left (f \left (x \right ) y\right )\mathop {\mathrm {d}y} &= \left (-g \left (x \right ) y^{2}-h \left (x \right )\right )\mathop {\mathrm {d}x}\\ \left (g \left (x \right ) y^{2}+h \left (x \right )\right )\mathop {\mathrm {d}x} + \left (f \left (x \right ) y\right )\mathop {\mathrm {d}y} &= 0 \tag {2A} \end {align*}
Comparing (1A) and (2A) shows that \begin {align*} M(x,y) &= g \left (x \right ) y^{2}+h \left (x \right )\\ N(x,y) &= f \left (x \right ) y \end {align*}
The next step is to determine if the ODE is is exact or not. The ODE is exact when the following condition is satisfied \[ \frac {\partial M}{\partial y} = \frac {\partial N}{\partial x} \] Using result found above gives \begin {align*} \frac {\partial M}{\partial y} &= \frac {\partial }{\partial y} \left (g \left (x \right ) y^{2}+h \left (x \right )\right )\\ &= 2 y g \left (x \right ) \end {align*}
And \begin {align*} \frac {\partial N}{\partial x} &= \frac {\partial }{\partial x} \left (f \left (x \right ) y\right )\\ &= f^{\prime }\left (x \right ) y \end {align*}
Since \(\frac {\partial M}{\partial y} \neq \frac {\partial N}{\partial x}\), then the ODE is not exact. Since the ODE is not exact, we will try to find an integrating factor to make it exact. Let \begin {align*} A &= \frac {1}{N} \left (\frac {\partial M}{\partial y} - \frac {\partial N}{\partial x} \right ) \\ &=\frac {1}{f \left (x \right ) y}\left ( \left ( 2 y g \left (x \right )\right ) - \left (f^{\prime }\left (x \right ) y \right ) \right ) \\ &=\frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )} \end {align*}
Since \(A\) does not depend on \(y\), then it can be used to find an integrating factor. The integrating factor \(\mu \) is \begin {align*} \mu &= e^{ \int A \mathop {\mathrm {d}x} } \\ &= e^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}\mathop {\mathrm {d}x} } \end {align*}
The result of integrating gives \begin {align*} \mu &= e^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x } \\ &= {\mathrm e}^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x} \end {align*}
\(M\) and \(N\) are multiplied by this integrating factor, giving new \(M\) and new \(N\) which are called \(\overline {M}\) and \(\overline {N}\) for now so not to confuse them with the original \(M\) and \(N\). \begin {align*} \overline {M} &=\mu M \\ &= {\mathrm e}^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x}\left (g \left (x \right ) y^{2}+h \left (x \right )\right ) \\ &= \left (g \left (x \right ) y^{2}+h \left (x \right )\right ) {\mathrm e}^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x} \end {align*}
And \begin {align*} \overline {N} &=\mu N \\ &= {\mathrm e}^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x}\left (f \left (x \right ) y\right ) \\ &= f \left (x \right ) y \,{\mathrm e}^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x} \end {align*}
Now a modified ODE is ontained from the original ODE, which is exact and can be solved. The modified ODE is \begin {align*} \overline {M} + \overline {N} \frac { \mathop {\mathrm {d}y}}{\mathop {\mathrm {d}x}} &= 0 \\ \left (\left (g \left (x \right ) y^{2}+h \left (x \right )\right ) {\mathrm e}^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x}\right ) + \left (f \left (x \right ) y \,{\mathrm e}^{\int \frac {2 g \left (x \right )-f^{\prime }\left (x \right )}{f \left (x \right )}d x}\right ) \frac { \mathop {\mathrm {d}y}}{\mathop {\mathrm {d}x}} &= 0 \end {align*}
The following equations are now set up to solve for the function \(\phi \left (x,y\right )\) \begin {align*} \frac {\partial \phi }{\partial x } &= \overline {M}\tag {1} \\ \frac {\partial \phi }{\partial y } &= \overline {N}\tag {2} \end {align*}
Integrating (1) w.r.t. \(x\) gives
\[ \begin {array}{lll} & {} & \textrm {Let's solve}\hspace {3pt} \\ {} & {} & f \left (x \right ) y y^{\prime }+g \left (x \right ) y^{2}=-h \left (x \right ) \\ \bullet & {} & \textrm {Highest derivative means the order of the ODE is}\hspace {3pt} 1 \\ {} & {} & y^{\prime } \\ \bullet & {} & \textrm {Solve for the highest derivative}\hspace {3pt} \\ {} & {} & y^{\prime }=-\frac {g \left (x \right ) y^{2}+h \left (x \right )}{f \left (x \right ) y} \end {array} \]
Maple trace
`Methods for first order ODEs: --- Trying classification methods --- trying a quadrature trying 1st order linear trying Bernoulli <- Bernoulli successful`
✓ Solution by Maple
Time used: 0.031 (sec). Leaf size: 114
dsolve(f(x)*y(x)*diff(y(x),x)+g(x)*y(x)^2+h(x)=0,y(x), singsol=all)
\begin{align*} y \left (x \right ) &= \sqrt {{\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} \left (-2 \left (\int \frac {{\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} \right )}\, {\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \\ y \left (x \right ) &= -\sqrt {{\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} \left (-2 \left (\int \frac {{\mathrm e}^{\int \frac {2 g \left (x \right )}{f \left (x \right )}d x} h \left (x \right )}{f \left (x \right )}d x \right )+c_{1} \right )}\, {\mathrm e}^{-2 \left (\int \frac {g \left (x \right )}{f \left (x \right )}d x \right )} \\ \end{align*}
✓ Solution by Mathematica
Time used: 0.329 (sec). Leaf size: 146
DSolve[f[x]*y[x]*y'[x]+g[x]*y[x]^2+h[x]==0,y[x],x,IncludeSingularSolutions -> True]
\begin{align*} y(x)\to -\exp \left (\int _1^x-\frac {g(K[1])}{f(K[1])}dK[1]\right ) \sqrt {2 \int _1^x-\frac {\exp \left (-2 \int _1^{K[2]}-\frac {g(K[1])}{f(K[1])}dK[1]\right ) h(K[2])}{f(K[2])}dK[2]+c_1} \\ y(x)\to \exp \left (\int _1^x-\frac {g(K[1])}{f(K[1])}dK[1]\right ) \sqrt {2 \int _1^x-\frac {\exp \left (-2 \int _1^{K[2]}-\frac {g(K[1])}{f(K[1])}dK[1]\right ) h(K[2])}{f(K[2])}dK[2]+c_1} \\ \end{align*}