21 research outputs found
Dynamics and Control of Whole Arm Grasps
In this paper we consider the dynamics and control of whole arm grasping systems. We develop a control scheme that employs a minimal set of inputs to control the trajectory of the system while using the surplus inputs to control the interaction forces in order to maintain the unilateral constraints at both rolling and sliding contacts. Since the number of surplus inputs is less than the number of output force variables, we propose a controller that controls the critical contact force components. We emphasize the dynamic models and algorithms for computing contact forces, which are crucial to the development of the control algorithms. Finally, we show how compliant contact models and a previously developed integrated simulation approach [14] are used to overcome the difficulties with uniqueness and existence of solutions. A planar whole arm manipulation system is used as an example to illustrate the basic ideas
Proceedings of the NASA Conference on Space Telerobotics, volume 3
The theme of the Conference was man-machine collaboration in space. The Conference provided a forum for researchers and engineers to exchange ideas on the research and development required for application of telerobotics technology to the space systems planned for the 1990s and beyond. The Conference: (1) provided a view of current NASA telerobotic research and development; (2) stimulated technical exchange on man-machine systems, manipulator control, machine sensing, machine intelligence, concurrent computation, and system architectures; and (3) identified important unsolved problems of current interest which can be dealt with by future research
MULTI-DIGIT HUMAN PREHENSION
The current dissertation addresses the central nervous system (CNS) strategies to solve kinetic redundancy in multi-digit static prehension under different geometries of hand-held objects and systematically varied mechanical constraints such as translation and rotation of the hand-held object. A series of experiments conducted for this dissertation tested the following hypotheses suggested in the current literatures for multi-digit human static prehension: Hierarchical organization hypothesis, principle of superposition hypothesis, proximity hypothesis, and mechanical advantage hypothesis. (1) Forces and moments produced by fingers during circular object prehension were grouped into two independent subsets: one subset related to grasping stability control and the other associated with rotational equilibrium control. This result supports the principle of superposition hypothesis. Individual fingers acted synergistically to compensate each other's errors. This result confirms the hierarchical organization hypothesis in circular object prehension. (2) During fixed object prehension of a rectangular object, the closer the non-task fingers positioned to the task finger, the greater the forces produced by the non-task fingers. However, during free object prehension, the non-task fingers with longer moment arms produced greater forces. The former and latter results support the proximity hypothesis and the mechanical advantage hypothesis, respectively. (3) The grasping stability control and rotational equilibrium control were decoupled during fixed object prehension as well as free object prehension. This result supports the principle of superposition hypothesis regardless of the mechanical constraints provided for these two prehension types. (4) During torque production, the fingers with longer moment arms produced greater forces when the fingers acted as agonists for the torque production. Therefore, the mechanical advantage hypothesis was supported for agonist fingers. (5) Coupling of thumb normal force and virtual finger normal force was not necessitated when horizontal translation of hand-held object was mechanically fixed. However, the coupling of two normal forces was always observed regardless of given translational constraints, and these two normal forces were independent to other mechanical variables such as tangential forces and moments. This result supports the principle of superposition hypothesis in static prehension under varied combinations of translational constraints
Proceedings of the NASA Conference on Space Telerobotics, volume 1
The theme of the Conference was man-machine collaboration in space. Topics addressed include: redundant manipulators; man-machine systems; telerobot architecture; remote sensing and planning; navigation; neural networks; fundamental AI research; and reasoning under uncertainty
Reflex: A Closed-Loop Tactile Feedback System for Use in Upper Limb Prosthesis Grip Control
Tactile sensing provides valuable insight to the environment in which we interact
with. Upper limb amputees lack the sensations that generates the necessary information
to stably grasp the wide variety of objects we interact with on a daily basis.
Utilizing tactile sensing to provide feedback to a prosthetic hand provides a mechanism
for replacing the grip control functionality of the mechanoreceptors found in
human skin. Novel customizable, low cost tactile sensors for monitoring the dynamics
of an object grasped by a prosthetic hand are developed and presented as part of
this thesis. The response of sensors placed on a prosthetic hand provides information
regarding the state of a grasped object, particularly contact and slip.
The sensors are made up of various textile materials, including stretchable interfacing layers and conductive traces. Essentially a force sensitive resistor, each sensor is shaped into stretchable cu ff that can be placed around the finger of a prosthetic hand. An outer rubber layer on the sensor provides compliance, which is found to enhance grasping performance with a prosthesis.
Two control algorithms were developed as part of the closed-loop tactile feedback system, called Reflex, to enhance grasping functionality with a prosthesis. A Contact Detection strategy uses force information to effectively reduce the user's electromyography (EMG) signals, which are used to control the prosthesis. Essentially, the goal of this strategy is to help a user grab fragile objects without breaking them. A second strategy, Slip Prevention, uses the derivative of a force signal to detect slip of a grasped object. Instances of slip trigger electrical pulses sent from the prosthesis control unit to close the hand in an effort to prevent additional slip.
The Reflex system, comprised of two control strategies along with flexible textile based force sensors on the fingers of a prosthesis, was shown to improve the grasping functionality of a prosthesis under normal use conditions. Able body participants were used to test the system. Results show the sensors' ability to greatly enhance grasping fragile objects while also helping prevent object slip. The compliant nature of the sensors enables users to more confidently pick up and move small,fragile objects, such as foam peanuts and crackers. Without sensors and tactile feedback, users had a higher likelihood of breaking objects while grabbing them. The addition of sensors reduced this failure rate, and the failure rate was reduced even further with the implementation of control algorithms running in real-time. The slip prevention strategy was also shown to help reduce the amount of object movement after a grasp is initiated, although the most benefit comes from the compliant nature of the sensors.
Reflex is the first closed-loop tactile feedback system with multiple control strategies that can be used on a prosthetic hand to enhance grasping functionality. The system allows one to switch between Contact Detection or Slip Prevention control strategies, giving the user the ability to use each control as needed. Feedback from the textile sensors directly to the prosthesis control unit provides valuable information regarding grasping forces. This research aims to help improve prosthetic technology so that one day amputees will feel as if their device is a natural extension of their body
Proceedings of the NASA Conference on Space Telerobotics, volume 5
Papers presented at the NASA Conference on Space Telerobotics are compiled. The theme of the conference was man-machine collaboration in space. The conference provided a forum for researchers and engineers to exchange ideas on the research and development required for the application of telerobotics technology to the space systems planned for the 1990's and beyond. Volume 5 contains papers related to the following subject areas: robot arm modeling and control, special topics in telerobotics, telerobotic space operations, manipulator control, flight experiment concepts, manipulator coordination, issues in artificial intelligence systems, and research activities at the Johnson Space Center
NASA space station automation: AI-based technology review
Research and Development projects in automation for the Space Station are discussed. Artificial Intelligence (AI) based automation technologies are planned to enhance crew safety through reduced need for EVA, increase crew productivity through the reduction of routine operations, increase space station autonomy, and augment space station capability through the use of teleoperation and robotics. AI technology will also be developed for the servicing of satellites at the Space Station, system monitoring and diagnosis, space manufacturing, and the assembly of large space structures