Difference between revisions of "Darboux integral"
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A [[first integral]] of a polynomial vector field on the plane, which has a specific form, the product of (non-integer) powers and exponentials of rational functions. | A [[first integral]] of a polynomial vector field on the plane, which has a specific form, the product of (non-integer) powers and exponentials of rational functions. | ||
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=== Invariant curves, factors and cofactors=== | === Invariant curves, factors and cofactors=== | ||
− | Let $v=P(x,y)\partial_x+Q(x,y)\partial_y$ be a polynomial vector field on the plane, with $P,Q\in\R[x,y]$, having only isolated singularities (i.e., $\gcd(P,Q)=1$); denote by $\omega$ the | + | Let $v=P(x,y)\partial_x+Q(x,y)\partial_y$ be a polynomial vector field on the plane, with $P,Q\in\R[x,y]$, having only isolated singularities (i.e., $\gcd(P,Q)=1$); denote by $\omega$ the polynomial $1$-form $-Q(x,y)\rd x+P(x,y)\rd y$ annulating $v$, so that $\omega\cdot v\equiv0$. |
An reduced (square-free) algebraic curve $\Gamma=\{R(x,y)=0\}$ is called an ''invariant curve'', or ''particular integral'' of the field $v$ (resp., the form $\omega)$, if $v$ is tangent to the curve at all smooth points of the latter. This means that the polynomial $\rd R\cdot v$ vanishes on $\Gamma$, hence is divisible by $R$: | An reduced (square-free) algebraic curve $\Gamma=\{R(x,y)=0\}$ is called an ''invariant curve'', or ''particular integral'' of the field $v$ (resp., the form $\omega)$, if $v$ is tangent to the curve at all smooth points of the latter. This means that the polynomial $\rd R\cdot v$ vanishes on $\Gamma$, hence is divisible by $R$: | ||
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The polynomial $K$ is called the ''cofactor'' of the curve $\Gamma$. | The polynomial $K$ is called the ''cofactor'' of the curve $\Gamma$. | ||
− | If the polynomial $R$ is reducible, $R=R_1\cdots R_k$ (without repetitions), then each of the irreducible invariant curves $\Gamma_i=\{R_i=0\}$ is a particular integral with the corresponding cofactors $K_i$ defined by the equations $\rd R_i\cdot v = R_i K_i$, $i=1,\dots,k$. Obviously, $K=K_1+\cdots+K_k$. | + | If the polynomial $R$ is reducible, $R=R_1\cdots R_k$ (without repetitions), then each of the irreducible invariant curves $\Gamma_i=\{R_i=0\}$ is a particular integral with the corresponding cofactors $K_i$ defined by the equations $\rd R_i\cdot v = R_i K_i$, $i=1,\dots,k$. Obviously, $K=K_1+\cdots+K_k$. |
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===Integrability theorems=== | ===Integrability theorems=== | ||
Let $n=\deg v=\max(\deg P,\deg Q)$ be the degree of the vector field. In general, it is not possible to place an upper bound on the degree $m=\deg \Gamma=\deg R$ of its integral curves<ref>See [[Poincare problem]].</ref>, the degree of the cofactor is always $n+(m-1)-m=n-1$. Thus the space of possible cofactors is finite-dimensional and its dimension is $\frac12 n(n+1)$. This number is the natural bound for the number of "nontrivial" invariant curves. | Let $n=\deg v=\max(\deg P,\deg Q)$ be the degree of the vector field. In general, it is not possible to place an upper bound on the degree $m=\deg \Gamma=\deg R$ of its integral curves<ref>See [[Poincare problem]].</ref>, the degree of the cofactor is always $n+(m-1)-m=n-1$. Thus the space of possible cofactors is finite-dimensional and its dimension is $\frac12 n(n+1)$. This number is the natural bound for the number of "nontrivial" invariant curves. | ||
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====Basic references==== | ====Basic references==== | ||
− | < | + | <references/> |
Latest revision as of 09:08, 12 December 2013
A first integral of a polynomial vector field on the plane, which has a specific form, the product of (non-integer) powers and exponentials of rational functions.
For upper and lower integral sums of a Riemann integrable function, see Darboux sums.
Invariant curves, factors and cofactors
Let $v=P(x,y)\partial_x+Q(x,y)\partial_y$ be a polynomial vector field on the plane, with $P,Q\in\R[x,y]$, having only isolated singularities (i.e., $\gcd(P,Q)=1$); denote by $\omega$ the polynomial $1$-form $-Q(x,y)\rd x+P(x,y)\rd y$ annulating $v$, so that $\omega\cdot v\equiv0$.
An reduced (square-free) algebraic curve $\Gamma=\{R(x,y)=0\}$ is called an invariant curve, or particular integral of the field $v$ (resp., the form $\omega)$, if $v$ is tangent to the curve at all smooth points of the latter. This means that the polynomial $\rd R\cdot v$ vanishes on $\Gamma$, hence is divisible by $R$: $$ \rd R\cdot v=KR,\qquad K=K(x,y)\in\R[x,y]. $$ The polynomial $K$ is called the cofactor of the curve $\Gamma$.
If the polynomial $R$ is reducible, $R=R_1\cdots R_k$ (without repetitions), then each of the irreducible invariant curves $\Gamma_i=\{R_i=0\}$ is a particular integral with the corresponding cofactors $K_i$ defined by the equations $\rd R_i\cdot v = R_i K_i$, $i=1,\dots,k$. Obviously, $K=K_1+\cdots+K_k$.
Integrability theorems
Let $n=\deg v=\max(\deg P,\deg Q)$ be the degree of the vector field. In general, it is not possible to place an upper bound on the degree $m=\deg \Gamma=\deg R$ of its integral curves[1], the degree of the cofactor is always $n+(m-1)-m=n-1$. Thus the space of possible cofactors is finite-dimensional and its dimension is $\frac12 n(n+1)$. This number is the natural bound for the number of "nontrivial" invariant curves.
Theorem (G. Darboux). If a polynomial vector field has $k\ge \frac12 n(n+1)+1$ different irreducible algebraic invariant curves $\Gamma_1=\{R_1=0\},\dots\Gamma_k=\{R_k=0\}$, then the field admits a first integral $H$, such that $\rd H\cdot v\equiv0$, of the form $$ H(x,y)=R_1^{\lambda_1}(x,y)\cdots R_k^{\lambda_k}(x,y),\qquad \lambda_1,\dots,\lambda_k\in\C, \tag DI $$ with the complex exponents $\lambda_1,\dots,\lambda_k$ not all equal to zero.
Definition. The function (DI) is referred to as the Darboux integral of the vector field.
Theorem (J.-P. Jouanolou, 1979[2]). If the number $k$ of the different irreducible algebraic invariant curves is greater or equal to $\frac12 n(n+1)+2$ (one more than before), then $v$ has a rational first integral $$ H(x,y)=\frac{F(x,y)}{G(x,y)},\qquad F,G\in\C[x,y],\ G\not\equiv0. $$
Vector fields with a Darbouxian (or rational) integrals are called integrable: they cannot exhibit limit cycles, one of the most elusive objects defined by ordinary differential equations on the plane.
Darbouxian integrability in the Pfaffian form
A Pfaffian form $\omega$ determines the distribution of lines tangent to the plane; this distribution does not change (except for the formal domain) after multiplication of $\omega$ by a rational function. Thus without loss of generality instead of polynomial, one can consider the class of rational Pfaffian forms tangent to the same vector field.
Definition. A Pfaffian differential equation $\omega=0$ with a rational 1-form $\omega$ is called Darboux integrable[3], if $\omega$ is a closed rational 1-form, $\rd \omega=0$.
Denote by $\varSigma\subset\C^2$ the algebraic curve which is the polar locus of the rational 1-form $\omega$, $\varSigma=\Gamma_1\cup\cdots\cup\Gamma_k$ is its representation as the union of the irreducible components defined by polynomial equations $\Gamma_i=\{R_i=0\}$, $i=1,\dots,k$.
Lemma. A closed rational 1-form with the polar locus $\varSigma$ has the form $$ \omega=\sum_{i=1}^k \lambda_i\frac{\rd R_i}{R_i}+\rd \biggl(\frac{F}{G}\biggr),\qquad \lambda_i\in\C,\ R_i,F,G\in\C[x,y]. $$
A vector field which is tangent to a closed rational 1-form admits a generalized Darboux first integral, $$ H(x,y)=\prod_{i=1}^k R_i^{\lambda_i}\cdot\exp(F/G), $$ which also excludes the appearance of limit cycles.
Appearance of the exponential factors can be explained by confluence of distinct but close algebraic invariant curves[4].
Basic references
- ↑ See Poincare problem.
- ↑ Jouanolou, J.-P. Équations de Pfaff algébriques, Lecture Notes in Mathematics, 708. Springer, Berlin, 1979. MR0537038.
- ↑ Ilyashenko, Yu., Yakovenko, S., Lectures on analytic differential equations, Graduate Studies in Mathematics, 86. American Mathematical Society, Providence, RI, 2008. MR2363178
- ↑ Christopher, C., Llibre, J., Pereira, J., Multiplicity of invariant algebraic curves in polynomial vector fields, Pacific J. Math. 229 (2007), no. 1, 63--117. MR2276503.
Darboux integral. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Darboux_integral&oldid=25838