2,709 research outputs found

    Exoskeleton master controller with force-reflecting telepresence

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    A thorough understanding of the requirements for successful master-slave robotic systems is becoming increasingly desirable. Such systems can aid in the accomplishment of tasks that are hazardous or inaccessible to humans. Although a history of use has proven master-slave systems to be viable, system requirements and the impact of specifications on the human factors side of system performance are not well known. In support of the next phase of teleoperation research being conducted at the Armstrong Research Laboratory, a force-reflecting, seven degree of freedom exoskeleton for master-slave teleoperation has been concepted, and is presently being developed. The exoskeleton has a unique kinematic structure that complements the structure of the human arm. It provides a natural means for teleoperating a dexterous, possibly redundant manipulator. It allows ease of use without operator fatigue and faithfully follows human arm and wrist motions. Reflected forces and moments are remotely transmitted to the operator hand grip using a cable transmission scheme. This paper presents the exoskeleton concept and development results to date. Conceptual design, hardware, algorithms, computer architecture, and software are covered

    Robot Manipulators

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    Robot manipulators are developing more in the direction of industrial robots than of human workers. Recently, the applications of robot manipulators are spreading their focus, for example Da Vinci as a medical robot, ASIMO as a humanoid robot and so on. There are many research topics within the field of robot manipulators, e.g. motion planning, cooperation with a human, and fusion with external sensors like vision, haptic and force, etc. Moreover, these include both technical problems in the industry and theoretical problems in the academic fields. This book is a collection of papers presenting the latest research issues from around the world

    Modeling, Control and Estimation of Reconfigurable Cable Driven Parallel Robots

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    The motivation for this thesis was to develop a cable-driven parallel robot (CDPR) as part of a two-part robotic device for concrete 3D printing. This research addresses specific research questions in this domain, chiefly, to present advantages offered by the addition of kinematic redundancies to CDPRs. Due to the natural actuation redundancy present in a fully constrained CDPR, the addition of internal mobility offers complex challenges in modeling and control that are not often encountered in literature. This work presents a systematic analysis of modeling such kinematic redundancies through the application of reciprocal screw theory (RST) and Lie algebra while further introducing specific challenges and drawbacks presented by cable driven actuators. It further re-contextualizes well-known performance indices such as manipulability, wrench closure quality, and the available wrench set for application with reconfigurable CDPRs. The existence of both internal redundancy and static redundancy in the joint space offers a large subspace of valid solutions that can be condensed through the selection of appropriate objective priorities, constraints or cost functions. Traditional approaches to such redundancy resolution necessitate computationally expensive numerical optimization. The control of both kinematic and actuation redundancies requires cascaded control frameworks that cannot easily be applied towards real-time control. The selected cost functions for numerical optimization of rCDPRs can be globally (and sometimes locally) non-convex. In this work we present two applied examples of redundancy resolution control that are unique to rCDPRs. In the first example, we maximize the directional wrench ability at the end-effector while minimizing the joint torque requirement by utilizing the fitness of the available wrench set as a constraint over wrench feasibility. The second example focuses on directional stiffness maximization at the end-effector through a variable stiffness module (VSM) that partially decouples the tension and stiffness. The VSM introduces an additional degrees of freedom to the system in order to manipulate both reconfigurability and cable stiffness independently. The controllers in the above examples were designed with kinematic models, but most CDPRs are highly dynamic systems which can require challenging feedback control frameworks. An approach to real-time dynamic control was implemented in this thesis by incorporating a learning-based frameworks through deep reinforcement learning. Three approaches to rCDPR training were attempted utilizing model-free TD3 networks. Robustness and safety are critical features for robot development. One of the main causes of robot failure in CDPRs is due to cable breakage. This not only causes dangerous dynamic oscillations in the workspace, but also leads to total robot failure if the controllability (due to lack of cables) is lost. Fortunately, rCDPRs can be utilized towards failure tolerant control for task recovery. The kinematically redundant joints can be utilized to help recover the lost degrees of freedom due to cable failure. This work applies a Multi-Model Adaptive Estimation (MMAE) framework to enable online and automatic objective reprioritization and actuator retasking. The likelihood of cable failure(s) from the estimator informs the mixing of the control inputs from a bank of feedforward controllers. In traditional rigid body robots, safety procedures generally involve a standard emergency stop procedure such as actuator locking. Due to the flexibility of cable links, the dynamic oscillations of the end-effector due to cable failure must be actively dampened. This work incorporates a Linear Quadratic Regulator (LQR) based feedback stabilizer into the failure tolerant control framework that works to stabilize the non-linear system and dampen out these oscillations. This research contributes to a growing, but hitherto niche body of work in reconfigurable cable driven parallel manipulators. Some outcomes of the multiple engineering design, control and estimation challenges addressed in this research warrant further exploration and study that are beyond the scope of this thesis. This thesis concludes with a thorough discussion of the advantages and limitations of the presented work and avenues for further research that may be of interest to continuing scholars in the community

    Realization of a demonstrator slave for robotic minimally invasive surgery

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    Robots for Minimally Invasive Surgery (MIS) can improve the surgeon’s work conditions with respect to conventional MIS and to enable MIS with more complex procedures. This requires to provide the surgeon with tactile feedback to feel forces executed on e.g. tissue and sutures, which is partially lost in conventional MIS. Additionally use of a robot should improve the approach possibilities of a target organ by means of instrument degrees of freedom (DoFs) and of the entry points with a compact set-up. These requirements add to the requirements set by the most common commercially available system, the da Vinci which are: (i) dexterity, (ii) natural hand-eye coordination, (iii) a comfortable body posture, (iv) intuitive utilization, and (v) a stereoscopic ’3D’ view of the operation site. The purpose of Sofie (Surgeon’s operating force-feedback interface Eindhoven) is to evaluate the possible benefit of force-feedback and the approach of both patient and target organ. Sofie integrates master, slave, electronic hardware and control. This thesis focusses on the design and realization of a technology demonstrator of the Slave. To provide good accuracy and valuable force-feedback, good dynamic behavior and limited hysteresis are required. To this end the Slave includes (i) a relatively short force-path between its instrument-tips and between tip and patient, and (ii) a passive instrument-support by means of a remote kinematically fixed point of rotation. The incision tissue does not support the instrument. The Slave is connected directly to the table. It provides a 20 DoF highly adaptable stiff frame (pre-surgical set-up) with a short force-path between the instrumenttips and between instrument-tip and patient. During surgery this frame supports three 4 DoF manipulators, two for exchangeable 4 DoF instruments and one for an endoscope. The pre-surgical set-up of the Slave consists of a 5 DoF platform-adjustment with a platform. This platform can hold three 5 DoF manipulator-adjustments in line-up. The set-up is compact to avoid interference with the team, entirely mechanical and allows fast manual adjustment and fixation of the joints. It provides a stiff frame during surgery. A weight-compensation mechanism for the platformadjustment has been proposed. Measurements indicate all natural frequencies are above 25 Hz. The manipulator moves the instrument in 4 DoFs (??, , ?? and Z). Each manipulator passively supports its instrument with a parallelogram mechanism, providing a kinematically fixed point of rotation. Two manipulators have been designed in consecutive order. The first manipulator drives with a worm-wormwheel, the second design uses a ball-screw drive. This ball-screw drive reduces friction, which is preferred for next generations of the manipulator, since the worm-wormwheel drive shows a relatively low coherence at low frequencies. The compact ??Zmanipulator moves the instrument in ?? by rotating a drum. Friction wheels in the drum provide Z. Eventually, the drum will be removable from the manipulator for sterilization. This layout of the manipulator results in a small motion-envelope and least obstructs the team at the table. Force sensors measuring forces executed with the instrument, are integrated in the manipulator instead of at the instrument tip, to avoid all risks of electrical signals being introduced into the patient. Measurements indicate the separate sensors function properly. Integrated in the manipulator the sensors provide a good indication of the force but do suffer from some hysteresis which might be caused by moving wires. The instrument as realized consists of a drive-box, an instrument-tube and a 4 DoF tip. It provides the surgeon with three DoFs additional to the gripper of conventional MIS instruments. These DoFs include two lateral rotations (pitch and pivot) to improve the approach possibilities and the roll DoF will contribute in stitching. Pitch and roll are driven by means of bevelgears, driven with concentric tubes. Cables drive the pivot and close DoFs of the gripper. The transmissions are backdriveable for safety. Theoretical torques that can be achieved with this instrument approximate the requirements closely. Further research needs to reveal the torques achieved in practice and whether the requirements obtained from literature actually are required for these 4 DoF instruments. Force-sensors are proposed and can be integrated. Sofie currently consists of a master prototype with two 5 DoF haptic interfaces, the Slave and an electronic hardware cabinet. The surgeon uses the haptic interfaces of the Master to manipulate the manipulators and instruments of the Slave, while the actuated DoFs of the Master provide the surgeon with force-feedback. This project resulted in a demonstrator of the slave with force sensors incorporated, compact for easy approach of the patient and additional DoFs to increase approach possibilities of the target organ. This slave and master provide a good starting point to implement haptic controllers. These additional features may ultimately benefit both surgeon and patient

    Design and realization of a master-slave system for reconstructive microsurgery

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    Robot Assisted Shoulder Rehabilitation: Biomechanical Modelling, Design and Performance Evaluation

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    The upper limb rehabilitation robots have made it possible to improve the motor recovery in stroke survivors while reducing the burden on physical therapists. Compared to manual arm training, robot-supported training can be more intensive, of longer duration, repetitive and task-oriented. To be aligned with the most biomechanically complex joint of human body, the shoulder, specific considerations have to be made in the design of robotic shoulder exoskeletons. It is important to assist all shoulder degrees-of-freedom (DOFs) when implementing robotic exoskeletons for rehabilitation purposes to increase the range of motion (ROM) and avoid any joint axes misalignments between the robot and human’s shoulder that cause undesirable interaction forces and discomfort to the user. The main objective of this work is to design a safe and a robotic exoskeleton for shoulder rehabilitation with physiologically correct movements, lightweight modules, self-alignment characteristics and large workspace. To achieve this goal a comprehensive review of the existing shoulder rehabilitation exoskeletons is conducted first to outline their main advantages and disadvantages, drawbacks and limitations. The research has then focused on biomechanics of the human shoulder which is studied in detail using robotic analysis techniques, i.e. the human shoulder is modelled as a mechanism. The coupled constrained structure of the robotic exoskeleton connected to a human shoulder is considered as a hybrid human-robot mechanism to solve the problem of joint axes misalignments. Finally, a real-scale prototype of the robotic shoulder rehabilitation exoskeleton was built to test its operation and its ability for shoulder rehabilitation

    Development of an actively compliant underwater manipulator

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    Submitted in partial fulfillment of the requirements for the degree of Master of Science at the Massachusetts Institute of Technology and the Woods Hole Oceanographic Institution May 1988This thesis describes the design, construction, and evaluation of an actively compliant underwater manipulator for installation on the underwater remotely operated vehicle (ROV) JASON. The goal of this work has been to produce a high fidelity force-controllable manipulator exhibiting no backlash, low stiction/friction, high backdriveability, wide dynamic range, and possessing a large work envelope. By reducing the inherent dynamic nonlineari ties, a wide range of joint compliances can realistically be achieved. This feature is important when implementing various force control schemes, particularly impedance control. In addition, a mechanically "clean" transmission reduces the need for sensors and allows the user to rely on integral motor sensors to provide torque, position, and velocity information. A three axis manipulator rated to full ocean depth was built. Each of the revolute joints is driven by a DC brushless sensorimotor working through a multi-stage cable/pulley transmission. The manipulator mechanism and wiring is fully enclosed by cast aluminum housings filled with mineral oil. Mineral oil functions to pressure compensate and lubricate the system. Exterior surfaces of the manipulator are smooth and continuous, and were designed to act as work surfaces. Joints one and two have a 240° range of motion, while joint three can rotate 380°. The manipulator transmissions are modeled and predictions of manipulator stiffness, dynamic range, payload capacity, and hysteresis are compared with the results of tests conducted on the actual system. Operation of the cable/pulley transmissions are evaluated and suggestions for improvements are given

    Towards Closed-loop, Robot Assisted Percutaneous Interventions under MRI Guidance

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    Image guided therapy procedures under MRI guidance has been a focused research area over past decade. Also, over the last decade, various MRI guided robotic devices have been developed and used clinically for percutaneous interventions, such as prostate biopsy, brachytherapy, and tissue ablation. Though MRI provides better soft tissue contrast compared to Computed Tomography and Ultrasound, it poses various challenges like constrained space, less ergonomic patient access and limited material choices due to its high magnetic field. Even after, advancements in MRI compatible actuation methods and robotic devices using them, most MRI guided interventions are still open-loop in nature and relies on preoperative or intraoperative images. In this thesis, an intraoperative MRI guided robotic system for prostate biopsy comprising of an MRI compatible 4-DOF robotic manipulator, robot controller and control application with Clinical User Interface (CUI) and surgical planning applications (3DSlicer and RadVision) is presented. This system utilizes intraoperative images acquired after each full or partial needle insertion for needle tip localization. Presented system was approved by Institutional Review Board at Brigham and Women\u27s Hospital(BWH) and has been used in 30 patient trials. Successful translation of such a system utilizing intraoperative MR images motivated towards the development of a system architecture for close-loop, real-time MRI guided percutaneous interventions. Robot assisted, close-loop intervention could help in accurate positioning and localization of the therapy delivery instrument, improve physician and patient comfort and allow real-time therapy monitoring. Also, utilizing real-time MR images could allow correction of surgical instrument trajectory and controlled therapy delivery. Two of the applications validating the presented architecture; closed-loop needle steering and MRI guided brain tumor ablation are demonstrated under real-time MRI guidance
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