Touchdown to take-off: at the interface of flight and surface locomotion

Roderick, William R. T.; Cutkosky, Mark R.; Lentink, David

doi:10.1098/rsfs.2016.0094

Cited by 72 publications

(70 citation statements)

References 176 publications

(407 reference statements)

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“…To the authors' knowledge, a thorough search of the relevant literature reveals that it does not exist any paper addressing a task similar to the one tackled by this letter. The most similar applications may be found in those employing climbing [5] and perching robots [6]. The former can climb on the surface of objects with different surface roughness, and the latter can perch on the surface of an object to eventually perform some manipulation tasks.…”

Section: State Of the Artmentioning

confidence: 99%

Nonlinear Model Predictive Control for the Stabilization of a Wheeled Unmanned Aerial Vehicle on a Pipe

Zhao

Ruggiero

Fontanelli

et al. 2019

IEEE Robot. Autom. Lett.

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This letter addresses the task of stabilizing a wheeled unmanned aerial vehicle on a pipe, which is an emerging application in oil and gas facilities for nondestructive measurements. After the derivation of the dynamic model of the system, a discrete-time nonlinear model predictive controller is designed over a finite horizon. The analysis of the asymptotic stability of the designed controller is carried out. Numerical tests show the performance and the robustness of the proposed solution.Index Terms-Nonlinear model predictive control, wheeled unmanned aerial vehicle, nondestructive testing

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Section: State Of the Artmentioning

confidence: 99%

Nonlinear Model Predictive Control for the Stabilization of a Wheeled Unmanned Aerial Vehicle on a Pipe

Zhao

Ruggiero

Fontanelli

et al. 2019

IEEE Robot. Autom. Lett.

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“…While the natural world evolves, its processes provides an extensive source of inspiration for creating comprehensive models of artificial systems that can mimic certain functions of their counterparts in nature (Manzanera & Smith, 2015). The bioinspired design paradigm (Kovač, 2014) and perching principles (Liu, Ravi, Kolomenskiy, & Tanaka, 2016;Roderick, Cutkosky, & Lentink, 2017) provide cross-disciplinary approaches to developing new devices by mimicking the natural world in the way of adopting concepts and principles in nature to solve engineering challenges.…”

Section: Brief Review On Biological Principles During Landing Maneumentioning

confidence: 99%

Bioinspired design of a landing system with soft shock absorbers for autonomous aerial robots

Zhang

Chermprayong

Tzoumanikas

et al. 2018

Journal of Field Robotics

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One of the main challenges for autonomous aerial robots is to land safely on a target position on varied surface structures in real‐world applications. Most of current aerial robots (especially multirotors) use only rigid landing gears, which limit the adaptability to environments and can cause damage to the sensitive cameras and other electronics onboard. This paper presents a bioinpsired landing system for autonomous aerial robots, built on the inspire–abstract–implement design paradigm and an additive manufacturing process for soft thermoplastic materials. This novel landing system consists of 3D printable Sarrus shock absorbers and soft landing pads which are integrated with an one‐degree‐of‐freedom actuation mechanism. Both designs of the Sarrus shock absorber and the soft landing pad are analyzed via finite element analysis, and are characterized with dynamic mechanical measurements. The landing system with 3D printed soft components is characterized by completing landing tests on flat, convex, and concave steel structures and grassy field in a total of 60 times at different speeds between 1 and 2 m/s. The adaptability and shock absorption capacity of the proposed landing system is then evaluated and benchmarked against rigid legs. It reveals that the system is able to adapt to varied surface structures and reduce impact force by 540N at maximum. The bioinspired landing strategy presented in this paper opens a promising avenue in Aerial Biorobotics, where a cross‐disciplinary approach in vehicle control and navigation is combined with soft technologies, enabled with adaptive morphology.

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“…With the estimate of distance, aerial robots potentially benefit from the ability to deploy a landing gear at a suitable moment or to approach the surface at arbitrary speed [42,43]. That is, the landing task is no longer constrained to a constant rate of optic flow.…”

Section: Altitude Estimation During Landing Maneuversmentioning

confidence: 99%

A direct optic flow-based strategy for inverse flight altitude estimation with monocular vision and IMU measurements

Chirarattananon

2018

Bioinspir. Biomim.

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With tiny and limited nervous systems, insects demonstrate a remarkable ability to fly through complex environments. Optic flow has been identified to play a crucial role in regulating flight conditions and navigation in flies and bees. In robotics, optic flow has been widely studied thanks to the low computational requirements. However, with only monocular visual information, optic flow is inherently devoid of a scale factor required for estimating the absolute distance. In this paper, we propose a strategy for estimating the flight altitude of a flying robot with a ventral camera by combining the optic flow with measurements from an inertial measurement unit. Instead of using the prevalent feature-based approach for calculation of optic flow, we implement a direct method that evaluates the flow information via image gradients. We show that the direct approach notably simplifies the computation steps compared to the feature-based method. When combined with an extended Kalman filter for fusion of inertial measurement units measurements, the flight altitude can be estimated in real time. We carried out extensive flight tests in different settings. Among 31 hovering and vertical flights near the altitude of 40 cm, we achieved the RMS errors in the altitude estimate of 2.51 cm. Further analysis of factors that affect the quality of the flow and the distance estimate is also provided. PAPER Original content from this work may be used under the terms of the Creative Commons Attribution 3.0 licence.

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Touchdown to take-off: at the interface of flight and surface locomotion

Cited by 72 publications

References 176 publications

Nonlinear Model Predictive Control for the Stabilization of a Wheeled Unmanned Aerial Vehicle on a Pipe

Nonlinear Model Predictive Control for the Stabilization of a Wheeled Unmanned Aerial Vehicle on a Pipe

Bioinspired design of a landing system with soft shock absorbers for autonomous aerial robots

A direct optic flow-based strategy for inverse flight altitude estimation with monocular vision and IMU measurements

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