A computational framework using relative Jacobian kinematics, differentiable SDF collision modeling, and constrained gradient projection on the self-motion manifold enables accurate, collision-free trajectory optimization for redundant robotic multi-axis additive manufacturing.
Trajectory Optimization on Manifolds: A Theoretically-Guaranteed Embedded Sequential Convex Programming Approach
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abstract
Sequential Convex Programming (SCP) has recently gained popularity as a tool for trajectory optimization due to its sound theoretical properties and practical performance. Yet, most SCP-based methods for trajectory optimization are restricted to Euclidean settings, which precludes their application to problem instances where one must reason about manifold-type constraints (that is, constraints, such as loop closure, which restrict the motion of a system to a subset of the ambient space). The aim of this paper is to fill this gap by extending SCP-based trajectory optimization methods to a manifold setting. The key insight is to leverage geometric embeddings to lift a manifold-constrained trajectory optimization problem into an equivalent problem defined over a space enjoying a Euclidean structure. This insight allows one to extend existing SCP methods to a manifold setting in a fairly natural way. In particular, we present a SCP algorithm for manifold problems with refined theoretical guarantees that resemble those derived for the Euclidean setting, and demonstrate its practical performance via numerical experiments.
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cs.RO 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Trajectory Optimization for Collision-Aware Redundant Robotic Multi-Axis Additive Manufacturing by Constrained Gradient Projection
A computational framework using relative Jacobian kinematics, differentiable SDF collision modeling, and constrained gradient projection on the self-motion manifold enables accurate, collision-free trajectory optimization for redundant robotic multi-axis additive manufacturing.