Wavelet transform

In mathematics, a Lie algebra $g$ is nilpotent if the lower central series

g > [g, g] > [[g, g], g] > [[[g, g], g], g] > \dots

becomes zero eventually. Equivalently, $g$ is nilpotent if

ad (x_{1}) ad (x_{2}) ad (x_{3}) . . . ad (x_{r}) = 0

for any sequence $x_{i}$ of elements of $g$ of sufficiently large length. (Here, $ad (x)$ is given by $ad (x) y = [x, y]$ .) Consequences are that $ad (x)$ is nilpotent (as a linear map), and that the Killing form of a nilpotent Lie algebra is identically zero. (In comparison, a Lie algebra is semisimple if and only if its Killing form is nondegenerate.)

Every nilpotent Lie algebra is solvable; this fact gives one of the powerful ways to prove the solvability of a Lie algebra since, in practice, it is usually easier to prove the nilpotency than the solvability. The converse is not true in general. A Lie algebra $g$ is nilpotent if and only if its quotient over an ideal containing the center of $g$ is nilpotent.

Most of classic classification results on nilpotency are concerned with finite-dimensional Lie algebras over a field of characteristic 0. Let $g$ be a finite-dimensional Lie algebra. $g$ is nilpotent if and only if $ad (g)$ is nilpotent. Engel's theorem states that $g$ is nilpotent if and only if $ad (x)$ is nilpotent for every $x \in g$ . $g$ is solvable if and only if $[g, g]$ is nilpotent.

Examples

Every subalgebra and quotient of a nilpotent Lie algebra is nilpotent.
If ${g l}_{k}$ is the set of $k \times k$ matrices, then the subalgebra consisting of strictly upper triangular matrices, denoted by $n_{k}$ , is a nilpotent Lie algebra.
A Heisenberg algebra is nilpotent.
A Cartan subalgebra of a Lie algebra is nilpotent and self-normalizing.

References

Humphreys, James E. Introduction to Lie Algebras and Representation Theory. Graduate Texts in Mathematics, 9. Springer-Verlag, New York, 1972. ISBN 0-387-90053-5

Wavelet transform

Examples

References

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