IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0733361
(2013-01-03)
|
등록번호 |
US-8594862
(2013-11-26)
|
우선권정보 |
FR-12 50069 (2012-01-04) |
발명자
/ 주소 |
- Callou, Francois
- Foinet, Gilles
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
15 인용 특허 :
5 |
초록
▼
The user inclines the apparatus (16) according to the pitch (32) and roll (34) axes to produce inclination signals (θI, φI) which are transformed into corresponding command setpoints (θd, φd) for the drone (10) in terms of attitude of the drone according to the pitch (22) and roll (24) axes of the d
The user inclines the apparatus (16) according to the pitch (32) and roll (34) axes to produce inclination signals (θI, φI) which are transformed into corresponding command setpoints (θd, φd) for the drone (10) in terms of attitude of the drone according to the pitch (22) and roll (24) axes of the drone. The drone and the apparatus each determine the orientation of their local reference frame (XlYlZl; XbYbZb) in relation to an absolute reference frame linked to the ground (XNEDYNEDZNED), to determine the relative angular orientation of the drone in relation to the apparatus. Then, the reference frame of the apparatus is realigned on the reference frame of the drone by a rotation that is a function of this relative angular orientation. The realigned values thus correspond to user commands referenced in the reference frame of the apparatus and no longer in that of the drone, which allows for more intuitive piloting when the user is watching the drone.
대표청구항
▼
1. A method for piloting, by means of a remote control apparatus, a rotary wing drone with multiple rotors driven by respective motors that can be controlled in a differentiated manner to pilot the drone attitude-wise and speed-wise, comprising the following steps: by the apparatus (16): inclination
1. A method for piloting, by means of a remote control apparatus, a rotary wing drone with multiple rotors driven by respective motors that can be controlled in a differentiated manner to pilot the drone attitude-wise and speed-wise, comprising the following steps: by the apparatus (16): inclination of the apparatus according to the pitch (32) and roll (34) axes of this apparatus, and production of corresponding inclination signals (θI, φI); andtransformation of these inclination signals of the apparatus into piloting commands and sending of these commands to the drone, andby the drone (10): reception of the piloting commands and generation from these commands of setpoint values (θd, φd) for a drone motor control loop, these setpoint values being suitable for controlling the attitude of the drone according to the pitch (22) and roll (24) axes of the drone,wherein this method comprises the following additional steps:acquisition of first orientation data (ψiP) of a local reference frame linked to the apparatus (XlYlZl) in relation to an absolute reference frame linked to the ground (XNEDYNEDZNED);acquisition of second orientation data (ψdrone) of a local reference frame linked to the drone (XbYbZb) in relation to said absolute reference frame (XNEDYNEDZNED);computation of a relative angular orientation datum (Δψ) of the drone in relation to the apparatus, from said first and second orientation data; andrealignment of the reference frame of the apparatus on the reference frame of the drone, by application to the piloting commands of a rotation that is a function of said relative angular orientation datum, so as to thus produce realigned setpoint values according to the pitch and roll axes of the drone which are a function of the inclinations, applied to the apparatus by the user according to the pitch and roll axes thereof, considered in the local reference frame linked to the apparatus and no longer in that linked to the drone. 2. The method of claim 1, in which the first and the second orientation data are obtained from respective heading angles (ψdrone, ψiP) of the apparatus and of the drone in relation to the north. 3. The method of claim 2, in which said rotation that is a function of said relative angular orientation datum is of the type: (θdφd)=(cosΔψsinΔψ-sinΔψcosΔψ)(θIφI)θd and φd being the realigned setpoint values according to the pitch and roll axes in the local reference frame linked to the drone,θI and φI being the inclinations applied according to the pitch and roll axes in the local reference frame linked to the apparatus, andΔψ being the difference of the respective heading angles of the apparatus and of the drone in relation to the north. 4. The method of claim 3, in which the computation of said rotation is performed within the drone, directly from data received from the apparatus, these data comprising the values of the inclinations applied to the apparatus and a heading angle datum of the apparatus. 5. The method of claim 2, in which said rotation that is a function of said relative angular orientation datum is of the type: {θd=tan-1[cosΔψ·tanθI+sinΔψ·tanφIcosθI]φd=sin-1[cosΔψ·sinφI-sinΔψ·sinθI·cosφI]θd and φd being the realigned setpoint values according to the pitch and roll axes of the drone,θI and φI being the inclinations applied according to the pitch and roll axes of the apparatus, andΔψ being the difference of the respective heading angles of the apparatus and of the drone in relation to the north. 6. The method of claim 5, in which the computation of said rotation is performed partially within the apparatus and partially within the drone with: within the apparatus, computation of a first rotation from the values of the inclinations θI and φI applied to the apparatus and of a heading angle datum ψiP of the apparatus: (θI′φI′)=(cosψiPsinψiP-sinψiPcosψiP)(θIφI)within the drone, computation of a second rotation from a heading angle datum ψdrone of the drone: (θdφd)=(cosψdrone-sinψdronesinψdronecosψdrone)(θI′φI′) 7. The method of claim 2, in which the absolute reference frame linked to the ground is a geomagnetic reference frame, and the heading angles are the angles measured in relation to the magnetic north. 8. The method of claim 7, in which the determination of the heading angle of the drone comprises the acquisition of a magnetic heading measurement delivered by a magnetometric sensor (116) of the drone. 9. The method of claim 8, in which the heading angle of the drone is acquired by the combination: of a magnetic heading measurement delivered by a magnetometric sensor (116) of the drone with application of a low-pass filtering (152), andof a gyroscopic heading measurement delivered by an inertial unit of the drone (102) with application of a high-pass filtering (154) complementing said low-pass filtering. 10. The method of claim 8, also comprising a preliminary step of calibration of the magnetometric sensor of the drone. 11. The method of claim 10, in which said calibration step comprises the substeps of: ordering a complete rotation of the drone in flight, flat around a yaw axis;recording of the measurements delivered by the magnetometric sensor;determination of a global offset value representative of the surrounding disturbing magnetic fields and of the specific offset of the magnetometric sensor.
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