On a Jansen leg with multiple gait patterns for reconfigurable walking platforms

Nansai, Shunsuke; Rojas, Nicolás; Elara, Mohan Rajesh; Sosa, Ricardo; Iwase, Masami

doi:10.1177/1687814015573824

Cited by 53 publications

(22 citation statements)

References 39 publications

(55 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It is important and necessary to optimize the dimension of the closed-chain mechanism [39]. Because of the dual-objective optimization, the special method of TOPSIS (Technique for Order Preference by Similarity to an Ideal Solution) was chosen for dimension optimization.…”

Section: Establishment Of Optimizationmentioning

confidence: 99%

Design and Experimental Evaluation of a Single-Actuator Continuous Hopping Robot Using the Geared Symmetric Multi-Bar Mechanism

et al. 2018

View full text Add to dashboard Cite

This paper proposes the design and performance evaluation of a miniaturized continuous hopping robot RHop for unstructured terrain. The hopping mechanism of RHop is realized by an optimized geared symmetric closed-chain multi-bar mechanism that is transformed from the eight-bar mechanism, and the actuator of RHop is realized by a servo motor and the clockwork spring, thereby enabling RHop to realize continuous hopping while its motor rotates continuously only in one direction. Comparative simulations and experiments are conducted for RHop. The results show that RHop can realize better continuous hopping performance, as well as the improvement of energy conversion efficiency from 70.98% to 76.29% when the clockwork spring is applied in the actuator. In addition, comparisons with some state-of-the-art hopping robots are conducted, and the normalized results show that RHop has a better energy storage speed.

show abstract

Section: Establishment Of Optimizationmentioning

confidence: 99%

Design and Experimental Evaluation of a Single-Actuator Continuous Hopping Robot Using the Geared Symmetric Multi-Bar Mechanism

et al. 2018

View full text Add to dashboard Cite

show abstract

“…In the above mentioned scenario, the robot's ability to reconfigure itself enables rotational locomotion in addition to the conventional rectilinear motion and clockwise-counterclockwise rotation using omnidirectional wheels. Nansai et al have done consequential work on the dynamic walking gait generation using the reconfigurable Theo Jansen mechanism that enables the robot to traverse multiple terrains by varying the link length associated with it [11,12]. In addition to the adoption of a reconfigurable mechanism in the mechanical design and control, there are also attempts reported to integrate the bio-inspired principles in reconfigurability.…”

Section: Introductionmentioning

confidence: 99%

Design and Implementation of a Shape Shifting Rolling–Crawling–Wall-Climbing Robot

et al. 2017

Self Cite

View full text Add to dashboard Cite

Abstract:Designing an urban reconnaissance robot is highly challenging work given the nature of the terrain in which these robots are required to operate. In this work, we attempt to extend the locomotion capabilities of these robots beyond what is currently feasible. The design and unique features of our bio-inspired reconfigurable robot, called Scorpio, with rolling, crawling, and wall-climbing locomotion abilities are presented in this paper. The design of the Scorpio platform is inspired by Cebrennus rechenbergi, a rare spider species that has rolling, crawling and wall-climbing locomotion attributes. This work also presents the kinematic and dynamic model of Scorpio. The mechanical design and system architecture are introduced in detail, followed by a detailed description on the locomotion modes. The conducted experiments validated the proposed approach and the ability of the Scorpio platform to synthesise crawling, rolling and wall-climbing behaviours. Future work is envisioned for using these robots as active, unattended, mobile ground sensors in urban reconnaissance missions. The accompanying video demonstrates the shape shifting locomotion capabilities of the Scorpio robot.

show abstract

“…5 As a major component sector of robot, the legged robot is one of the most versatile design strategies for robot locomotion. 6 The legged robot can be usually categorized into biped robot, quadruped robot, and hexapod robot. With only a group of point contact and a proper site as landing point, the legged robot can smoothly and effectively cross road obstacles.…”

Section: Introductionmentioning

confidence: 99%

A velocity estimation algorithm for legged robot

Wang

Liu

Zha

et al. 2017

Advances in Mechanical Engineering

View full text Add to dashboard Cite

To secure the data accuracy while reducing development cost of robot, in this article, we conducted fusion estimation of the information measured by strapdown inertial navigation system and the information solved by forward kinematics using extended Kalman filter and regarding the motion parameter error was proposed as state variable. On this basis, state equation and detecting equation can be established. In addition, this article made innovative attempt to compensate the optimal estimation of motion parameter error using feedback correction method, and finally obtained stable and accurate velocity estimation of robot. Being unrestricted by the number of robot's leg, this method is suitable for both static gait and dynamic gait, and can overcome the impact from leg slipping. As for the verification of this method, in this article, a quadruped robot was employed for motion simulation and experimental verification, and results verified the correctness and feasibility of the proposed method.

show abstract

On a Jansen leg with multiple gait patterns for reconfigurable walking platforms

Cited by 53 publications

References 39 publications

Design and Experimental Evaluation of a Single-Actuator Continuous Hopping Robot Using the Geared Symmetric Multi-Bar Mechanism

Design and Experimental Evaluation of a Single-Actuator Continuous Hopping Robot Using the Geared Symmetric Multi-Bar Mechanism

Design and Implementation of a Shape Shifting Rolling–Crawling–Wall-Climbing Robot

A velocity estimation algorithm for legged robot

Contact Info

Product

Resources

About