I'm interested in numerical methods on $\mathrm{SO}(3)$ manifold, and working on a particular problem using the exponential coordinates. These can be computed using the Rodrigues' formula:
$$
R(u) := \exp(u_\times)=\mathrm{Id} +\frac{\sin(a)}{a}u_\times +\frac{1-\cos(a)}{a^2}u_\times^2
$$
with $a:=|u|$, $u\in \mathbb{R}^3$ and where $u_\times \in \mathfrak{so}(3)$ is the cross-product matrix of vector $u$.\
Its differential with respect to $u$ is:
$$
D_u[R(u)X] = -[R(u)X]_\times T(u)
$$
for any vector $X\in \mathbb{R}^3$, where
$$
T(u) := \int_0^1R(su)ds = \mathrm{Id} +\frac{1-\cos(a)}{a^2}u_\times+\frac{a-\sin(a)}{a^3}u_\times^2
$$
We can restate this by saying that the directional derivative of $R(u)$ in the direction $Y$ is:
$$
[D_u R]Y = [T(u)Y]_\times R(u)
$$
Both $R$ and $T$ are Lipschitz continuous:
$$
\|R(u)-R(v)\| \le|u-v| \\
\|T(u)-T(v)\| \le \frac{1}{2}|u-v|
$$
for any $u$ and $v$, where I use the operator norm (subordinate norm) of the Euclidean norm.
To prove the convergence of Newton's iterations for the numerical method I'm using (conditions of Kantorovich) I need to estimate a bound on the second derivative (which is really hard to compute explicitly as far as I know), or a bound on:
$$
\|D_u[R(u)X] - D_v[R(v)X]\| = \sup_{|Y|=1}\left([R(u)X] \times [T(u)Y] - [R(v)X] \times [T(v)Y]\right)
$$
that is I need to show that the derivative $D_u[R(u)X]$ is Lipschitz continuous in $u$. I found experimentally (using a program) that
$$
\|[R(u)X]_\times T(u) - [R(v)X]_\times T(v)\| \le \left|X\right| \left|u-v\right|
$$
or equivalently that:
$$
\big|[R(u)X] \times [T(u)Y] - [R(v)X] \times [T(v)Y]\big| \le \left|X\right| \left|Y\right| \left|u-v\right|
$$
for any vectors $X$ and $Y$. Any hints on how to prove this last inequality would be greatly appreciated. Thanks for your time!
**Edit:** It's possible to show a weaker statement using the triangle inequality:
$$
\big|[R(u)X] \times [T(u)Y] - [R(v)X] \times [T(v)Y]\big| \le \frac{3}{2} \left|X\right| \left|Y\right| \left|u-v\right|
$$
but experimentally this bound is never reached.