The problem of on-ground testing guidance, navigation and control (GNC) algorithms for planetary accurate and safe landing can be approached through the Flight of small quadrotors (< 1kg mass), suitable for indoor and outdoor operations. The literature is full of studies and experiments with such aerial vehicles (sometimes referred to as aerial robots as well) aiming at very different exploration, commercial and education goals. Here we focus on the test of GNC algorithms for planetary landing that are partly presented in a companion paper submitted to this conference and others submitted elsewhere. Only simulated results will be presented as a baseline, as the relevant hardware, to be employed outside of the aforementioned project STEPS, is under procurement. Modelling and control design will follow the Embedded Model Control methodology . Firstly, the main difference of an on- Earth-flying quadrotor dynamics with respect to a generic planetary landing vehicle is analyzed, showing that a similitude can be formulated, capable of scaling down mass, geometry and trajectories to outdoor tests, and of compensating the different gravity acceleration. As a result, indoor tests look rather critical as they would require small quantization to quadrotor thrusts, in order to keep landing flight duration constant. Similitude to be very accurate needs a careful model of propeller dynamics and response. A further problem comes from emulating radar altimeter and velocimeter; both can be emulated by a GPS receiver but reliably only in outdoor tests. Indoor tests should require camera. Radar altimeters are massive. Altimeter may be also emulated by a barometric altimeter. Ultrasonic range sensors are used at touch-down. Initial alignment must be provided by some attitude sensor either magnetometers or external markers, or the accelerometer themselves (on-ground). Subsequently under a short flight time (< 200s), attitude, velocity and position can be obtained by gyro and accelerometer integration. Thus essential sensor devices are assumed, namely IMU (accelerometers and gyros) and ultrasonic range sensor (conservative conditions). An outline of the guidance, navigation and control algorithms is included. Simulated runs are provided.

MODELLING AND CONTROL OF A SMALL QUADROTOR FOR TESTING PROPULSIVEPLANETARY LANDING GUIDANCE, NAVIGATION AND CONTROL / Canuto, Enrico; Perez, C.. - ELETTRONICO. - IAC-12:(2012), pp. A3.2D.1-A3.2D.9. (Intervento presentato al convegno 63rd IAC- International Astronautical Congress tenutosi a Napoli nel 1-5 Ottobre).

MODELLING AND CONTROL OF A SMALL QUADROTOR FOR TESTING PROPULSIVEPLANETARY LANDING GUIDANCE, NAVIGATION AND CONTROL

CANUTO, Enrico;
2012

Abstract

The problem of on-ground testing guidance, navigation and control (GNC) algorithms for planetary accurate and safe landing can be approached through the Flight of small quadrotors (< 1kg mass), suitable for indoor and outdoor operations. The literature is full of studies and experiments with such aerial vehicles (sometimes referred to as aerial robots as well) aiming at very different exploration, commercial and education goals. Here we focus on the test of GNC algorithms for planetary landing that are partly presented in a companion paper submitted to this conference and others submitted elsewhere. Only simulated results will be presented as a baseline, as the relevant hardware, to be employed outside of the aforementioned project STEPS, is under procurement. Modelling and control design will follow the Embedded Model Control methodology . Firstly, the main difference of an on- Earth-flying quadrotor dynamics with respect to a generic planetary landing vehicle is analyzed, showing that a similitude can be formulated, capable of scaling down mass, geometry and trajectories to outdoor tests, and of compensating the different gravity acceleration. As a result, indoor tests look rather critical as they would require small quantization to quadrotor thrusts, in order to keep landing flight duration constant. Similitude to be very accurate needs a careful model of propeller dynamics and response. A further problem comes from emulating radar altimeter and velocimeter; both can be emulated by a GPS receiver but reliably only in outdoor tests. Indoor tests should require camera. Radar altimeters are massive. Altimeter may be also emulated by a barometric altimeter. Ultrasonic range sensors are used at touch-down. Initial alignment must be provided by some attitude sensor either magnetometers or external markers, or the accelerometer themselves (on-ground). Subsequently under a short flight time (< 200s), attitude, velocity and position can be obtained by gyro and accelerometer integration. Thus essential sensor devices are assumed, namely IMU (accelerometers and gyros) and ultrasonic range sensor (conservative conditions). An outline of the guidance, navigation and control algorithms is included. Simulated runs are provided.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2497002
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