Abstract
We developed an octocopter-based unmanned aerial system (UAS) to monitor remote environments. The system contains various environmental monitoring sensors for measuring wind speed/direction, temperature, relative humidity, atmospheric pressure, fine dust, and multispectral and RGB data. The UAS consists of an unmanned aerial vehicle (UAV), a ground control station, and a server. We studied its electrical, mechanical, and software (SW) configurations. Specifically, we developed hardware (HW) and SW to control the yaw and gimbal pitch directions of the UAV conveying multispectral and RGB cameras. To prevent the obtained solar reflectance from affecting the multispectral and RGB data and to improve the quality of the obtained data, we maneuvered the yaw so that it would always deviate 135° from the solar azimuth angle, with the sun at its rear. Managing the yaw direction involves controlling the UAV based on a micro air vehicle link message-based robot operating system (ROS). To safely test the UAS performance before the maiden flight in an ocean area, we first evaluated PX4 and ROS-based SW through indoor software-in-the-loop simulation (SILS) via the Gazebo tool. Subsequently, we used an F450 UAV and an actual maritime UAV to sequentially perform pre-flight and flight experiments. This paper explains the system operation scenario, UAS component, and simulation and experimental results. The results reveal that the average yaw angle error during the mission, $\bar {\left |{ \theta _{y,des}-\theta _{y} }\right |}$ , is approximately 8°, and the average pitch angle of the gimbal during the mission, $\left |{ 50^{\circ }-\left |{ \bar {\theta _{c}} }\right | }\right |$ , is less than 5°.
Highlights
Satellites [1,2], crewed aircraft [3,4], and vessels [5] generally capture ocean color, a critical indicator of ocean conditions
SOFTWARE CONFIGURATION To maneuver the directional angle of both the multispectral camera and RGB camera mounted on the gimbal, we controlled the yaw angle of the unmanned aerial vehicle (UAV) and pitch angle of the gimbal based on the robot operating system (ROS), which we installed on an mission computer (MC) communicating with an flight controller (FC)
Detail F450 quadrotor UAV carrying a Jetson TX2 assembled with an Orbitty Carrier board 2021-04-16 12:47 Lat: 35.143364°, Lon: 126.925803°, Alt: 57 m 188.62° 53.62°
Summary
Satellites [1,2], crewed aircraft [3,4], and vessels [5] generally capture ocean color, a critical indicator of ocean conditions. It may be challenging to capture anomalies, such as the red tide in the ocean [6], which requires immediate or time-based observations. Understanding phenomena such as the resuspension– precipitation process of suspended solids and the spread of low-salinity water originating in coastal areas is difficult. Using a micro-sized multi-copter UAV can measure real-time data for distances up to tens of kilometers, which sufficiently monitors anomalies occurring near a coastal area or near a moving ship in the middle of a vast sea [7,8,9]. Because of the benefits mentioned above, UAS can be used for marine fauna surveys in place of crewed aircraft [10,11,12,13,14,15,16,17,18]
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