Study of Flea Jumping Mechanism for Biomimetic Robot Design

A growing research in biomimetic legged robot design challenges today's theory path planning and motion control. For many reasons a biomimetic robot requires a heading sensor onboard for better path following and steering. We propose a use of a digital compass as low-cost sensor. However, cheap versions of that sensor are extremely sensitive to inclination that occurs due to locomotion, resulting in incorrect measurements. This paper presents a modeling procedure of a digital compass performance with respect to altered roll and pitch angles. With information from an additional accelerometer as tilt sensor that reads roll and pitch angles of the robot the model improves the compass readings making it insensitive to altered tilt. The fusion of the modeling and a compass-accelerometer setup is experimentally verified.

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Humans and humanoids

10.1093/oso/9780199674923.003.0047 ◽

2018 ◽

Author(s):

Giorgio Metta

Keyword(s):

Humanoid Robot ◽

Robot Vision ◽

Physical Space ◽

Humanoid Robots ◽

Human Robot Interaction ◽

Biologically Inspired ◽

Robot Interaction ◽

Humanoid Robotics ◽

Biomimetic Robot ◽

Compliant Actuation

This chapter outlines a number of research lines that, starting from the observation of nature, attempt to mimic human behavior in humanoid robots. Humanoid robotics is one of the most exciting proving grounds for the development of biologically inspired hardware and software—machines that try to recreate billions of years of evolution with some of the abilities and characteristics of living beings. Humanoids could be especially useful for their ability to “live” in human-populated environments, occupying the same physical space as people and using tools that have been designed for people. Natural human–robot interaction is also an important facet of humanoid research. Finally, learning and adapting from experience, the hallmark of human intelligence, may require some approximation to the human body in order to attain similar capacities to humans. This chapter focuses particularly on compliant actuation, soft robotics, biomimetic robot vision, robot touch, and brain-inspired motor control in the context of the iCub humanoid robot.

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Economical Mobile Robot Design Prototype and Simulation for Industry 4.0 Applications

2020 IEEE 3rd International Conference and Workshop in Óbuda on Electrical and Power Engineering (CANDO-EPE) ◽

10.1109/cando-epe51100.2020.9337786 ◽

2020 ◽

Author(s):

Csaba Hajdu ◽

Janos Hollosi ◽

Rudolf Krecht ◽

Aron Ballagi ◽

Claudiu Radu Pozna

Keyword(s):

Mobile Robot ◽

Industry 4.0 ◽

Robot Design

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Warning: This Robot is Not What it Seems! Exploring Expectation Discrepancy Resulting from Robot Design

Companion of the 2020 ACM/IEEE International Conference on Human-Robot Interaction ◽

10.1145/3371382.3378280 ◽

2020 ◽

Author(s):

Lena T. Schramm ◽

Derek Dufault ◽

James E. Young

Keyword(s):

Robot Design

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The Catenary Robot: Design and Control of a Cable Propelled by Two Quadrotors

IEEE Robotics and Automation Letters ◽

10.1109/lra.2021.3062603 ◽

2021 ◽

pp. 1-1

Author(s):

Diego S.Dantonio ◽

Gustavo A. Cardona ◽

David Saldana

Keyword(s):

Robot Design ◽

And Control

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Exploring Web-Based VR for Participatory Robot Design

Companion of the 2021 ACM/IEEE International Conference on Human-Robot Interaction ◽

10.1145/3434074.3447139 ◽

2021 ◽

Author(s):

Simran Bhatia ◽

Elin A. Björling ◽

Tanya Budhiraja

Keyword(s):

Robot Design ◽

Web Based

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Mechatronic Design of ARC Humanoid Robot Open Platform: First Fully 3D Printed Kid-Sized Robot

International Journal of Humanoid Robotics ◽

10.1142/s0219843620500103 ◽

2020 ◽

Vol 17 (03) ◽

pp. 2050010

Author(s):

Saeed Saeedvand ◽

Hadi S. Aghdasi ◽

Jacky Baltes

Keyword(s):

Humanoid Robot ◽

Size Range ◽

Robot Design ◽

3D Printer ◽

Wide Angle ◽

Open Platform ◽

3D Printed ◽

Wide Angle Camera ◽

Computational Resources ◽

User Friendly

Although there are several popular and capable humanoid robot designs available in the kid-size range, they lack some important characteristics: affordability, being user-friendly, using a wide-angle camera, sufficient computational resources for advanced AI algorithms, and mechanical robustness and stability are the most important ones. Recent advances in 3D printer technology enables researchers to move from model to physical implementation relatively easy. Therefore, we introduce a novel fully 3D printed open platform humanoid robot design named ARC. In this paper, we discuss the mechanical structure and software architecture. We show the capabilities of the ARC design in a series of experimental evaluations.

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A Simple Analytical Tool for Legged Robot Design

Volume 4: 36th Mechanisms and Robotics Conference, Parts A and B ◽

10.1115/detc2012-71452 ◽

2012 ◽

Author(s):

Zhuohua Shen ◽

Justin Seipel

Keyword(s):

Analytical Solutions ◽

Inverted Pendulum ◽

Legged Locomotion ◽

Robot Design ◽

Slip Model ◽

Legged Robot ◽

Biologically Relevant ◽

Analytical Approximations ◽

Energy Conserving ◽

Spring Loaded Inverted Pendulum

Although legged locomotion is better at tackling complicated terrains compared with wheeled locomotion, legged robots are rare, in part, because of the lack of simple design tools. The dynamics governing legged locomotion are generally nonlinear and hybrid (piecewise-continuous) and so require numerical simulation for analysis and are not easily applied to robot designs. During the past decade, a few approximated analytical solutions of Spring-Loaded Inverted Pendulum (SLIP), a canonical model in legged locomotion, have been developed. However, SLIP is energy conserving and cannot predict the dynamical stability of real-world legged locomotion. To develop new analytical tools for legged robot designs, we first analytically solved SLIP in a new way. Then based on SLIP solution, we developed an analytical solution of a hip-actuated Spring-Loaded Inverted Pendulum (hip-actuated-SLIP) model, which is more biologically relevant and stable than the canonical energy conserving SLIP model. The analytical approximations offered here for SLIP and the hip actuated-SLIP solutions compare well with the numerical simulations of each. The analytical solutions presented here are simpler in form than those resulting from existing analytical approximations. The analytical solutions of SLIP and the hip actuated-SLIP can be used as tools for robot design or for generating biological hypotheses.

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Mechanism Design and Simulation of the ULTRA Spine: A Tensegrity Robot

Volume 5A: 39th Mechanisms and Robotics Conference ◽

10.1115/detc2015-47583 ◽

2015 ◽

Cited By ~ 10

Author(s):

Andrew P. Sabelhaus ◽

Hao Ji ◽

Patrick Hylton ◽

Yakshu Madaan ◽

ChanWoo Yang ◽

...

Keyword(s):

Mechanism Design ◽

Design Process ◽

Inverse Kinematics ◽

Gear Ratio ◽

Forward Kinematics ◽

Robot Design ◽

Link Structure ◽

Iterative Design ◽

Quadruped Robots ◽

Ongoing Effort

The Underactuated Lightweight Tensegrity Robotic Assistive Spine (ULTRA Spine) project is an ongoing effort to create a compliant, cable-driven, 3-degree-of-freedom, underactuated tensegrity core for quadruped robots. This work presents simulations and preliminary mechanism designs of that robot. Design goals and the iterative design process for an ULTRA Spine prototype are discussed. Inverse kinematics simulations are used to develop engineering characteristics for the robot, and forward kinematics simulations are used to verify these parameters. Then, multiple novel mechanism designs are presented that address challenges for this structure, in the context of design for prototyping and assembly. These include the spine robot’s multiple-gear-ratio actuators, spine link structure, spine link assembly locks, and the multiple-spring cable compliance system.

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