In mathematics, a jet group is a generalization of the general linear group which applies to Taylor polynomials instead of vectors at a point. A jet group is a group of jets that describes how a Taylor polynomial transforms under changes of coordinate systems (or, equivalently, diffeomorphisms).
The k-th order jet group G<sup>n</sup><sub>k</sub> consists of jets of smooth diffeomorphisms ÃÂ: R<sup>n</sup> â R<sup>n</sup> such that ÃÂ(0)=0.
The following is a more precise definition of the jet group.
Let k âÂÂ¥ 2. The differential of a function f: R<sup>k</sup> â R can be interpreted as a section of the cotangent bundle of R<sup>K</sup> given by df: R<sup>k</sup> â T*R<sup>k</sup>. Similarly, derivatives of order up to m are sections of the jet bundle J<sup>m</sup>(R<sup>k</sup>) = R<sup>k</sup> àW, where
Here R* is the dual vector space to R, and S<sup>i</sup> denotes the i-th symmetric power. A smooth function f: R<sup>k</sup> â R has a prolongation j<sup>m</sup>f: R<sup>k</sup> â J<sup>m</sup>(R<sup>k</sup>) defined at each point p â R<sup>k</sup> by placing the i-th partials of f at p in the S<sup>i</sup>((R*)<sup>k</sup>) component of W.
Consider a point . There is a unique polynomial f<sub>p</sub> in k variables and of order m such that p is in the image of j<sup>m</sup>f<sub>p</sub>. That is, . The differential data xâ² may be transferred to lie over another point y â R<sup>n</sup> as j<sup>m</sup>f<sub>p</sub>(y) , the partials of f<sub>p</sub> over y.
Provide J<sup>m</sup>(R<sup>n</sup>) with a group structure by taking
With this group structure, J<sup>m</sup>(R<sup>n</sup>) is a Carnot group of class m + 1.
Because of the properties of jets under function composition, G<sup>n</sup><sub>k</sub> is a Lie group. The jet group is a semidirect product of the general linear group and a connected, simply connected nilpotent Lie group. It is also in fact an algebraic group, since the composition involves only polynomial operations.