Аннотация:
We describe new fine properties of Carnot–Carathéodory spaces under
minimal assumptions on smoothness of the basis vector fields. As a
corollary, we discover new geometric properties of weighted
Carnot-Caratheodory spaces. All these results are new even for a “smooth”
case. They play crucial role in the development of the differentiability
theory on sub-Riemannian structures (see, e.g., works by S. Vodopyanov
[1, 2]), in the investigation of non-equiregular
Carnot–Carathéodory spaces (see, e.g., work by S. Selivanova
[3]) and imply many basic results of the theory of non-holonomic
spaces (see, e.g., work by S. Basalaev and S. Vodopyanov [4]).
$ $ Definition (see, e.g., [5, 2, 4, 6, 7]).
Fix a connected Riemannian $C^{\infty}$-manifold $\mathbb M$ of topological dimension $N$. The
manifold $\mathbb M$ is called the
Carnot–Carathéodory space if the
tangent bundle $T\mathbb M$ has a filtration
$$
H\mathbb M=H_1\mathbb M\subsetneq\ldots\subsetneq H_i\mathbb M\subsetneq\ldots\subsetneq H_M\mathbb M=T\mathbb M
$$
by subbundles such that every
point $p\in\mathbb M$ has a neighborhood $U\subset\mathbb M$
equipped with a collection of $C^{1}$-smooth vector fields
$X_1,\dots,X_N$ enjoying the following two properties.
$ $ (1) At every point $v\in U$ we have a subspace
$$
H_i\mathbb M(v)=H_i(v)=\operatorname{span}\{X_1(v),\dots,X_{\dim H_i}(v)\}\subset T_v\mathbb M
$$
of the dimension $\dim H_i$ independent of $v$, $i=1,\ldots,M$.
$ $ (2) The inclusion
$[H_i, H_j]\subset H_{i+j}$,
$i+j\leq M$, holds.
$ $ Moreover, if the third condition holds then the Carnot–Carathéodory space is called the Carnot manifold:
$ $ (3) $H_{j+1}=\operatorname{span}\{H_j, [H_1,H_{j}], [H_2,H_{j-1}],\ldots,[H_k, H_{j+1-k}]\}$, where $k=\bigl[\frac{j+1}{2}\bigr]$, $H_0=\{0\}$, $j=1,\ldots, M-1$.
$ $ The subbundle $H\mathbb M$ is called horizontal.
The number $M$ is called the depth of the manifold $\mathbb
M$.
$ $ The main result is the following
$ $ Theorem[6, 7].Let$\mathbb M$be a Carnot–Carathéodory space with$C^{1,\alpha}$-smooth basis vector fields,$\alpha\geq0$ (if$\alpha=0$then the fields belong to the class$C^1$). Then for each point of$\mathbb M$, there exists a sufficiently small neighborhood$\mathcal U\Subset\mathbb M$possessing the following property: for$u,v\in \mathcal U$, $w=\gamma(1)$and$\widehat{w}=\widehat{\gamma}(1)$, where$\gamma,\widehat{\gamma}:[0,1]\to\mathbb M$are absolutely continuous (in the classical sense)
curves contained
in$\operatorname{Box}(u, \varepsilon)$such that \begin{equation*}
\dot{\gamma}(t)=\sum\limits_{i=1}^Nb_i(t)X_i(\gamma(t)),\ \gamma(0)=v,
\quad\text{and}\quad
\dot{\widehat{\gamma}}(t)=\sum\limits_{i=1}^Nb_i(t)\widehat{X}^u_i(\gamma(t)),\ \widehat{\gamma}(0)=v,
\end{equation*} and each measurable function$b_i(t)$meets the property $$
\tag{1}
\int_0^1|b_i(t)|\,dt<S\varepsilon^{\operatorname{deg}X_i},
$$ $S<\infty$, $i=1,\ldots, N$, we have $$
\tag{2}
\max\{d_{\infty}(w,\widehat{w}), d^u_{\infty}(w,\widehat{w})\}=
\begin{cases}
O(1)\cdot\varepsilon^{1+\frac{\alpha}{M}} \text{ if }\alpha>0,\\
o(1)\cdot\varepsilon\text{ if }\alpha=0,
\end{cases}
$$ with$O(1)$and$o(1)$to be uniform in$u\in\mathcal U$and all collections of functions$\{b_i(t)\}_{i=1}^N$with the property (1).
$ $ Remark[7] (see also [8]).
For weighted Carnot–Carathéodory spaces, the estimate in (2) is $O(1)\cdot\varepsilon^{1+\frac{\alpha}{l_M}}$ for $\alpha>0$, where $l_M$ is the maximal weight [3, 7, 8].
$ $ The research is supported by Grant of the Government of Russian Federation for the State Support of Researches (Agreement No 14.B25.31.0029).
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