Title :
Particle filter based multi-sensor data fusion techniques for RPAS navigation and guidance
Author :
Cappello, Francesco ; Sabatini, Roberto ; Ramasamy, Subramanian ; Marino, Matthew
Author_Institution :
Sch. of Aerosp., Mech. & Manuf. Eng., RMIT Univ., Melbourne, VIC, Australia
Abstract :
This paper presents a Particle Filter (PF) based Multi-Sensor Data Fusion (MSDF) technique in an integrated Navigation and Guidance System (NGS) design based on low-cost avionics sensors. The performance of PF based MSDF method is compared with other previously implemented data fusion architectures for small-sized Remotely Piloted Aircraft Systems (RPAS). The sensor suite of the implemented NGS includes; Global Navigation Satellite System (GNSS) sensor, which is adopted as the primary means of navigation, Micro-ElectroMechanical System (MEMS) based Inertial Measuring Unit (IMU) and Vision-Based Navigation (VBN) sensor. Additionally, an Aircraft Dynamics Model (ADM) is used as a virtual sensor to compensate for the MEMS-IMU sensor shortcomings in high-dynamics attitude determination tasks. The PF is specifically implemented to increase the accuracy of navigation solution obtained from the inherently inaccurate, low-cost Commercial-Off-The-Shelf (COTS) sensors. Simulations are carried out on the AEROSONDE RPAS performing high-dynamics manoeuvres representative of the RPAS operational flight envelope. The Extended Kalman Filter (EKF) based VBN-IMU-GNSS-ADM (E-VIGA) system, Unscented Kalman Filter (UKF) based U-VIGA system and the PF based P-VIGA system performances are evaluated and compared. Additionally, an error covariance analysis is performed on the centralised filter using Monte Carlo simulation. Results indicate that the PF is computationally expensive as the number of particles is increased. Compared to E-VIGA and U-VIGA systems, P-VIGA system shows an improvement of accuracy in the position, velocity and attitude measurements.
Keywords :
Kalman filters; Monte Carlo methods; aircraft navigation; avionics; microsensors; nonlinear filters; particle filtering (numerical methods); remotely operated vehicles; satellite navigation; sensor fusion; vehicle dynamics; ADM; AEROSONDE RPAS; COTS sensors; E-VIGA system; EKF based VBN-IMU-GNSS-ADM system; GNSS sensor; MEMS-IMU sensor; Monte Carlo simulation; NGS design; PF MSDF technique; PF based P-VIGA system performances; RPAS navigation and guidance; RPAS operational flight envelope; UKF based U-VIGA system; VBN sensor; aircraft dynamics model; attitude measurements; centralised filter; data fusion architectures; error covariance analysis; extended Kalman filter; global navigation satellite system; high-dynamics attitude determination tasks; high-dynamics manoeuvres; integrated navigation and guidance system design; low-cost avionics sensors; low-cost commercial-off-the-shelf sensors; microelectromechanical system based inertial measuring unit; particle filter based multisensor data fusion techniques; position measurements; small-sized remotely piloted aircraft systems; unscented Kalman filter; velocity measurements; virtual sensor; vision-based navigation sensor; Aircraft; Aircraft navigation; Approximation methods; Atmospheric measurements; Computational modeling; Global Positioning System; Sensors; Aircraft Dynamics Model; Global Navigation Satellite System; Low-Cost Avionics Sensors; Particle Filter; Remotely Piloted Aircraft Systems; Unscented Kalman Filter;
Conference_Titel :
Metrology for Aerospace (MetroAeroSpace), 2015 IEEE
Conference_Location :
Benevento
DOI :
10.1109/MetroAeroSpace.2015.7180689
