Abstract
This paper presents a non-linear state observer-based integrated navigation scheme for estimating the attitude, position and velocity of micro aerial vehicles (MAV) operating in GPS-denied indoor environments, using the measurements from low-cost MEMS (micro electro-mechanical systems) inertial sensors and an RGB-D camera. A robust RGB-D visual odometry (VO) approach was developed to estimate the MAV’s relative motion by extracting and matching features captured by the RGB-D camera from the environment. The state observer of the RGB-D visual-aided inertial navigation was then designed based on the invariant observer theory for systems possessing symmetries. The motion estimates from the RGB-D VO were fused with inertial and magnetic measurements from the onboard MEMS sensors via the state observer, providing the MAV with accurate estimates of its full six degree-of-freedom states. Implementations on a quadrotor MAV and indoor flight test results demonstrate that the resulting state observer is effective in estimating the MAV’s states without relying on external navigation aids such as GPS. The properties of computational efficiency and simplicity in gain tuning make the proposed invariant observer-based navigation scheme appealing for actual MAV applications in indoor environments.
Highlights
Micro aerial vehicles (MAV) are playing an increasingly important role in both civil and military applications
RGB-D visual odometry refers to the process of estimating the relative motion of the MAV between successive time steps, using environmental features from consecutive images captured by the RGB-D camera
These results indicate that the drifts of the low-cost MEMS IMU sensor can be effectively bounded through data fusion of RGB-D visual odometry (VO) estimates and inertial measurements using the proposed invariant observer
Summary
Micro aerial vehicles (MAV) are playing an increasingly important role in both civil and military applications. One of the key problems is the state estimation of MAVs since the control and other decision-making functions rely on reliable and accurate knowledge of the MAV’s position, attitude and velocity This requires the design and development of lightweight navigation systems to provide reliable state estimation of the vehicle. Taking advantage of RGB-D devices, many researchers have achieved successful results in the field of indoor MAV navigation, such as state estimation, control and indoor mapping [17,18] Despite these advances achieved in this domain, there is still significant progress to be made in developing more robust and computationally efficient visual odometry approaches for MAVs in complex environments, using lightweight and low-cost RGB-D devices and MEMS sensors.
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