Your search keyword '"Cho, Kyu-Jin"' showing total 12 results

1. Perching and Grasping Using a Passive Dynamic Bioinspired Gripper

Author

Firouzeh, Amir, Lee, Jongeun, Yang, Hyunsoo, Lee, Dongjun, and Cho, Kyu-Jin

Abstract

The ability to grasp objects broadens the application range of unmanned aerial vehicles (UAVs) by allowing interactions with the environment. The difficulty in performing a midair grasp is the high probability of impact between the UAV's foot and the target. For a successful grasp, the foot must smoothly absorb the energy of impact and simultaneously engage with the target in a short period of time. We present a bioinspired passive dynamic foot in which the claws are actuated solely by the impact energy. Our gripper simultaneously resolves the issue of smooth absorption of the impact energy and fast closure of the claws by linking the motion of an ankle linkage and the claws through soft tendons. We study the dynamics of impact and use the stiffness of the tendon as our design/control parameter to adjust the mechanics of the gripper for smooth recycling of the impact energy. Our gripper closes within 45 ms after initial contact with the impacting object without requiring any controller or actuation energy. An electroadhesive locking mechanism attached to the tendon locks the claws within 20 ms after reaching closed configuration. We demonstrated the effectiveness of our gripper by integrating it in an UAV and performing a variety of passive dynamic perching and grasping tasks.

Published

2024

2. Perching and grasping using a passive dynamic bioinspired gripper

Author

Firouzeh, Amir, primary, Lee, Jongeun, additional, Yang, Hyunsoo, additional, Lee, Dongjun, additional, and Cho, Kyu-Jin, additional

Published

2023

3. Exo-Abs: A Wearable Robotic System Inspired by Human Abdominal Muscles for Noninvasive and Effort-Synchronized Respiratory Assistance

Author

Lee, Sang-Yoep, primary, Hahn, Jin-Oh, additional, Beom, Jaewon, additional, Park, Ji-Hong, additional, Cho, Han Eol, additional, Kang, Seong-Woong, additional, and Cho, Kyu-Jin, additional

Published

2022

4. Morphing Origami Block for Lightweight Reconfigurable System

Author

Kim, Sa-Reum, primary, Lee, Dae-Young, additional, Ahn, Sang-Joon, additional, Koh, Je-Sung, additional, and Cho, Kyu-Jin, additional

Published

2021

5. Architecture design of a multiaxis cellular actuator array using segmented binary control of shape memory alloy

Author

Cho, Kyu-Jin and Asada, H. Harry

Subjects

Actuators -- Analysis, Robots -- Control systems, Robots -- Analysis

Abstract

A new approach to artificial muscle actuator design is presented, and is implemented using shape memory alloys (SMA). An array of SMA actuators is segmented into many independently controlled, spatially discrete volumes, each contributing a small displacement to create a large motion. The segmented cellular architecture of SMA wires is extended to a multiaxis actuator array by arranging the segments in a two-dimensional (2-D) array. The multiaxis control is streamlined and coordinated using a 2-D segmentation method in order to activate multiple links of a robot mechanism in a coordinated manner. The basic principle of segmented binary control (SBC) is first presented, followed by multiaxis segmentation theory and a design procedure. The method is applied to a five-fingered robotic hand capable of taking a variety of postures. A 10-axis SMA actuator array is built, and SBC is implemented using Peltier-effect thermoelectric devices for selective local heating and cooling. Experiments demonstrate the feasibility and effectiveness of the new method. Index Terms--Actuators, cellular architecture, multiaxis coordination, segmented binary control (SBC).

Published

2006

6. Continuously Variable Stiffness Mechanism Using Nonuniform Patterns on Coaxial Tubes for Continuum Microsurgical Robot

Author

Kim, Jongwoo, primary, Choi, Woo-Young, additional, Kang, Sungchul, additional, Kim, Chunwoo, additional, and Cho, Kyu-Jin, additional

Published

2019

7. Anisotropic Patterning to Reduce Instability of Concentric-Tube Robots

Author

Lee, Dae-Young, primary, Kim, Jongwoo, additional, Kim, Ji-Suk, additional, Baek, Changyeob, additional, Noh, Gunwoo, additional, Kim, Do-Nyun, additional, Kim, Keri, additional, Kang, Sungchul, additional, and Cho, Kyu-Jin, additional

Published

2015

8. Design of an Optically Controlled MR-Compatible Active Needle

Author

Ryu, Seok Chang, primary, Quek, Zhan Fan, additional, Koh, Je-Sung, additional, Renaud, Pierre, additional, Black, Richard J., additional, Moslehi, Behzad, additional, Daniel, Bruce L., additional, Cho, Kyu-Jin, additional, and Cutkosky, Mark R., additional

Published

2015

9. Wheel Transformer: A Wheel-Leg Hybrid Robot With Passive Transformable Wheels

Author

Kim, Yoo-Seok, primary, Jung, Gwang-Pil, additional, Kim, Haan, additional, Cho, Kyu-Jin, additional, and Chu, Chong-Nam, additional

Published

2014

10. Underactuated Adaptive Gripper Using Flexural Buckling

Author

Jung, Gwang-Pil, primary, Koh, Je-Sung, additional, and Cho, Kyu-Jin, additional

Published

2013

11. Kinematic Condition for Maximizing the Thrust of a Robotic Fish Using a Compliant Caudal Fin

Author

Park, Yong-Jai, primary, Jeong, Useok, additional, Lee, Jeongsu, additional, Kwon, Seok-Ryung, additional, Kim, Ho-Young, additional, and Cho, Kyu-Jin, additional

Published

2012

12. Flea-Inspired Catapult Mechanism for Miniature Jumping Robots.

Author

Noh, Minkyun, Kim, Seung-Won, An, Sungmin, Koh, Je-Sung, and Cho, Kyu-Jin

Subjects

ROBOT motion, CATAPULT, ACTUATORS, SHAPE memory alloys, BIOMIMETIC chemicals, MICROSTRUCTURE, DYNAMIC models

Abstract

Fleas can jump more than 200 times their body length. They do so by employing a unique catapult mechanism: storing a large amount of elastic energy and releasing it quickly by torque reversal triggering. This paper presents a flea-inspired catapult mechanism for miniature jumping robots. A robotic design was created to realize the mechanism for the biological catapult with shape memory alloy (SMA) spring actuators and a smart composite microstructure. SMA spring actuators replace conventional actuators, transmissions, and the elastic element to reduce the size. The body uses a four-bar mechanism that simulates a flea's leg kinematics with reduced degrees of freedom. Dynamic modeling was derived, and theoretical jumping was simulated to optimize the leg design for increased takeoff speed. A robotic prototype was fabricated with 1.1-g weight and 2-cm body size that can jump a distance of up to 30 times its body size. [ABSTRACT FROM AUTHOR]

Published

2012