Abel equation of the first kind

If ${\displaystyle f_{3}(x)=0}$  and ${\displaystyle f_{0}(x)=0}$ , or ${\displaystyle f_{2}(x)=0}$  and ${\displaystyle f_{0}(x)=0}$ , the equation reduces to a Bernoulli equation, while if ${\displaystyle f_{3}(x)=0}$  the equation reduces to a Riccati equation.

The substitution ${\displaystyle y={\dfrac {1}{u}}}$  brings the Abel equation of the first kind to the Abel equation of the second kind, of the form

${\displaystyle uu'=-f_{0}(x)u^{3}-f_{1}(x)u^{2}-f_{2}(x)u-f_{3}(x).\,}$ 

The substitution

${\displaystyle {\begin{aligned}\xi &=\int f_{3}(x)E^{2}~dx,\\[6pt]u&=\left(y+{\dfrac {f_{2}(x)}{3f_{3}(x)}}\right)E^{-1},\\[6pt]E&=\exp \left(\int \left(f_{1}(x)-{\frac {f_{2}^{2}(x)}{3f_{3}(x)}}\right)~dx\right)\end{aligned}}}$ 

brings the Abel equation of the first kind to the canonical form

${\displaystyle u'=u^{3}+\phi (\xi ).\,}$ 

Dimitrios E. Panayotounakos and Theodoros I. Zarmpoutis discovered an analytic method to solve the above equation in an implicit form.^[1]

• Panayotounakos, D.E.; Panayotounakou, N.D.; Vakakis, A.F.A (2002). "On the Solution of the Unforced Damped Duffing Oscillator with No Linear Stiffness Term". Nonlinear Dynamics. 28: 1–16. doi:10.1023/A:1014925032022. S2CID 117115358.
• Mancas, Stefan C.; Rosu, Haret C. (2013). "Integrable dissipative nonlinear second order differential equations via factorizations and Abel equations". Physics Letters A. 377: 1434–1438. arXiv:1212.3636. doi:10.1016/j.physleta.2013.04.024.