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In engineering, a mechanical singularity is a position or configuration of a mechanism or a machine where the subsequent behaviour cannot be predicted, or the forces or other physical quantities involved become infinite or nondeterministic.
When the underlying engineering equations of a mechanism or machine are evaluated at the singular configuration (if any exists), then those equations exhibit mathematical singularity.
Examples of mechanical singularities are gimbal lock and in static mechanical analysis, an under-constrained system.
Types of singularities
editThere are three types of singularities that can be found in mechanisms: direct-kinematics singularities, inverse-kinematics singularities, and combined singularities. These singularities occur when one or both Jacobian matrices of the mechanisms becomes singular of rank-deficient.[1] The relationship between the input and output velocities of the mechanism are defined by the following general equation:
where is the output velocities, is the input velocities, is the direct-kinematics Jacobians, and is the inverse-kinematics Jacobian.
Type-I: Inverse-kinematics singularities
editThis first kind of singularities occurs when:
Type-II: Direct-kinematics singularities
editThis second kind of singularities occurs when:
Type-III: Combined singularities
editThis kind of singularities occurs when for a particular configuration, both and become singular simultaneously.
References
edit- ^ "Singularity analysis of closed-loop kinematic chains - IEEE Journals & Magazine". doi:10.1109/70.56660.
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