Abstract This paper presents a comprehensive dimensional design and optimization strategy for a redundantly actuated space quadruped climbing robot (SQCR). Our approach focuses on non-dimensional optimization, utilizing a dimensionally normalized Jacobian and a design space dimensionality reduction method (DSDRM) for both the leg mechanisms and the overall robot structure. A key component of this strategy is a novel performance evaluation framework, the Dominant Joint-Workspace Partitioning Framework (DJ-WPF).The DJ-WPF uses a Joint Participation Index (JPI) to identify dominant actuators for different regions of the workspace, enabling the selection of optimal region-specific actuator sets. Using this framework, we generate performance atlases to visualize key indicators and identify high-performing design regions. An optimal set of non-dimensional parameters is then determined using a weighted averaging method. Finally, these parameters are scaled to physical dimensions under practical constraints. The resulting optimized design achieves a condition index and minimum payload index that are 50.19% and 79.3% of their theoretical maximums, respectively, while reducing computational cost.
Shen et al. (Wed,) studied this question.
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