Global ETD Search

1	Design of an Algae Harvesting Cable Robot, Including a Novel Solution to the Forward Pose Kinematics Problem Needler, Noah J. 25 September 2013 (has links) No description available. Robotics Engineering Robots Mechanical Engineering cable robot cable algae harvest algae harvest robot
2	Aplikace lanového robota / Application of cable robot Bulenínec, Martin January 2017 (has links) The thesis deals with the changes of a cable robot to a manipulator. The mechanical changes are mostly about adding an active part to a moving platform with the ability to transfer objects and the effort to exchange the silicon cables for metal ones. The main part of the thesis is the proposed design and implementation of the algorithm for detection of a possible collision of the cable robot with an object in its working space.
3	Mathematical Modeling of Cable Sag, Kinematics, Statics, and Optimization of a Cable Robot Sridhar, Dheerendra M. January 2015 (has links) No description available. Mechanical Engineering Robotics Engineering Applied Mathematics Mechanical Engineering Robotics Cable Robot Cable Sag Tension Mathematical Modeling Optimization Kinematics Statics
4	A Cable-Actuated Robotic Lumbar Spine as the Haptic Interface for Palpatory Training of Medical Students Karadogan, Ernur January 2011 (has links) No description available. Biomechanics Mechanical Engineering Robotics Cable robot human lumbar spine Palpatory training RLS Robotic lumbar spine three-dimensional static modeling
5	Cable-Suspended Robot System with Real Time Kinematics GPS Position Correction for Algae Harvesting Pagan, Jesus Manuel January 2018 (has links) No description available. Alternative Energy Engineering Mechanical Engineering Robotics Robots Cable-Suspended Robot System Cable-Suspended Parallel Robot Cable Robot Algae Harvesting Global Positioning System GPS Real Time Kinematics RTK
6	Kinematics, Dynamics, and Controller Design for the Contour Crafting Cartesian Cable (C4) Robot Xin, Ming 08 August 2008 (has links) No description available. Civil Engineering Engineering Mechanical Engineering Kinematics Dynamics Computed-torque Control Workspace Stiffness Translational Stiffness Rotational Stiffness Cable-suspended Robot Contour Crafting Cartesian Cable Robot Cartesian motion Positive cable tensions Pesudostatics
7	Force-Feasible Workspace Analysis and Motor Mount Disturbance Compensation for Point-Mass Cable Robots Riechel, Andrew T. 12 April 2004 (has links) Cable-actuated manipulators (or 'cable robots') constitute a relatively new classification of robots which use motors, located at fixed remote locations, to manipulate an end-effector by extending or retracting cables. These manipulators possess a number of unique properties which make them proficient with tasks involving high payloads, large workspaces, and dangerous or contaminated environments. However, a number of challenges exist which have limited the mainstream emergence of cable robots. This thesis addresses two of the most important of these issues-- workspace analysis and disturbance compensation. Workspace issues are particularly important, as many large-scale applications require the end-effector to operate in regions of a particular shape, and to exert certain minimum forces throughout those regions. The 'Force-Feasible Workspace' represents the set of end-effector positions, for a given robot design, for which the robot can exert a set of required forces on its environment. This can be considered as the robot's 'usable' workspace, and an analysis of this workspace shape for point-mass cable robots is therefore presented to facilitate optimal cable robot design. Numerical simulation results are also presented to validate the analytical results, and to aid visualization of certain complex workspace shapes. Some cable robot applications may require mounting motors to moving bases (i.e. mobile robots) or other surfaces which are subject to disturbances (i.e. helicopters or crane arms). Such disturbances can propagate to the end-effector and cause undesired motion, so the rejection of motor mount disturbances is also of interest. This thesis presents a strategy for measuring these disturbances and compensating for them. General approaches and implementation issues are explored qualitatively with a simple one-degree-of-freedom prototype (including a strategy for mitigating accelerometer drift), and quantitative simulation results are presented as a proof of concept. Disaster cleanup Manipulator Workspace shape Force-Feasible Workspace Workspace derivation Nondimensional parameter Disturbance compensation Workspace analysis Unidirectional constraint Accelerometer drift Disturbance rejection Required Force-Set Attainable Force-Set Parallel robot Design Tendon-driven Wire-driven Simulation Simulink MATLAB Cable robot

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