dc.description.abstract |
Tremendously increasing variations in the robotic applications has led to the
importance of utilizing hybrid configurations for the design of robotic manipulators.
The motivation lies in the fact that serially connected links are normally selected
for larger manipulability, and parallel manipulators are utilized for better positional
accuracy. Common choices of hybrid configurations include either serially connected
parallelograms or a loop inserted in a serial manipulator at different locations. With
various hybrid combinations possible, even with a fixed number of degrees-of-freedom
(dof), the experience and previous knowledge play key roles in the selection of a basic
configuration. Once a basic structure is selected, it is followed by some systematic/optimal
geometric synthesis, kinematic and/or dynamic design methodologies. However,
selection of a basic structure of a manipulator configuration itself is critical enough,
which needs further attention. Literature digests are presented for quick visualization
of the research directions related to the proposed work, arranged with respect to their
era and area.
To provide solutions for the selection of a hybrid morphology, performance
analysis platform and optimal dimensional synthesis of planar hybrid manipulators,
the work has been planned in four phases — random morphology generation, retrieval
of kinematic information, unified performance evaluation criteria and evolutionary
synthesis for planar hybrid manipulators. ‘Morphology’ here is referred to a basic
kinematic framework for a manipulator. A large set of hybrid configurations are
randomly generated for a range of number of degree-of-freedom and evaluated through
a proposed unified approach for kinematic performance analysis. This provides a most
suitable planar hybrid morphology selection for a given set of task-space locations.
In the first phase, the work is to randomly generate the variations in the possible
morphologies of planar hybrid manipulators with any number of links. For this, a
stipulated range of number of degrees-of-freedom had been considered and all the
possible variations in manipulators with links connected in series and/or loops had
been explored with the help of introduction of Mechanism Assembly Matrix (MAM).
Each element of the matrix signifies a joint between the row-indexed link and the
column-indexed link.
After generation of MAM, the major task was to retrieve the linkage information
corresponding to each generated morphology. This information was required to perform
the analysis in next phase. Major challenge in retrieval of such information is faced
due to variations in the randomly generated mechanisms. For this, a graph-theorybased
algorithmic framework had been developed for the determination of kinematic
information. This includes all serially connected links, link numbers, number of loops,
loops locations and sizes, base location and the end-effector link of the generated hybrid
manipulators.
The development of general performance evaluation criteria has gone through
various stages, to develop a unified approach for computation of randomly generated
morphologies. Due to the variations in the basic configurations, one of the major
challenge was the development of kinematic models corresponding to each generated
linkage. A unified approach is proposed for kinematic modelling and performance
evaluation criteria of generated linkages. The proposed approach is verified for specific
cases of planar hybrid morphologies. Comparative study is detailed based upon the
computational efforts, extendibility and modularity of the approach.
Final phase of the work deals with the integration of methodologies proposed
for three phases, and utilizing the resulting overall approach for evolutionary design
of all selected configurations. The evolutionary algorithm had been simulated for
selection of the best possible manipulator morphology for a specified task. Jacobian
based conditioning index has been considered as the performance criteria for optimal
dimensional synthesis of all generated planar hybrid manipulators. The overall scheme
of generation and selection of basic planar hybrid manipulators has been applied to
the realistic applications of arm-rehabilitation and sit-to-stand assistive mechanism
synthesis. |
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