Design of an Anthropomorphic, Compliant, and Lightweight Dual Arm for Aerial Manipulation

This paper presents an anthropomorphic, compliant and lightweight dual arm manipulator designed and developed for aerial manipulation applications with multi-rotor platforms. Each arm provides four degrees of freedom in a human-like kinematic configuration for end effector positioning: shoulder pitch, roll and yaw, and elbow pitch. The dual arm, weighting 1.3 kg in total, employs smart servo actuators and a customized and carefully designed aluminum frame structure manufactured by laser cut. The proposed design reduces the manufacturing cost as no computer numerical control machined part is used. Mechanical joint compliance is provided in all the joints, introducing a compact spring-lever transmission mechanism between the servo shaft and the links, integrating a potentiometer for measuring the deflection of the joints. The servo actuators are partially or fully isolated against impacts and overloads thanks to the ange bearings attached to the frame structure that support the rotation of the links and the deflection of the joints. This simple mechanism increases the robustness of the arms and safety in the physical interactions between the aerial robot and the environment. The developed manipulator has been validated through different experiments in fixed base test-bench and in outdoor flight tests.Unión Europea H2020-ICT-2014- 644271Ministerio de Economía y Competitividad DPI2015-71524-RMinisterio de Economía y Competitividad DPI2017-89790-

Telenursing RoboPuppet

The goal of this project is to improve the TRINA nursing robots ability to perform common medical tasks by designing an improved input device. The selected solution was to create a RoboPuppet, a DH parameter scale model of Baxters arms with angle sensors. A RoboPuppet allows for direct manipulation of Baxters joint space with one-to-one correspondence. Actuators were integrated to provide the opportunity for gravity compensation and haptic feedback. The puppet was successful in manipulating Baxters arms smoothly and precisely

Telenursing RoboPuppet

The goal of this project is to improve the TRINA nursing robots ability to perform common medical tasks by designing an improved input device. The selected solution was to create a RoboPuppet, a DH parameter scale model of Baxters arms with angle sensors. A RoboPuppet allows for direct manipulation of Baxters joint space with one-to-one correspondence. Actuators were integrated to provide the opportunity for gravity compensation and haptic feedback. The puppet was successful in manipulating Baxters arms smoothly and precisely

Scalability study for robotic hand platform

The goal of this thesis project was to determine the lower limit of scale for the RIT robotic grasping hand. This was accomplished using a combination of computer simulation and experimental studies. A force analysis was conducted to determine the size of air muscles required to achieve appropriate contact forces at a smaller scale. Input variables, such as the actuation force and tendon return force, were determined experimentally. A dynamic computer model of the hand system was then created using Recurdyn. This was used to predict the contact (grasping) force of the fingers at full-scale, half-scale, and quarter-scale. Correlation between the computer model and physical testing was achieved for both a life-size and half-scale finger assembly. To further demonstrate the scalability of the hand design, both half and quarter-scale robotic hand rapid prototype assemblies were built using 3D printing techniques. This thesis work identified the point where further miniaturization would require a change in the manufacturing process to micro-fabrication. Several techniques were compared as potential methods for making a production intent quarter-scale robotic hand. Investment casting, Swiss machining, and Selective Laser Sintering were the manufacturing techniques considered. A quarter-scale robotic hand tested the limits of each technology. Below this scale, micro-machining would be required. The break point for the current actuation method, air muscles, was also explored. Below the quarter-scale, an alternative actuation method would also be required. Electroactive Polymers were discussed as an option for the micro-scale. In summary, a dynamic model of the RIT robotic grasping hand was created and validated as scalable at full and half-scales. The model was then used to predict finger contact forces at the quarter-scale. The quarter-scale was identified as the break point in terms of the current RIT robotic grasping hand based on both manufacturing and actuation. A novel, prototype quarter-scale robotic hand assembly was successfully built by an additive manufacturing process, a high resolution 3D printer. However, further miniaturization would require alternate manufacturing techniques and actuation mechanisms

Aeacus: The Design and Realization of an Ant-Like Robotic Platform

A large volume of recyclable material is inescapably placed in landfills, despite modern recycling efforts. In order to create an effective way of recovering such material, we have designed and manufactured an ant-like robot with the potential to do so. The robot is equipped with the capacity to navigate through the uneven terrain of a trash heap with the ability to lift objects greater than its own weight. The robot is also designed with the intent of becoming part of a swarm to more effectively work over a large area, mimicking an ant colony

DEPUSH HexCrawler Improvement Project

DEPUSH Technologies purchased the rights to an older six-legged walking robot design and sought help from WPI and HUST students to improve its functionality to better meet the needs of the secondary education market in mainland China. To accomplish this goal, both the mechanical walking system and control system were improved. The mechanical structure was redesigned for three degree of freedom legs and a more robust chassis, while an entirely new control system was utilized to implement full inverse body and walking kinematics. The result was a cutting-edge hexapod, the HexCrawler 2.0, a versatile platform with potential applications in a variety of robotics-related projects and solid foundation for future research on high-level control

Design, modelling, and control of an ambidextrous robot arm

This thesis was submitted for the award of Doctor of Philosophy and was awarded by Brunel University LondonThis thesis presents the novel design of an ambidextrous robot arm that offers double range of motion as compared to dexterous arms. The proposed arm is unique in terms of design (ambidextrous feature), actuation (use of two different actuators simultaneously: Pneumatic Artificial Muscle (PAM) & Electric Motor)) and control (combined use of Proportional Integral Derivative (PID) with Neural Network (NN) for the hand and modified Multiple Adaptive Neuro-fuzzy Inference System (MANFIS) controller for the arm). The primary challenge of the project was to achieve ambidextrous behavior of the arm. Thus, a feasibility analysis was carried out to evaluate possible mechanical designs. The secondary aim was to deal with control issues associated with the ambidextrous design. Due to the ambidextrous nature of the design, the stability of such a device becomes a challenging task. Conventional controllers and artificial intelligence-based controllers were explored to find the most suitable one. Performances of all these controllers have been compared through experiments, and combined use of PID with NN was found to be the most accurate controller to drive the ambidextrous robot hand. In terms of ambidextrous robot arm control, a solution based on forward kinematic and inverse kinematic approach is presented, and results are verified using the derived equation in MATLAB. Since solving inverse kinematics analytically is difficult, Adaptive Neuro-Fuzzy Inference system (ANFIS) is developed using ANFIS MATLAB toolbox. When generic ANFIS failed to produce satisfactory results, modified MANFIS is proposed. The efficiency of the ambidextrous arm has been tested by comparing its performance with a conventional robot arm. The results obtained from experiments proved the efficiency of the ambidextrous arm when compared with a conventional arm in terms of power consumption and stability

The design and analysis of a novel 5 degree of freedom parallel kinematic manipulator.

Masters Degree. University of KwaZulu-Natal, Durban.Abstract available in PDF

DEPUSH HexCrawler: Mechanical and Control System Improvement

The DEPUSH HexCrawler robot has a dated control system and walking mechanism making it unstable and clumsy. DEPUSH asked our team to update the HexCrawler in conjunction with HUST students from Wuhan, China. The team redesigned the robot\u27s chassis and legs to increase mobility and stability, and implemented a powerful control system capable of precisely manipulating the robot\u27s limbs. The resulting product is a 6 Degree-of-Freedom hexapod and accompanying computer interface with applications in a variety of robotics research areas