Andrew Lessieur scite author profile

We report the design of a morpho-functional robot called Husky Carbon. Our goal is to integrate two forms of mobility, aerial and quadrupedal legged locomotion, within a single platform. There are prohibitive design restrictions such as tight power budget and payload, which can particularly become important in aerial flights. To address these challenges, we pose a problem called the Mobility Value of Added Mass (MVAM) problem. In the MVAM problem, we attempt to allocate mass in our designs such that the energetic performance is affected the least. To solve the MVAM problem, we adopted a generative design approach using Grasshopper's evolutionary solver to synthesize a parametric design space for Husky. Then, this space was searched for the morphologies that could yield a minimized Total Cost Of Transport (TCOT) and payload. This approach revealed that a front heavy quadrupedal robot can achieve a lower TCOT while retaining larger margins on allowable added mass to its design. Based on this framework Husky was built and tested as a front heavy robot.

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An Integrated Mechanical Intelligence and Control Approach Towards Flight Control of Aerobat

Sihite¹,

Darabi²,

Dangol³

et al. 2021

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An Integrated Mechanical Intelligence and Control Approach Towards Flight Control of Aerobat

Sihite¹,

Darabi²,

Dangol³

et al. 2021

Preprint

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Our goal in this work is to expand the theory and practice of robot locomotion by addressing critical challenges associated with the robotic biomimicry of bat aerial locomotion. Bats are known for their pronounced, fast wing articulations, e.g., bats can mobilize as many as forty joints during a single wingbeat, with some joints reaching to over one thousand degrees per second in angular speed. Copying bats flight is a significant ordeal, however, very rewarding. Aerial drones with morphing bodies similar to bats can be safer, agile and energy efficient owing to their articulated and soft wings. Current design paradigms have failed to copy bat flight because they assume only closed-loop feedback roles and ignore computational roles carried out by morphology. To respond to the urgency, a design framework called Morphing via Integrated Mechanical Intelligence and Control (MIMIC) is proposed. In this paper, using the dynamic model of Northeastern University's Aerobat, which is designed to test the effectiveness of the MIMIC framework, it will be shown that computational structures and closed-loop feedback can be successfully used to mimic bats stable flight apparatus.

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Mechanical design and fabrication of a kinetic sculpture with application to bioinspired drone design

Lessieur

Sihite

Dangol

et al. 2021

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Andrew Lessieur

Rough-Terrain Locomotion and Unilateral Contact Force Regulations With a Multi-Modal Legged Robot

Generative Design of NU's Husky Carbon, A Morpho-Functional, Legged Robot

An Integrated Mechanical Intelligence and Control Approach Towards Flight Control of Aerobat

An Integrated Mechanical Intelligence and Control Approach Towards Flight Control of Aerobat

Mechanical design and fabrication of a kinetic sculpture with application to bioinspired drone design

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