Internal problem ID [8878]
Internal file name [OUTPUT/7813_Monday_June_06_2022_12_31_42_AM_87592513/index.tex]
Book: Differential Gleichungen, E. Kamke, 3rd ed. Chelsea Pub. NY, 1948
Section: Chapter 1, linear first order
Problem number: 544.
ODE order: 1.
ODE degree: 3.
The type(s) of ODE detected by this program : "unknown"
Maple gives the following as the ode type
[[_homogeneous, `class G`]]
Unable to solve or complete the solution.
\[ \boxed {x^{7} y^{2} {y^{\prime }}^{3}-\left (3 y^{3} x^{6}-1\right ) {y^{\prime }}^{2}+3 x^{5} y^{4} y^{\prime }-y^{5} x^{4}=0} \] Solving the given ode for \(y^{\prime }\) results in \(3\) differential equations to solve. Each one of these will generate a solution. The equations generated are \begin {align*} y^{\prime }&=\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}-\frac {2 \left (6 y^{3} x^{6}-1\right )}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}} \tag {1} \\ y^{\prime }&=-\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{12 y^{2} x^{7}}+\frac {6 y^{3} x^{6}-1}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}}+\frac {i \sqrt {3}\, \left (\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}+\frac {4 y^{3} x^{6}-\frac {2}{3}}{y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}\right )}{2} \tag {2} \\ y^{\prime }&=-\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{12 y^{2} x^{7}}+\frac {6 y^{3} x^{6}-1}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}}-\frac {i \sqrt {3}\, \left (\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}+\frac {4 y^{3} x^{6}-\frac {2}{3}}{y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}\right )}{2} \tag {3} \end {align*}
Now each one of the above ODE is solved.
Solving equation (1)
Writing the ode as \begin {align*} y^{\prime }&=\frac {6 y^{3} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{6}-24 x^{6} y^{3}+{\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{2}/{3}}-2 {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}}+4}{6 y^{2} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{7}}\\ 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 not in the lookup table. To determine \(\xi ,\eta \) then (A) is solved using ansatz. Making bivariate polynomials of degree 1 to use as anstaz gives \begin{align*} \tag{1E} \xi &= x a_{2}+y a_{3}+a_{1} \\ \tag{2E} \eta &= x b_{2}+y b_{3}+b_{1} \\ \end{align*} Where the unknown coefficients are \[ \{a_{1}, a_{2}, a_{3}, b_{1}, b_{2}, b_{3}\} \] Substituting equations (1E,2E) and \(\omega \) into (A) gives \begin{equation} \tag{5E} \text {Expression too large to display} \end{equation} Putting the above in normal form gives \[ \text {Expression too large to display} \] Setting the numerator to zero gives \begin{equation} \tag{6E} \text {Expression too large to display} \end{equation} Simplifying the above gives \begin{equation} \tag{6E} \text {Expression too large to display} \end{equation} Since the PDE has radicals, simplifying gives \[ \text {Expression too large to display} \] Looking at the above PDE shows the following are all the terms with \(\{x, y\}\) in them. \[ \left \{x, y, {\left (\sqrt {3}\, \left (-27 \sqrt {3}\, x^{12} y^{6}+9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}+18 \sqrt {3}\, x^{6} y^{3}-2 \sqrt {3}\right )\right )}^{{1}/{3}}, {\left (\sqrt {3}\, \left (-27 \sqrt {3}\, x^{12} y^{6}+9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}+18 \sqrt {3}\, x^{6} y^{3}-2 \sqrt {3}\right )\right )}^{{2}/{3}}, \sqrt {\frac {27 x^{6} y^{3}-4}{y}}\right \} \] The following substitution is now made to be able to collect on all terms with \(\{x, y\}\) in them \[ \left \{x = v_{1}, y = v_{2}, {\left (\sqrt {3}\, \left (-27 \sqrt {3}\, x^{12} y^{6}+9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}+18 \sqrt {3}\, x^{6} y^{3}-2 \sqrt {3}\right )\right )}^{{1}/{3}} = v_{3}, {\left (\sqrt {3}\, \left (-27 \sqrt {3}\, x^{12} y^{6}+9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}+18 \sqrt {3}\, x^{6} y^{3}-2 \sqrt {3}\right )\right )}^{{2}/{3}} = v_{4}, \sqrt {\frac {27 x^{6} y^{3}-4}{y}} = v_{5}\right \} \] The above PDE (6E) now becomes \begin{equation} \tag{7E} \text {Expression too large to display} \end{equation} Collecting the above on the terms \(v_i\) introduced, and these are \[ \{v_{1}, v_{2}, v_{3}, v_{4}, v_{5}\} \] Equation (7E) now becomes \begin{equation} \tag{8E} \text {Expression too large to display} \end{equation} Setting each coefficients in (8E) to zero gives the following equations to solve \begin {align*} -59616 a_{1}&=0\\ -1344 a_{1}&=0\\ 16704 a_{1}&=0\\ 77760 a_{1}&=0\\ -6048 a_{3}&=0\\ -4608 a_{3}&=0\\ -192 a_{3}&=0\\ 2112 a_{3}&=0\\ 23328 a_{3}&=0\\ -10368 b_{1}&=0\\ -384 b_{1}&=0\\ 4032 b_{1}&=0\\ 15552 b_{1}&=0\\ -10368 b_{2}&=0\\ -384 b_{2}&=0\\ 4032 b_{2}&=0\\ 15552 b_{2}&=0\\ -233280 \sqrt {3}\, a_{1}&=0\\ -11520 \sqrt {3}\, a_{1}&=0\\ 113184 \sqrt {3}\, a_{1}&=0\\ -69984 \sqrt {3}\, a_{3}&=0\\ -4320 \sqrt {3}\, a_{3}&=0\\ -1536 \sqrt {3}\, a_{3}&=0\\ 12672 \sqrt {3}\, a_{3}&=0\\ -46656 \sqrt {3}\, b_{1}&=0\\ -4032 \sqrt {3}\, b_{1}&=0\\ 34560 \sqrt {3}\, b_{1}&=0\\ -46656 \sqrt {3}\, b_{2}&=0\\ -4032 \sqrt {3}\, b_{2}&=0\\ 34560 \sqrt {3}\, b_{2}&=0\\ -1296 \,6^{{1}/{3}} a_{1}&=0\\ -224 \,6^{{1}/{3}} a_{1}&=0\\ 1440 \,6^{{1}/{3}} a_{1}&=0\\ -432 \,6^{{1}/{3}} a_{3}&=0\\ -32 \,6^{{1}/{3}} a_{3}&=0\\ 160 \,6^{{1}/{3}} a_{3}&=0\\ 192 \,6^{{1}/{3}} a_{3}&=0\\ -64 \,6^{{1}/{3}} b_{1}&=0\\ 288 \,6^{{1}/{3}} b_{1}&=0\\ -64 \,6^{{1}/{3}} b_{2}&=0\\ 288 \,6^{{1}/{3}} b_{2}&=0\\ -2112 \,6^{{2}/{3}} a_{1}&=0\\ -1296 \,6^{{2}/{3}} a_{1}&=0\\ 224 \,6^{{2}/{3}} a_{1}&=0\\ 3888 \,6^{{2}/{3}} a_{1}&=0\\ -256 \,6^{{2}/{3}} a_{3}&=0\\ 32 \,6^{{2}/{3}} a_{3}&=0\\ 144 \,6^{{2}/{3}} a_{3}&=0\\ 432 \,6^{{2}/{3}} a_{3}&=0\\ -480 \,6^{{2}/{3}} b_{1}&=0\\ 64 \,6^{{2}/{3}} b_{1}&=0\\ 1296 \,6^{{2}/{3}} b_{1}&=0\\ -576 \,6^{{2}/{3}} b_{2}&=0\\ 64 \,6^{{2}/{3}} b_{2}&=0\\ 864 \,6^{{2}/{3}} b_{2}&=0\\ -768 \,6^{{1}/{3}} \sqrt {3}\, a_{1}&=0\\ 3888 \,6^{{1}/{3}} \sqrt {3}\, a_{1}&=0\\ -128 \,6^{{1}/{3}} \sqrt {3}\, a_{3}&=0\\ 480 \,6^{{1}/{3}} \sqrt {3}\, a_{3}&=0\\ 1296 \,6^{{1}/{3}} \sqrt {3}\, a_{3}&=0\\ -96 \,6^{{1}/{3}} \sqrt {3}\, b_{1}&=0\\ -96 \,6^{{1}/{3}} \sqrt {3}\, b_{2}&=0\\ -9648 \,6^{{2}/{3}} \sqrt {3}\, a_{1}&=0\\ 1344 \,6^{{2}/{3}} \sqrt {3}\, a_{1}&=0\\ 3888 \,6^{{2}/{3}} \sqrt {3}\, a_{1}&=0\\ -1296 \,6^{{2}/{3}} \sqrt {3}\, a_{3}&=0\\ -1104 \,6^{{2}/{3}} \sqrt {3}\, a_{3}&=0\\ 192 \,6^{{2}/{3}} \sqrt {3}\, a_{3}&=0\\ -3888 \,6^{{2}/{3}} \sqrt {3}\, b_{1}&=0\\ -2016 \,6^{{2}/{3}} \sqrt {3}\, b_{1}&=0\\ 384 \,6^{{2}/{3}} \sqrt {3}\, b_{1}&=0\\ -2592 \,6^{{2}/{3}} \sqrt {3}\, b_{2}&=0\\ 384 \,6^{{2}/{3}} \sqrt {3}\, b_{2}&=0\\ -46656 a_{2}-23328 b_{3}&=0\\ -1152 a_{2}-576 b_{3}&=0\\ 13824 a_{2}+6912 b_{3}&=0\\ 62208 a_{2}+31104 b_{3}&=0\\ -186624 \sqrt {3}\, a_{2}-93312 \sqrt {3}\, b_{3}&=0\\ -10368 \sqrt {3}\, a_{2}-5184 \sqrt {3}\, b_{3}&=0\\ 98496 \sqrt {3}\, a_{2}+49248 \sqrt {3}\, b_{3}&=0\\ -864 \,6^{{1}/{3}} a_{2}-432 \,6^{{1}/{3}} b_{3}&=0\\ -192 \,6^{{1}/{3}} a_{2}-96 \,6^{{1}/{3}} b_{3}&=0\\ 1152 \,6^{{1}/{3}} a_{2}+576 \,6^{{1}/{3}} b_{3}&=0\\ -1728 \,6^{{2}/{3}} a_{2}-864 \,6^{{2}/{3}} b_{3}&=0\\ 192 \,6^{{2}/{3}} a_{2}+96 \,6^{{2}/{3}} b_{3}&=0\\ 2592 \,6^{{2}/{3}} a_{2}+1296 \,6^{{2}/{3}} b_{3}&=0\\ -576 \,6^{{1}/{3}} \sqrt {3}\, a_{2}-288 \,6^{{1}/{3}} \sqrt {3}\, b_{3}&=0\\ 2592 \,6^{{1}/{3}} \sqrt {3}\, a_{2}+1296 \,6^{{1}/{3}} \sqrt {3}\, b_{3}&=0\\ -7776 \,6^{{2}/{3}} \sqrt {3}\, a_{2}-3888 \,6^{{2}/{3}} \sqrt {3}\, b_{3}&=0\\ 1152 \,6^{{2}/{3}} \sqrt {3}\, a_{2}+576 \,6^{{2}/{3}} \sqrt {3}\, b_{3}&=0 \end {align*}
Solving the above equations for the unknowns gives \begin {align*} a_{1}&=0\\ a_{2}&=a_{2}\\ a_{3}&=0\\ b_{1}&=0\\ b_{2}&=0\\ b_{3}&=-2 a_{2} \end {align*}
Substituting the above solution in the anstaz (1E,2E) (using \(1\) as arbitrary value for any unknown in the RHS) gives \begin{align*} \xi &= x \\ \eta &= -2 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 \(S(R)\). Unable to determine \(R\). Terminating
Unable to determine ODE type.
Solving equation (2)
Writing the ode as \begin {align*} y^{\prime }&=\frac {3 i y^{3} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{6} \sqrt {3}+12 i y^{3} \sqrt {3}\, x^{6}+3 y^{3} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{6}-12 x^{6} y^{3}-i {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} \sqrt {3}-2 i \sqrt {3}-{\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{2}/{3}}-{\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}}+2}{3 y^{2} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{7} \left (1+i \sqrt {3}\right )}\\ 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 not in the lookup table. To determine \(\xi ,\eta \) then (A) is solved using ansatz. Making bivariate polynomials of degree 1 to use as anstaz gives \begin{align*} \tag{1E} \xi &= x a_{2}+y a_{3}+a_{1} \\ \tag{2E} \eta &= x b_{2}+y b_{3}+b_{1} \\ \end{align*} Where the unknown coefficients are \[ \{a_{1}, a_{2}, a_{3}, b_{1}, b_{2}, b_{3}\} \] Substituting equations (1E,2E) and \(\omega \) into (A) gives \begin{equation} \tag{5E} \text {Expression too large to display} \end{equation} Putting the above in normal form gives \[ \text {Expression too large to display} \] Setting the numerator to zero gives \begin{equation} \tag{6E} \text {Expression too large to display} \end{equation} Simplifying the above gives \begin{equation} \tag{6E} \text {Expression too large to display} \end{equation} Since the PDE has radicals, simplifying gives \[ \text {Expression too large to display} \] Looking at the above PDE shows the following are all the terms with \(\{x, y\}\) in them. \[ \left \{x, y, \sqrt {\frac {27 x^{6} y^{3}-4}{y}}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{1}/{3}}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{2}/{3}}\right \} \] The following substitution is now made to be able to collect on all terms with \(\{x, y\}\) in them \[ \left \{x = v_{1}, y = v_{2}, \sqrt {\frac {27 x^{6} y^{3}-4}{y}} = v_{3}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{1}/{3}} = v_{4}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{2}/{3}} = v_{5}\right \} \] The above PDE (6E) now becomes \begin{equation} \tag{7E} \text {Expression too large to display} \end{equation} Collecting the above on the terms \(v_i\) introduced, and these are \[ \{v_{1}, v_{2}, v_{3}, v_{4}, v_{5}\} \] Equation (7E) now becomes \begin{equation} \tag{8E} \text {Expression too large to display} \end{equation} Setting each coefficients in (8E) to zero gives the following equations to solve \begin {align*} -59616 a_{1}&=0\\ -1344 a_{1}&=0\\ 16704 a_{1}&=0\\ 77760 a_{1}&=0\\ -6048 a_{3}&=0\\ -4608 a_{3}&=0\\ -192 a_{3}&=0\\ 2112 a_{3}&=0\\ 23328 a_{3}&=0\\ -10368 b_{1}&=0\\ -384 b_{1}&=0\\ 4032 b_{1}&=0\\ 15552 b_{1}&=0\\ -10368 b_{2}&=0\\ -384 b_{2}&=0\\ 4032 b_{2}&=0\\ 15552 b_{2}&=0\\ -233280 \sqrt {3}\, a_{1}&=0\\ -11520 \sqrt {3}\, a_{1}&=0\\ 113184 \sqrt {3}\, a_{1}&=0\\ -69984 \sqrt {3}\, a_{3}&=0\\ -4320 \sqrt {3}\, a_{3}&=0\\ -1536 \sqrt {3}\, a_{3}&=0\\ 12672 \sqrt {3}\, a_{3}&=0\\ -46656 \sqrt {3}\, b_{1}&=0\\ -4032 \sqrt {3}\, b_{1}&=0\\ 34560 \sqrt {3}\, b_{1}&=0\\ -46656 \sqrt {3}\, b_{2}&=0\\ -4032 \sqrt {3}\, b_{2}&=0\\ 34560 \sqrt {3}\, b_{2}&=0\\ -1152 a_{2}-576 b_{3}&=0\\ 13824 a_{2}+6912 b_{3}&=0\\ 62208 a_{2}+31104 b_{3}&=0\\ -23328 b_{3}-46656 a_{2}&=0\\ -186624 \sqrt {3}\, a_{2}-93312 \sqrt {3}\, b_{3}&=0\\ -10368 \sqrt {3}\, a_{2}-5184 \sqrt {3}\, b_{3}&=0\\ 98496 \sqrt {3}\, a_{2}+49248 \sqrt {3}\, b_{3}&=0\\ -14472 i 6^{{2}/{3}} a_{1}+4824 \sqrt {3}\, 6^{{2}/{3}} a_{1}&=0\\ -5832 i 6^{{1}/{3}} a_{1}-1944 \sqrt {3}\, 6^{{1}/{3}} a_{1}&=0\\ -5832 i 6^{{2}/{3}} b_{1}+1944 \sqrt {3}\, 6^{{2}/{3}} b_{1}&=0\\ -3888 i 6^{{2}/{3}} b_{2}+1296 \sqrt {3}\, 6^{{2}/{3}} b_{2}&=0\\ -3024 i 6^{{2}/{3}} b_{1}+1008 \sqrt {3}\, 6^{{2}/{3}} b_{1}&=0\\ -1944 i 6^{{1}/{3}} a_{3}-648 \sqrt {3}\, 6^{{1}/{3}} a_{3}&=0\\ -1944 i 6^{{2}/{3}} a_{3}+648 \sqrt {3}\, 6^{{2}/{3}} a_{3}&=0\\ -1656 i 6^{{2}/{3}} a_{3}+552 \sqrt {3}\, 6^{{2}/{3}} a_{3}&=0\\ -720 i 6^{{1}/{3}} a_{3}-240 \sqrt {3}\, 6^{{1}/{3}} a_{3}&=0\\ 144 i 6^{{1}/{3}} b_{1}+48 \sqrt {3}\, 6^{{1}/{3}} b_{1}&=0\\ 144 i 6^{{1}/{3}} b_{2}+48 \sqrt {3}\, 6^{{1}/{3}} b_{2}&=0\\ 192 i 6^{{1}/{3}} a_{3}+64 \sqrt {3}\, 6^{{1}/{3}} a_{3}&=0\\ 288 i 6^{{2}/{3}} a_{3}-96 \sqrt {3}\, 6^{{2}/{3}} a_{3}&=0\\ 576 i 6^{{2}/{3}} b_{1}-192 \sqrt {3}\, 6^{{2}/{3}} b_{1}&=0\\ 576 i 6^{{2}/{3}} b_{2}-192 \sqrt {3}\, 6^{{2}/{3}} b_{2}&=0\\ 1152 i 6^{{1}/{3}} a_{1}+384 \sqrt {3}\, 6^{{1}/{3}} a_{1}&=0\\ 2016 i 6^{{2}/{3}} a_{1}-672 \sqrt {3}\, 6^{{2}/{3}} a_{1}&=0\\ 5832 i 6^{{2}/{3}} a_{1}-1944 \sqrt {3}\, 6^{{2}/{3}} a_{1}&=0\\ -1056 i \sqrt {3}\, 6^{{2}/{3}} a_{1}+1056 \,6^{{2}/{3}} a_{1}&=0\\ -720 i \sqrt {3}\, 6^{{1}/{3}} a_{1}-720 \,6^{{1}/{3}} a_{1}&=0\\ -648 i \sqrt {3}\, 6^{{2}/{3}} a_{1}+648 \,6^{{2}/{3}} a_{1}&=0\\ -288 i \sqrt {3}\, 6^{{2}/{3}} b_{2}+288 \,6^{{2}/{3}} b_{2}&=0\\ -240 i \sqrt {3}\, 6^{{2}/{3}} b_{1}+240 \,6^{{2}/{3}} b_{1}&=0\\ -144 i \sqrt {3}\, 6^{{1}/{3}} b_{1}-144 \,6^{{1}/{3}} b_{1}&=0\\ -144 i \sqrt {3}\, 6^{{1}/{3}} b_{2}-144 \,6^{{1}/{3}} b_{2}&=0\\ -128 i \sqrt {3}\, 6^{{2}/{3}} a_{3}+128 \,6^{{2}/{3}} a_{3}&=0\\ -96 i \sqrt {3}\, 6^{{1}/{3}} a_{3}-96 a_{3} 6^{{1}/{3}}&=0\\ -80 i \sqrt {3}\, 6^{{1}/{3}} a_{3}-80 a_{3} 6^{{1}/{3}}&=0\\ 16 i \sqrt {3}\, 6^{{1}/{3}} a_{3}+16 a_{3} 6^{{1}/{3}}&=0\\ 16 i \sqrt {3}\, 6^{{2}/{3}} a_{3}-16 \,6^{{2}/{3}} a_{3}&=0\\ 32 i \sqrt {3}\, 6^{{1}/{3}} b_{1}+32 \,6^{{1}/{3}} b_{1}&=0\\ 32 i \sqrt {3}\, 6^{{1}/{3}} b_{2}+32 \,6^{{1}/{3}} b_{2}&=0\\ 32 i \sqrt {3}\, 6^{{2}/{3}} b_{1}-32 \,6^{{2}/{3}} b_{1}&=0\\ 32 i \sqrt {3}\, 6^{{2}/{3}} b_{2}-32 \,6^{{2}/{3}} b_{2}&=0\\ 72 i \sqrt {3}\, 6^{{2}/{3}} a_{3}-72 \,6^{{2}/{3}} a_{3}&=0\\ 112 i \sqrt {3}\, 6^{{1}/{3}} a_{1}+112 \,6^{{1}/{3}} a_{1}&=0\\ 112 i \sqrt {3}\, 6^{{2}/{3}} a_{1}-112 \,6^{{2}/{3}} a_{1}&=0\\ 216 i \sqrt {3}\, 6^{{1}/{3}} a_{3}+216 a_{3} 6^{{1}/{3}}&=0\\ 216 i \sqrt {3}\, 6^{{2}/{3}} a_{3}-216 \,6^{{2}/{3}} a_{3}&=0\\ 432 i \sqrt {3}\, 6^{{2}/{3}} b_{2}-432 \,6^{{2}/{3}} b_{2}&=0\\ 648 i \sqrt {3}\, 6^{{1}/{3}} a_{1}+648 \,6^{{1}/{3}} a_{1}&=0\\ 648 i \sqrt {3}\, 6^{{2}/{3}} b_{1}-648 \,6^{{2}/{3}} b_{1}&=0\\ 1944 i \sqrt {3}\, 6^{{2}/{3}} a_{1}-1944 \,6^{{2}/{3}} a_{1}&=0\\ -11664 i 6^{{2}/{3}} a_{2}-5832 i 6^{{2}/{3}} b_{3}+3888 \sqrt {3}\, 6^{{2}/{3}} a_{2}+1944 \sqrt {3}\, 6^{{2}/{3}} b_{3}&=0\\ -3888 i 6^{{1}/{3}} a_{2}-1944 i 6^{{1}/{3}} b_{3}-1296 \sqrt {3}\, 6^{{1}/{3}} a_{2}-648 \sqrt {3}\, 6^{{1}/{3}} b_{3}&=0\\ 864 i 6^{{1}/{3}} a_{2}+432 i 6^{{1}/{3}} b_{3}+288 \sqrt {3}\, 6^{{1}/{3}} a_{2}+144 \sqrt {3}\, 6^{{1}/{3}} b_{3}&=0\\ 1728 i 6^{{2}/{3}} a_{2}+864 i 6^{{2}/{3}} b_{3}-576 \sqrt {3}\, 6^{{2}/{3}} a_{2}-288 \sqrt {3}\, 6^{{2}/{3}} b_{3}&=0\\ -864 i \sqrt {3}\, 6^{{2}/{3}} a_{2}-432 i \sqrt {3}\, 6^{{2}/{3}} b_{3}+864 \,6^{{2}/{3}} a_{2}+432 \,6^{{2}/{3}} b_{3}&=0\\ -576 i \sqrt {3}\, 6^{{1}/{3}} a_{2}-288 i \sqrt {3}\, 6^{{1}/{3}} b_{3}-576 \,6^{{1}/{3}} a_{2}-288 \,6^{{1}/{3}} b_{3}&=0\\ 96 i \sqrt {3}\, 6^{{1}/{3}} a_{2}+48 i \sqrt {3}\, 6^{{1}/{3}} b_{3}+96 \,6^{{1}/{3}} a_{2}+48 \,6^{{1}/{3}} b_{3}&=0\\ 96 i \sqrt {3}\, 6^{{2}/{3}} a_{2}+48 i \sqrt {3}\, 6^{{2}/{3}} b_{3}-96 \,6^{{2}/{3}} a_{2}-48 \,6^{{2}/{3}} b_{3}&=0\\ 432 i \sqrt {3}\, 6^{{1}/{3}} a_{2}+216 i \sqrt {3}\, 6^{{1}/{3}} b_{3}+432 \,6^{{1}/{3}} a_{2}+216 \,6^{{1}/{3}} b_{3}&=0\\ 1296 i \sqrt {3}\, 6^{{2}/{3}} a_{2}+648 i \sqrt {3}\, 6^{{2}/{3}} b_{3}-1296 \,6^{{2}/{3}} a_{2}-648 \,6^{{2}/{3}} b_{3}&=0 \end {align*}
Solving the above equations for the unknowns gives \begin {align*} a_{1}&=0\\ a_{2}&=a_{2}\\ a_{3}&=0\\ b_{1}&=0\\ b_{2}&=0\\ b_{3}&=-2 a_{2} \end {align*}
Substituting the above solution in the anstaz (1E,2E) (using \(1\) as arbitrary value for any unknown in the RHS) gives \begin{align*} \xi &= x \\ \eta &= -2 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 \(S(R)\). Unable to determine \(R\). Terminating
Unable to determine ODE type.
Solving equation (3)
Writing the ode as \begin {align*} y^{\prime }&=\frac {3 i y^{3} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{6} \sqrt {3}+12 i y^{3} \sqrt {3}\, x^{6}-3 y^{3} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{6}+12 x^{6} y^{3}-i {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} \sqrt {3}-2 i \sqrt {3}+{\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{2}/{3}}+{\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}}-2}{3 y^{2} {\left (-\frac {4 \sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )}{3}\right )}^{{1}/{3}} x^{7} \left (i \sqrt {3}-1\right )}\\ 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 not in the lookup table. To determine \(\xi ,\eta \) then (A) is solved using ansatz. Making bivariate polynomials of degree 1 to use as anstaz gives \begin{align*} \tag{1E} \xi &= x a_{2}+y a_{3}+a_{1} \\ \tag{2E} \eta &= x b_{2}+y b_{3}+b_{1} \\ \end{align*} Where the unknown coefficients are \[ \{a_{1}, a_{2}, a_{3}, b_{1}, b_{2}, b_{3}\} \] Substituting equations (1E,2E) and \(\omega \) into (A) gives \begin{equation} \tag{5E} \text {Expression too large to display} \end{equation} Putting the above in normal form gives \[ \text {Expression too large to display} \] Setting the numerator to zero gives \begin{equation} \tag{6E} \text {Expression too large to display} \end{equation} Simplifying the above gives \begin{equation} \tag{6E} \text {Expression too large to display} \end{equation} Since the PDE has radicals, simplifying gives \[ \text {Expression too large to display} \] Looking at the above PDE shows the following are all the terms with \(\{x, y\}\) in them. \[ \left \{x, y, \sqrt {\frac {27 x^{6} y^{3}-4}{y}}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{1}/{3}}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{2}/{3}}\right \} \] The following substitution is now made to be able to collect on all terms with \(\{x, y\}\) in them \[ \left \{x = v_{1}, y = v_{2}, \sqrt {\frac {27 x^{6} y^{3}-4}{y}} = v_{3}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{1}/{3}} = v_{4}, {\left (-\sqrt {3}\, \left (27 \sqrt {3}\, x^{12} y^{6}-9 x^{9} y^{5} \sqrt {\frac {27 x^{6} y^{3}-4}{y}}-18 \sqrt {3}\, x^{6} y^{3}+2 \sqrt {3}\right )\right )}^{{2}/{3}} = v_{5}\right \} \] The above PDE (6E) now becomes \begin{equation} \tag{7E} \text {Expression too large to display} \end{equation} Collecting the above on the terms \(v_i\) introduced, and these are \[ \{v_{1}, v_{2}, v_{3}, v_{4}, v_{5}\} \] Equation (7E) now becomes \begin{equation} \tag{8E} \text {Expression too large to display} \end{equation} Setting each coefficients in (8E) to zero gives the following equations to solve \begin {align*} -59616 a_{1}&=0\\ -1344 a_{1}&=0\\ 16704 a_{1}&=0\\ 77760 a_{1}&=0\\ -6048 a_{3}&=0\\ -4608 a_{3}&=0\\ -192 a_{3}&=0\\ 2112 a_{3}&=0\\ 23328 a_{3}&=0\\ -10368 b_{1}&=0\\ -384 b_{1}&=0\\ 4032 b_{1}&=0\\ 15552 b_{1}&=0\\ -10368 b_{2}&=0\\ -384 b_{2}&=0\\ 4032 b_{2}&=0\\ 15552 b_{2}&=0\\ -233280 \sqrt {3}\, a_{1}&=0\\ -11520 \sqrt {3}\, a_{1}&=0\\ 113184 \sqrt {3}\, a_{1}&=0\\ -69984 \sqrt {3}\, a_{3}&=0\\ -4320 \sqrt {3}\, a_{3}&=0\\ -1536 \sqrt {3}\, a_{3}&=0\\ 12672 \sqrt {3}\, a_{3}&=0\\ -46656 \sqrt {3}\, b_{1}&=0\\ -4032 \sqrt {3}\, b_{1}&=0\\ 34560 \sqrt {3}\, b_{1}&=0\\ -46656 \sqrt {3}\, b_{2}&=0\\ -4032 \sqrt {3}\, b_{2}&=0\\ 34560 \sqrt {3}\, b_{2}&=0\\ -46656 a_{2}-23328 b_{3}&=0\\ -1152 a_{2}-576 b_{3}&=0\\ 13824 a_{2}+6912 b_{3}&=0\\ 62208 a_{2}+31104 b_{3}&=0\\ -186624 \sqrt {3}\, a_{2}-93312 \sqrt {3}\, b_{3}&=0\\ -10368 \sqrt {3}\, a_{2}-5184 \sqrt {3}\, b_{3}&=0\\ 98496 \sqrt {3}\, a_{2}+49248 \sqrt {3}\, b_{3}&=0\\ -5832 i 6^{{2}/{3}} a_{1}-1944 \,6^{{2}/{3}} \sqrt {3}\, a_{1}&=0\\ -2016 i 6^{{2}/{3}} a_{1}-672 \,6^{{2}/{3}} \sqrt {3}\, a_{1}&=0\\ -1152 i 6^{{1}/{3}} a_{1}+384 \,6^{{1}/{3}} \sqrt {3}\, a_{1}&=0\\ -576 i 6^{{2}/{3}} b_{1}-192 \,6^{{2}/{3}} \sqrt {3}\, b_{1}&=0\\ -576 i 6^{{2}/{3}} b_{2}-192 \,6^{{2}/{3}} \sqrt {3}\, b_{2}&=0\\ -288 i 6^{{2}/{3}} a_{3}-96 \,6^{{2}/{3}} \sqrt {3}\, a_{3}&=0\\ -192 i 6^{{1}/{3}} a_{3}+64 \sqrt {3}\, 6^{{1}/{3}} a_{3}&=0\\ -144 i 6^{{1}/{3}} b_{1}+48 \,6^{{1}/{3}} \sqrt {3}\, b_{1}&=0\\ -144 i 6^{{1}/{3}} b_{2}+48 \,6^{{1}/{3}} \sqrt {3}\, b_{2}&=0\\ 720 i 6^{{1}/{3}} a_{3}-240 \sqrt {3}\, 6^{{1}/{3}} a_{3}&=0\\ 1656 i 6^{{2}/{3}} a_{3}+552 \,6^{{2}/{3}} \sqrt {3}\, a_{3}&=0\\ 1944 i 6^{{1}/{3}} a_{3}-648 \sqrt {3}\, 6^{{1}/{3}} a_{3}&=0\\ 1944 i 6^{{2}/{3}} a_{3}+648 \,6^{{2}/{3}} \sqrt {3}\, a_{3}&=0\\ 3024 i 6^{{2}/{3}} b_{1}+1008 \,6^{{2}/{3}} \sqrt {3}\, b_{1}&=0\\ 3888 i 6^{{2}/{3}} b_{2}+1296 \,6^{{2}/{3}} \sqrt {3}\, b_{2}&=0\\ 5832 i 6^{{1}/{3}} a_{1}-1944 \,6^{{1}/{3}} \sqrt {3}\, a_{1}&=0\\ 5832 i 6^{{2}/{3}} b_{1}+1944 \,6^{{2}/{3}} \sqrt {3}\, b_{1}&=0\\ 14472 i 6^{{2}/{3}} a_{1}+4824 \,6^{{2}/{3}} \sqrt {3}\, a_{1}&=0\\ -1944 i 6^{{2}/{3}} \sqrt {3}\, a_{1}-1944 \,6^{{2}/{3}} a_{1}&=0\\ -648 i 6^{{1}/{3}} \sqrt {3}\, a_{1}+648 \,6^{{1}/{3}} a_{1}&=0\\ -648 i 6^{{2}/{3}} \sqrt {3}\, b_{1}-648 \,6^{{2}/{3}} b_{1}&=0\\ -432 i 6^{{2}/{3}} \sqrt {3}\, b_{2}-432 \,6^{{2}/{3}} b_{2}&=0\\ -216 i \sqrt {3}\, 6^{{1}/{3}} a_{3}+216 \,6^{{1}/{3}} a_{3}&=0\\ -216 i 6^{{2}/{3}} \sqrt {3}\, a_{3}-216 \,6^{{2}/{3}} a_{3}&=0\\ -112 i 6^{{1}/{3}} \sqrt {3}\, a_{1}+112 \,6^{{1}/{3}} a_{1}&=0\\ -112 i 6^{{2}/{3}} \sqrt {3}\, a_{1}-112 \,6^{{2}/{3}} a_{1}&=0\\ -72 i 6^{{2}/{3}} \sqrt {3}\, a_{3}-72 \,6^{{2}/{3}} a_{3}&=0\\ -32 i 6^{{1}/{3}} \sqrt {3}\, b_{1}+32 \,6^{{1}/{3}} b_{1}&=0\\ -32 i 6^{{1}/{3}} \sqrt {3}\, b_{2}+32 \,6^{{1}/{3}} b_{2}&=0\\ -32 i 6^{{2}/{3}} \sqrt {3}\, b_{1}-32 \,6^{{2}/{3}} b_{1}&=0\\ -32 i 6^{{2}/{3}} \sqrt {3}\, b_{2}-32 \,6^{{2}/{3}} b_{2}&=0\\ -16 i \sqrt {3}\, 6^{{1}/{3}} a_{3}+16 \,6^{{1}/{3}} a_{3}&=0\\ -16 i 6^{{2}/{3}} \sqrt {3}\, a_{3}-16 \,6^{{2}/{3}} a_{3}&=0\\ 80 i \sqrt {3}\, 6^{{1}/{3}} a_{3}-80 \,6^{{1}/{3}} a_{3}&=0\\ 96 i \sqrt {3}\, 6^{{1}/{3}} a_{3}-96 \,6^{{1}/{3}} a_{3}&=0\\ 128 i 6^{{2}/{3}} \sqrt {3}\, a_{3}+128 \,6^{{2}/{3}} a_{3}&=0\\ 144 i 6^{{1}/{3}} \sqrt {3}\, b_{1}-144 \,6^{{1}/{3}} b_{1}&=0\\ 144 i 6^{{1}/{3}} \sqrt {3}\, b_{2}-144 \,6^{{1}/{3}} b_{2}&=0\\ 240 i 6^{{2}/{3}} \sqrt {3}\, b_{1}+240 \,6^{{2}/{3}} b_{1}&=0\\ 288 i 6^{{2}/{3}} \sqrt {3}\, b_{2}+288 \,6^{{2}/{3}} b_{2}&=0\\ 648 i 6^{{2}/{3}} \sqrt {3}\, a_{1}+648 \,6^{{2}/{3}} a_{1}&=0\\ 720 i 6^{{1}/{3}} \sqrt {3}\, a_{1}-720 \,6^{{1}/{3}} a_{1}&=0\\ 1056 i 6^{{2}/{3}} \sqrt {3}\, a_{1}+1056 \,6^{{2}/{3}} a_{1}&=0\\ -1728 i 6^{{2}/{3}} a_{2}-864 i 6^{{2}/{3}} b_{3}-576 \,6^{{2}/{3}} \sqrt {3}\, a_{2}-288 \,6^{{2}/{3}} \sqrt {3}\, b_{3}&=0\\ -864 i 6^{{1}/{3}} a_{2}-432 i 6^{{1}/{3}} b_{3}+288 \,6^{{1}/{3}} \sqrt {3}\, a_{2}+144 \sqrt {3}\, 6^{{1}/{3}} b_{3}&=0\\ 3888 i 6^{{1}/{3}} a_{2}+1944 i 6^{{1}/{3}} b_{3}-1296 \,6^{{1}/{3}} \sqrt {3}\, a_{2}-648 \sqrt {3}\, 6^{{1}/{3}} b_{3}&=0\\ 11664 i 6^{{2}/{3}} a_{2}+5832 i 6^{{2}/{3}} b_{3}+3888 \,6^{{2}/{3}} \sqrt {3}\, a_{2}+1944 \,6^{{2}/{3}} \sqrt {3}\, b_{3}&=0\\ -1296 i 6^{{2}/{3}} \sqrt {3}\, a_{2}-648 i 6^{{2}/{3}} \sqrt {3}\, b_{3}-1296 \,6^{{2}/{3}} a_{2}-648 \,6^{{2}/{3}} b_{3}&=0\\ -432 i 6^{{1}/{3}} \sqrt {3}\, a_{2}-216 i \sqrt {3}\, 6^{{1}/{3}} b_{3}+432 \,6^{{1}/{3}} a_{2}+216 \,6^{{1}/{3}} b_{3}&=0\\ -96 i 6^{{1}/{3}} \sqrt {3}\, a_{2}-48 i \sqrt {3}\, 6^{{1}/{3}} b_{3}+96 \,6^{{1}/{3}} a_{2}+48 \,6^{{1}/{3}} b_{3}&=0\\ -96 i 6^{{2}/{3}} \sqrt {3}\, a_{2}-48 i 6^{{2}/{3}} \sqrt {3}\, b_{3}-96 \,6^{{2}/{3}} a_{2}-48 \,6^{{2}/{3}} b_{3}&=0\\ 576 i 6^{{1}/{3}} \sqrt {3}\, a_{2}+288 i \sqrt {3}\, 6^{{1}/{3}} b_{3}-576 \,6^{{1}/{3}} a_{2}-288 \,6^{{1}/{3}} b_{3}&=0\\ 864 i 6^{{2}/{3}} \sqrt {3}\, a_{2}+432 i 6^{{2}/{3}} \sqrt {3}\, b_{3}+864 \,6^{{2}/{3}} a_{2}+432 \,6^{{2}/{3}} b_{3}&=0 \end {align*}
Solving the above equations for the unknowns gives \begin {align*} a_{1}&=0\\ a_{2}&=a_{2}\\ a_{3}&=0\\ b_{1}&=0\\ b_{2}&=0\\ b_{3}&=-2 a_{2} \end {align*}
Substituting the above solution in the anstaz (1E,2E) (using \(1\) as arbitrary value for any unknown in the RHS) gives \begin{align*} \xi &= x \\ \eta &= -2 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 \(S(R)\). Unable to determine \(R\). Terminating
Unable to determine ODE type.
\[ \begin {array}{lll} & {} & \textrm {Let's solve}\hspace {3pt} \\ {} & {} & x^{7} y^{2} {y^{\prime }}^{3}-\left (3 y^{3} x^{6}-1\right ) {y^{\prime }}^{2}+3 x^{5} y^{4} y^{\prime }-y^{5} 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} \\ {} & {} & \left [y^{\prime }=\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}-\frac {2 \left (6 y^{3} x^{6}-1\right )}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}}, y^{\prime }=-\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{12 y^{2} x^{7}}+\frac {6 y^{3} x^{6}-1}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}}-\frac {\mathrm {I} \sqrt {3}\, \left (\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}+\frac {2 \left (6 y^{3} x^{6}-1\right )}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}\right )}{2}, y^{\prime }=-\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{12 y^{2} x^{7}}+\frac {6 y^{3} x^{6}-1}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}}+\frac {\mathrm {I} \sqrt {3}\, \left (\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}+\frac {2 \left (6 y^{3} x^{6}-1\right )}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}\right )}{2}\right ] \\ \bullet & {} & \textrm {Solve the equation}\hspace {3pt} y^{\prime }=\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}-\frac {2 \left (6 y^{3} x^{6}-1\right )}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}} \\ \bullet & {} & \textrm {Solve the equation}\hspace {3pt} y^{\prime }=-\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{12 y^{2} x^{7}}+\frac {6 y^{3} x^{6}-1}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}}-\frac {\mathrm {I} \sqrt {3}\, \left (\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}+\frac {2 \left (6 y^{3} x^{6}-1\right )}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}\right )}{2} \\ \bullet & {} & \textrm {Solve the equation}\hspace {3pt} y^{\prime }=-\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{12 y^{2} x^{7}}+\frac {6 y^{3} x^{6}-1}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}+\frac {3 y^{3} x^{6}-1}{3 y^{2} x^{7}}+\frac {\mathrm {I} \sqrt {3}\, \left (\frac {\left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}{6 y^{2} x^{7}}+\frac {2 \left (6 y^{3} x^{6}-1\right )}{3 y^{2} x^{7} \left (-108 y^{6} x^{12}+12 \sqrt {3}\, \sqrt {\frac {27 y^{3} x^{6}-4}{y}}\, y^{5} x^{9}+72 y^{3} x^{6}-8\right )^{{1}/{3}}}\right )}{2} \\ \bullet & {} & \textrm {Set of solutions}\hspace {3pt} \\ {} & {} & \left \{\mathit {workingODE} , \mathit {workingODE} , \mathit {workingODE}\right \} \end {array} \]
Maple trace
`Methods for first order ODEs: *** Sublevel 2 *** Methods for first order ODEs: -> Solving 1st order ODE of high degree, 1st attempt trying 1st order WeierstrassP solution for high degree ODE trying 1st order WeierstrassPPrime solution for high degree ODE trying 1st order JacobiSN solution for high degree ODE trying 1st order ODE linearizable_by_differentiation trying differential order: 1; missing variables trying simple symmetries for implicit equations Successful isolation of dy/dx: 3 solutions were found. Trying to solve each resulting ODE. *** Sublevel 3 *** Methods for first order ODEs: --- Trying classification methods --- trying homogeneous types: trying homogeneous G trying an integrating factor from the invariance group <- integrating factor successful <- homogeneous successful ------------------- * Tackling next ODE. *** Sublevel 3 *** Methods for first order ODEs: --- Trying classification methods --- trying homogeneous types: trying homogeneous G trying an integrating factor from the invariance group <- integrating factor successful <- homogeneous successful ------------------- * Tackling next ODE. *** Sublevel 3 *** Methods for first order ODEs: --- Trying classification methods --- trying homogeneous types: trying homogeneous G trying an integrating factor from the invariance group <- integrating factor successful <- homogeneous successful`
✓ Solution by Maple
Time used: 0.937 (sec). Leaf size: 4638
dsolve(x^7*y(x)^2*diff(y(x),x)^3-(3*x^6*y(x)^3-1)*diff(y(x),x)^2+3*x^5*y(x)^4*diff(y(x),x)-x^4*y(x)^5=0,y(x), singsol=all)
\begin{align*} y \left (x \right ) &= \frac {2^{\frac {2}{3}}}{3 x^{2}} \\ y \left (x \right ) &= -\frac {2^{\frac {2}{3}} \left (1+i \sqrt {3}\right )}{6 x^{2}} \\ y \left (x \right ) &= \frac {2^{\frac {2}{3}} \left (i \sqrt {3}-1\right )}{6 x^{2}} \\ y \left (x \right ) &= 0 \\ \text {Expression too large to display} \\ \text {Expression too large to display} \\ \text {Expression too large to display} \\ \end{align*}
✓ Solution by Mathematica
Time used: 2.117 (sec). Leaf size: 80
DSolve[-(x^4*y[x]^5) + 3*x^5*y[x]^4*y'[x] - (-1 + 3*x^6*y[x]^3)*y'[x]^2 + x^7*y[x]^2*y'[x]^3==0,y[x],x,IncludeSingularSolutions -> True]
\begin{align*} y(x)\to \sqrt [3]{c_1 x^3+c_1{}^{2/3}} \\ y(x)\to 0 \\ y(x)\to \frac {(-2)^{2/3}}{3 x^2} \\ y(x)\to \frac {2^{2/3}}{3 x^2} \\ y(x)\to -\frac {\sqrt [3]{-1} 2^{2/3}}{3 x^2} \\ \end{align*}