Passive stability enhancement with sails of a hovering flapping twin-wing robot

H. Altartouri; A. Roshanbin; G. Andreolli; L. Fazzi; M. Karásek; M. Lalami; A. Preumont

doi:10.1177/1756829319841817

Passive stability enhancement with sails of a hovering flapping twin-wing robot

H. Altartouri, A. Roshanbin, G. Andreolli, L. Fazzi, M. Karásek, M. Lalami, A. Preumont^*

^*Corresponding author for this work

Control & Simulation

Research output: Contribution to journal › Article › Scientific › peer-review

11 Citations (Scopus)

93 Downloads (Pure)

Abstract

Hovering flapping wing flight is intrinsically unstable in most cases and requires active flight stabilization mechanisms. This paper explores the passive stability enhancement with the addition of top and bottom sails, and the capability to predict the stability from a very simple model decoupling the roll and pitch axes. The various parameters involved in the dynamical model are evaluated from experiments. One of the findings is that the damping coefficient of a bottom sail (located in the flow induced by the flapping wings) is significantly larger than that of a top sail. Flight experiments have been conducted on a flapping wing robot of the size of a hummingbird with sails of various sizes and the observations regarding the flight stability correlate quite well with the predictions of the dynamical model. Twelve out of 13 flight experiments are in agreement with stability predictions.

Original language	English
Number of pages	9
Journal	International Journal of Micro Air Vehicles
Volume	11
DOIs	https://doi.org/10.1177/1756829319841817
Publication status	Published - 2019

Keywords

aero-dampers
Micro air vehicles
passive stabilization
stability derivatives

Access to Document

10.1177/1756829319841817

1756829319841817Final published version, 1.14 MBLicence: CC BY-NC

Cite this

@article{4d0a158785e740cbac04a019078e536b,

title = "Passive stability enhancement with sails of a hovering flapping twin-wing robot",

abstract = "Hovering flapping wing flight is intrinsically unstable in most cases and requires active flight stabilization mechanisms. This paper explores the passive stability enhancement with the addition of top and bottom sails, and the capability to predict the stability from a very simple model decoupling the roll and pitch axes. The various parameters involved in the dynamical model are evaluated from experiments. One of the findings is that the damping coefficient of a bottom sail (located in the flow induced by the flapping wings) is significantly larger than that of a top sail. Flight experiments have been conducted on a flapping wing robot of the size of a hummingbird with sails of various sizes and the observations regarding the flight stability correlate quite well with the predictions of the dynamical model. Twelve out of 13 flight experiments are in agreement with stability predictions.",

keywords = "aero-dampers, Micro air vehicles, passive stabilization, stability derivatives",

author = "H. Altartouri and A. Roshanbin and G. Andreolli and L. Fazzi and M. Kar{\'a}sek and M. Lalami and A. Preumont",

year = "2019",

doi = "10.1177/1756829319841817",

language = "English",

volume = "11",

journal = "International Journal of Micro Air Vehicles",

issn = "1756-8293",

publisher = "Multi-Science Publishing Co. Ltd",

}

TY - JOUR

T1 - Passive stability enhancement with sails of a hovering flapping twin-wing robot

AU - Altartouri, H.

AU - Roshanbin, A.

AU - Andreolli, G.

AU - Fazzi, L.

AU - Karásek, M.

AU - Lalami, M.

AU - Preumont, A.

PY - 2019

Y1 - 2019

N2 - Hovering flapping wing flight is intrinsically unstable in most cases and requires active flight stabilization mechanisms. This paper explores the passive stability enhancement with the addition of top and bottom sails, and the capability to predict the stability from a very simple model decoupling the roll and pitch axes. The various parameters involved in the dynamical model are evaluated from experiments. One of the findings is that the damping coefficient of a bottom sail (located in the flow induced by the flapping wings) is significantly larger than that of a top sail. Flight experiments have been conducted on a flapping wing robot of the size of a hummingbird with sails of various sizes and the observations regarding the flight stability correlate quite well with the predictions of the dynamical model. Twelve out of 13 flight experiments are in agreement with stability predictions.

AB - Hovering flapping wing flight is intrinsically unstable in most cases and requires active flight stabilization mechanisms. This paper explores the passive stability enhancement with the addition of top and bottom sails, and the capability to predict the stability from a very simple model decoupling the roll and pitch axes. The various parameters involved in the dynamical model are evaluated from experiments. One of the findings is that the damping coefficient of a bottom sail (located in the flow induced by the flapping wings) is significantly larger than that of a top sail. Flight experiments have been conducted on a flapping wing robot of the size of a hummingbird with sails of various sizes and the observations regarding the flight stability correlate quite well with the predictions of the dynamical model. Twelve out of 13 flight experiments are in agreement with stability predictions.

KW - aero-dampers

KW - Micro air vehicles

KW - passive stabilization

KW - stability derivatives

UR - http://www.scopus.com/inward/record.url?scp=85064196233&partnerID=8YFLogxK

U2 - 10.1177/1756829319841817

DO - 10.1177/1756829319841817

M3 - Article

AN - SCOPUS:85064196233

SN - 1756-8293

VL - 11

JO - International Journal of Micro Air Vehicles

JF - International Journal of Micro Air Vehicles

ER -

Passive stability enhancement with sails of a hovering flapping twin-wing robot

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this