On Semidefinite Relaxations for Matrix-Weighted State-Estimation Problems in Robotics
arxiv(2023)
摘要
In recent years, there has been remarkable progress in the development of
so-called certifiable perception methods, which leverage semidefinite, convex
relaxations to find global optima of perception problems in robotics. However,
many of these relaxations rely on simplifying assumptions that facilitate the
problem formulation, such as an isotropic measurement noise distribution. In
this paper, we explore the tightness of the semidefinite relaxations of
matrix-weighted (anisotropic) state-estimation problems and reveal the
limitations lurking therein: matrix-weighted factors can cause convex
relaxations to lose tightness. In particular, we show that the semidefinite
relaxations of localization problems with matrix weights may be tight only for
low noise levels. To better understand this issue, we introduce a theoretical
connection between the posterior uncertainty of the state estimate and the dual
variable of the convex relaxation. With this connection in mind, we empirically
explore the factors that contribute to this loss of tightness and demonstrate
that redundant constraints can be used to regain it. As a second technical
contribution of this paper, we show that the state-of-the-art relaxation of
scalar-weighted SLAM cannot be used when matrix weights are considered. We
provide an alternate formulation and show that its SDP relaxation is not tight
(even for very low noise levels) unless specific redundant constraints are
used. We demonstrate the tightness of our formulations on both simulated and
real-world data.
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