Planning Adaptive Brachistochrone and Circular Arc Hip Trajectory for a Toe-Foot Bipedal Robot going Downstairs

Bhardwaj, Gaurav; Mishra, Utkarsh A.; Sukavanam, N.; Balasubramanian, R.

doi:10.1088/1742-6596/1831/1/012032

Cited by 2 publications

(2 citation statements)

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“…The commonly used swing leg trajectories for legged robots are geometrically designed, like spline [12] or cycloid [13]. But these trajectories didn't consider the dynamics of the leg, thus these swing leg trajectories cannot comply with the characteristics of the natural mammal's swing leg trajectories.…”

Section: Related Workmentioning

confidence: 99%

Smart Gait: A Gait Optimization Framework for Hexapod Robots

Yin,

Gao,

Sun

et al. 2023

Preprint

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This paper proposes a gait optimization framework for hexapod robots called Smart Gait. Smart Gait contains three modules: swing leg trajectory optimization, gait period & duty optimization, and gait sequence optimization. The full dynamics of a single leg, and the centroid dynamics of the overall robot are considered in the respective modules. The Smart Gait not only helps the robot to decrease the energy consumption when in locomotion, mostly, it enables the hexapod robot to determine its gait pattern transitions based on its current state, instead of repeating the formalistic clock-set step cycles. Our Smart Gait framework allows the hexapod robot to behave nimbly as a living animal when in 3D movements for the first time. The Smart Gait framework combines offline and online optimizations without any fussy data-driven training procedures, and it can run efficiently on board in real-time after deployment. Various experiments are carried out on the hexapod robot LittleStrong and have shown promising results, fully demonstrating the feasibility of our algorithm.

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Section: Related Workmentioning

confidence: 99%

Smart Gait: A Gait Optimization Framework for Hexapod Robots

Yin,

Gao,

Sun

et al. 2023

Preprint

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“…Another important but not often stressed part of bipedal robots is the hip. Udai [24] and Bhardwaj [25] both discussed the hip trajectory of bipedal robots. Previous work of Tang [23] also proposed a symmetrical hip design for bipedal robots.…”

Section: Introductionmentioning

confidence: 99%

High Dynamic Bipedal Robot with Underactuated Telescopic Straight Legs

Mou,

Tang,

Liu

et al. 2024

Mathematics

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Bipedal robots have long been a focal point of robotics research with an unwavering emphasis on platform stability. Achieving stability necessitates meticulous design considerations at every stage, encompassing resilience against environmental disturbances and the inevitable wear associated with various tasks. In pursuit of these objectives, here, the bipedal L04 Robot is introduced. The L04 Robot employs a groundbreaking approach by compactly enclosing the hip joints in all directions and employing a coupled joint design. This innovative approach allows the robot to attain the traditional 6 degrees of freedom in the hip joint while using only four motors. This design not only enhances energy efficiency and battery life but also safeguards all vulnerable motor reducers. Moreover, the double-slider leg design enables the robot to simulate knee bending and leg height adjustment through leg extension. This simulation can be mathematically modeled as a linear inverted pendulum (LIP), rendering the L04 Robot a versatile platform for research into bipedal robot motion control. A dynamic analysis of the bipedal robot based on this structural innovation is conducted accordingly. The design of motion control laws for forward, backward, and lateral movements are also presented. Both simulation and physical experiments corroborate the excellent bipedal walking performance, affirming the stability and superior walking capabilities of the L04 Robot.

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Planning Adaptive Brachistochrone and Circular Arc Hip Trajectory for a Toe-Foot Bipedal Robot going Downstairs

Cited by 2 publications

References 0 publications

Smart Gait: A Gait Optimization Framework for Hexapod Robots

Smart Gait: A Gait Optimization Framework for Hexapod Robots

High Dynamic Bipedal Robot with Underactuated Telescopic Straight Legs

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