Consider a Hadamard manifold $\cal M$ with a lower sectional curvature bound $\kappa\leq 0$. Let $W=(w_{ij})\in\mathbb{R}^{n\times n}$ be a symmetric and doubly stochastic matrix, that is, $\sum_{i}w_{ij}=\sum_jw_{ij}=1$, $w_{ij}\geq 0$.  

Now consider the following procedure. For any $n$ points $\{x_i\}_{i=1}^n\subseteq {\cal M}$, we can obtain $n$ points $\{y_i\}_{i=1}^n$ through the weighted Frechet means:
$$
y_i=\arg\min_{y\in{\cal M}}\sum_jw_{ij}d^2(y,x_j),\quad\forall i,
$$
where $d(\cdot,\cdot)$ is the geodesic distance on ${\cal M}$ and $w_{ij}$ are the weights. *Can we prove that the Frechet variance significantly reduces after this procedure* in the sense that
$$
\sum_id^2(y_i,\bar y)\leq \sigma_2^2(W)\cdot \sum_id^2(x_i,\bar x),
$$
where $\sigma_2(W)$ is the second largest singular vlaue of $W$ and $\bar y,\bar x$ are the Frechet means of $\{y_i\}$ and $\{x_i\}$, respectively.