Tarantula: Design, Modeling, and Kinematic Identification of a Quadruped Wheeled Robot

Hayat, Abdullah Aamir; Elangovan, Karthikeyan; Elara, Mohan Rajesh; Teja, Mullapudi Sai

doi:10.3390/app9010094

Cited by 30 publications

(19 citation statements)

References 36 publications

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“…Note that the two subsystems are considered for the ease of kinematic and dynamic formulations with block-2 assumed to be the center block about which the two subsystems are labeled as in Figure 4b. Table 1 lists the Denavit-Hartenberg (DH) parameters notation as adapted in [23] for the two dissections of the hTetro. Table 1.…”

Section: Kinematicsmentioning

confidence: 99%

Modeling and Assessing of Self-Reconfigurable Cleaning Robot hTetro Based on Energy Consumption

et al. 2019

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The autonomous floor-cleaning self-reconfigurable robots have entered into the practical stage by establishing enhanced area coverage over the fixed morphology counterparts. Energy consumption during the self-reconfiguration, i.e., changing the shape of the robot from one form to another, becomes a primary focus in these robots that carry finite energy sources. In this paper, hTetro platform with two hinge dissections namely, Left–Left–Left (LLL) and Left–Left–Right (LLR) are modeled and assessed for the energy consumption during the reconfiguration. The geometry of the two dissections, its workspaces, and the set of inverse kinematics solutions for the seven forms are presented. The inverse dynamics using the Newton–Euler approach was adopted to calculate the wrench, i.e., forces and moments at the hinge joints, and subsequently assess the power consumed during the reconfigurations of two hinge dissections in the simulation. Extensive experiments were performed across the two assembled platforms to estimate the power consumption by logging the current data. The comparison was made with the simulation results. The results are particularly useful in the selection of reconfiguration with minimal energy consumption during the floor cleaning.

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Section: Kinematicsmentioning

confidence: 99%

Modeling and Assessing of Self-Reconfigurable Cleaning Robot hTetro Based on Energy Consumption

et al. 2019

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“…They showed a caterpillar-inspired quadruped robot whichimitatesthe prolegs of caterpillars, and a mudskipper-inspired crawling algorithm based on reinforcement learning, which improves the adaptation of locomotion. Hayat et al [35] designed a quadruped wheeled robot and showed its kinematic formulation. Jia et al [36] tackled the motion stability of quadruped robots with dynamic gait.…”

Section: Advanced Mobile Roboticsmentioning

confidence: 99%

Special Feature on Advanced Mobile Robotics

Kim

2019

Applied Sciences

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“…The precedence of the Tarantula-II is based on the first version of the robot here referred as Tarantula-I reported in [27]. The two versions can be compared using the framework for evaluating the autonomy of the self-reconfigurable robot as reported in [28].…”

Section: Introductionmentioning

confidence: 99%

Design of a Self-Reconfigurable Drain Mapping Robot With Level-Shifting Capability

et al. 2020

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Nature has always been an inspiration for engineers and designers to have technological inventions. The postures, locomotion and gait cycles of animals are usually smooth, dynamically stable, and highly adaptable in an unknown terrain. Based on a giraffe's leg folding pattern, we develop a quadruped hybrid drain mapping robot with modular subsystems , four bar inversion mechanism based legs and bi-directional rolling wheel, named, Tarantula-II. The platform undergoes self-reconfiguration and achieves variable height and width, which in turn helps in navigation in a drain with multiple level-shifts. This paper describes the key features of giraffe's limb, how the folding pattern of the limbs are implemented in the robot design. In addition, we discuss the detailed mechanical design of platform, the kinematics analysis of each leg, kinematics of the platform with respect to wheels, and structural analysis of the platform under different gait condition. Applying the kinematics formulation and posture correction algorithm, we verify the mobility and level shifting capability of the platform both in lab setting and drain environment.

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Tarantula: Design, Modeling, and Kinematic Identification of a Quadruped Wheeled Robot

Cited by 30 publications

References 36 publications

Modeling and Assessing of Self-Reconfigurable Cleaning Robot hTetro Based on Energy Consumption

Modeling and Assessing of Self-Reconfigurable Cleaning Robot hTetro Based on Energy Consumption

Special Feature on Advanced Mobile Robotics

Design of a Self-Reconfigurable Drain Mapping Robot With Level-Shifting Capability

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