The role of algebraic solutions in planar polynomial differential systems
Abstract
We study a planar polynomial differential system, given by x=P(x,y), y=Q(x,y). We consider a function I(x,y)= \h2(x) A1(x,y) A0(x,y) \ h1(x) Πi=1 (y-gi(x))αi, where gi(x) are algebraic functions, A1(x,y)=Πk=1r (y-ak(x)), A0(x,y)=Πj=1s (y-gj(x)) with ak(x) and gj(x) algebraic functions, A0 and A1 do not share any common factor, h2(x) is a rational function, h(x) and h1(x) are functions with a rational logarithmic derivative and αi are complex numbers. We show that if I(x,y) is a first integral or an integrating factor, then I(x,y) is a Darboux function. In order to prove this result, we show that if g(x) is such that there exists an irreducible polynomial f(x,y) with f(x,g(x)) 0, then f(x,y)=0 is an invariant algebraic curve of the system. In relation with this fact, we give some characteristics related to particular solutions and functions of the form I(x,y) such as the structure of their cofactor. Moreover, we consider a function of the form (x,y):= \h2(x) A1(x,y) / A0 (x,y) \. We show that if the derivative of (x,y) with respect to the flow is well defined over A0(x,y)=0 then (x,y) gives rise to an exponential factor.
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