Micro/nano mono-wing aircraft with the wing configured as a winged seed (Samara) is uniquely suited for autonomous or remotely controlled operation in confined environments for surrounding images acquisition. The aircraft is capable of effective autorotation and steady hovering. The wing is flexibly
Micro/nano mono-wing aircraft with the wing configured as a winged seed (Samara) is uniquely suited for autonomous or remotely controlled operation in confined environments for surrounding images acquisition. The aircraft is capable of effective autorotation and steady hovering. The wing is flexibly connected to a fuselage via a servo-mechanism which is controlled to change the wing's orientation to control the flight trajectory and characteristics. A propeller on the fuselage rotates about the axis oriented to oppose a torque created about the longitudinal axis of the fuselage and is controlled to contribute in the aircraft maneuvers. A controller, either ON-board or OFF-board, creates input command signals to control the operation of the aircraft based on a linear control model identified as a result of extensive experimentations with a number of models.
대표청구항▼
1. A miniature mono-wing aircraft, comprising: a wing configured in the shape of a winged seed (Samara),a fuselage member flexibly coupled to said wing at one end thereof, anda controller unit operatively coupled to said wing to control said wing orientation relative said fuselage member, thereby co
1. A miniature mono-wing aircraft, comprising: a wing configured in the shape of a winged seed (Samara),a fuselage member flexibly coupled to said wing at one end thereof, anda controller unit operatively coupled to said wing to control said wing orientation relative said fuselage member, thereby controlling said mono-wing aircraft displacement said controller unit generating a first input control signal corresponding to a collective pitch command for said wing based on said aircraft vertical position and heave velocity. 2. The miniature mono-wing aircraft of claim 1, further comprising at least one propeller attached to said fuselage member in proximity to one end thereof and actuated by said controller unit. 3. The miniature mono-wing aircraft of claim 2, wherein an axis cx extends along said fuselage member, wherein an axis cy is a pitch axis of said wing, wherein said axis cx is substantially perpendicular to said axis cy, wherein an axis cz of the aircraft rotation extends in perpendicular to a plane formed by said axes cx,cy, and wherein a said at least one propeller rotates in a plane positioned in a predetermined angular range relative said axes cx, cy, cz. 4. The miniature mono-wing aircraft of claim 3, wherein said predetermined angular range is −90°-+45° in a plane formed by said axis cx, cz, and wherein said predetermined angular range is −45°-+45° in a plane formed by said axis cx, cy. 5. The miniature mono-wing aircraft of claim 3, further coupling a second propeller rotating around a rotational axis extending in opposite direction of a rotational axis of said at least one propeller. 6. The miniature mono-wing aircraft of claim 2, further comprising: a servo mechanism coupled to said wing at said one end thereof, wherein said controller unit is operatively coupled to said servo mechanism to control the orientation of said wing. 7. The miniature mono-wing aircraft of claim 6, wherein said controller unit couples said first input control signal to said servo mechanism. 8. The miniature mono-wing aircraft of claim 7, wherein the heave velocity w(t) response of said miniature mono-wing aircraft to said first input control signal is described by ω(t)=-Zθ0Zωθ0(1-ⅇZωt),where θ0 is an input collective pitch control signal, Zθ0 is a collective pitch stability derivative, and Zω is a heave stability derivative. 9. The miniature mono-wing aircraft of claim 7, wherein for said first input control signal described by: θ=θ0+θ1c cos ψ+θ1s sin ψ,said wing resulting orientation is described by: β=β0+θ1c cos(ω−π/2)+θ1s sin(ψ−π/2),wherein θ is a wing input control pitch signal, θ0 is an input control collective pitch, θ1c is an input control pitch of the wing causing forward motion of the aircraft, θ1s is an input control pitch of the wing causing lateral motion of the aircraft, ψ is an azimuth of the wing, β is the wing response flap to said wing input control signal, and β0 is the mean flap angle response of said wing. 10. The miniature mono-wing aircraft of claim 7, wherein a relationship between said first input control signal and a resulting reaction of said wing is described by a linear control model. 11. The miniature mono-wing aircraft of claim 6, wherein said controller unit generates a second input control signal corresponding to a rotation speed of said at least one propeller and couples said second input control signal to said at least one propeller to control a throttle of said aircraft. 12. The miniature mono-wing aircraft of claim 2, wherein said controller unit is selected from a group consisting of an on-board control unit secured at said fuselage, and an off-board control unit operatively coupled to said on-board control unit, wherein said on-board control unit includes a receiver receiving input control signals generated to control the operation of said aircraft in a desired manner. 13. The miniature mono-wing aircraft of claim 2, further including a motor attached to said fuselage member and rotating said at least one propeller. 14. The miniature mono-wing aircraft of claim 2, wherein said fuselage member is attached to said wing in proximity to the center of mass thereof. 15. The miniature mono-wing aircraft of claim 1, wherein said wing has the area centroid thereof located between the geometric center line and the tip of said wing. 16. The miniature mono-wing aircraft of claim 1, wherein said wing has a leading edge and a trailing edge, and wherein said leading edge has a larger vertical cross-section than said trailing edge. 17. The miniature mono-wing aircraft of claim 16, wherein for the optimal descent, a span of said wing along said trailing edge thereof is approximately 0.168 m, and the width of said wing between the leading and trailing edges is approximately 0.048 m. 18. The miniature mono-wing aircraft of claim 1, wherein said controller unit includes a control unit selected from a group consisting of: open-loop controller, closed-loop controller, and a feedback control unit, said feedback control unit including a Proportional-plus-Derivative Plus Integral (PID) controller.
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이 특허에 인용된 특허 (3)
Jameson, Stephen M.; Boesch, Brian P.; Allen, Edward H., Active maple seed flyer.
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