1.3.4.2 Radar Positioning and Return to Home
Most drones are equipped with GPS but now the latest drones have dual Global Navigation Satellite Systems (GNSS) [13] such as GPS [14] and GLONASS [3] (Global Orbiting Navigation Satellite System, Russian). Drones can fly in both non-satellite mode and GNSS mode. For example, DJI drones can fly in P-Mode (GPS and GLONASS) or ATTI mode, which don’t use GPS. Highly accurate drone navigation is important while flying, as it has immense importance in drone applications such as surveying the landscape, SAR (Search and Rescue) missions, and creating 3D maps.
When the quadcopter is switched on its navigation satellite searches and detects GNSS satellite. High-end GNSS systems use satellite Constellation Technology. A satellite constellation is a group of satellites working together in near proximity and sync with one another giving coordinated coverage. This is done in such a way that these satellites overlap an area and is well in coverage. Here, pass or coverage is referred to as the period in which a satellite is visible above the local horizon.
1.3.4.3 GNSS on Ground Control Station
RADAR displays the below data on the remote control display:
1. Signals that adequate GNSS satellite signals are detected and the drone is ready to fly.
2. Displays the current location and position or orientation of a drone in accordance with the controller.
3. Records the home-point for the ‘Return to Home’ safety feature.
The return-to-home safety feature can be pilot initiated by pressing the button on the remote controller or in an application/software, also it can be automatically triggered when the battery is low as a failsafe whenever there is a loss of contact between remote controller and UAV, then UAV will fly back automatically to its home point. The latest technology drone has obstacle avoidance technology while returning home.
1.3.4.4 Collision Avoidance Technology and Obstacle Detection
Modern drones are now equipped with a collision-avoidance system. They use sensors/cameras or scanners to scan their surroundings, while SLAM (Simultaneous Localization & Mapping) technology produces 3D maps from real-time images allowing them to involve in real-time to sense and avoid. SLAM is an extremely important technology when it comes to drones, robots and cars in detecting and avoiding obstacles. Through the combined feedback of the sensors the drone’s sense and avoid, there are:
1 1. Monocular Vision
2 2. Vision Sensor
3 3. Ultrasonic Sensor
4 4. Time-of-Flight (ToF)
5 5. Infrared
6 6. LIDAR.
Drones these days have obstacle avoidance sensors on all six sides. They use both infrared and vision sensors which are then fused into the vision system and this technique is known as Omni-directional obstacle sensing [3]. It senses an object then flies around the obstacle, avoiding any collision and can also do the same when flying in the opposite direction. Also, it can hover if it isn’t possible to pass the obstacle. This technology is known as APAS (Advanced Pilot Assistance System).
1.3.4.5 Gyroscopic Stabilization, Flight Controllers and IMU
Gyroscopic stabilization technology gives the UAV drone its smooth flying capabilities. The gyroscope works almost instantly to the forces moving against the drone, keeping it flying or hovering smoothly. It provides essential navigational information to the flight controller.
The IMU (Inertial Measurement Unit) detects the current rate of acceleration using one or more accelerometers. The IMU detects the changes in rotational attributes like pitch, yaw, and roll using one or more gyroscopes. Sometimes a magnetometer is also used with the IMU to assist with calibration against orientation drift. Gyroscope is a component of IMU and IMU is an essential component of the Flight controller which is the central brain of the drone.
1.3.4.6 UAV Drone Propulsion System
The propulsion system with which drones fly in any direction or hover includes BLDC motors (Brushless DC motor), ESC (Electronic Speed Controller), and propellers. It varies according to the different types of platforms. In a quadcopter, the motor and propellers work in pairs with two motors & propellers placed alternatively one pair rotating clockwise (CW propellers), the other two motors rotate counter-clockwise (CCW Propellers). Similarly, in Hex three motors/propellers pair and in Oct four motors/propellers pair. These BLDC motors receive the electric signal from ESC which receives the signal from the flight controller which in turn receives the signal from the radio transmitter. Together they signal motor speed, braking, monitoring, and fault tolerance.
Apart, from this combustion-derived propulsion is also used in UAV mostly in a fixed-wing platform where some of them use a mini Turbojet engine to cruise at a higher speed. These fast jet mini UAVs have achieved speed as high as 700 km/h and even more. It uses ECU (Engine Control Unit) which comes along with actuators and some sensors and is directly connected to the fuel supply line of the combustion chamber to control the speed of the Turbojet engine.
1.3.4.6.1 Proposed Technology
With advancement and improvement in propulsion system technology, it could be possible in the future that drone would be propelled by ion thruster without brushless motor, while drones with turbojet engine traveling very far distance have already become possible but still achieving heights as high as that of satellites with much higher speed is still a future tech. However, this type of drone will have less application for commercial purposes and will be more for research & military tech, and would be costly [15].
1.3.4.7 Flight Parameters Through Telemetry
Nearly all drones have a Ground Station Controller (GSC), allowing the remote controller to fly the drone and keep track of the current flight telemetry. Telemetry data on the remote controller may include remaining battery power, warnings, speed, height, UAV range, GNSS strength, and video.
1.3.4.8 Drone Security & Hacking
UAV in many ways is a kind of flying computer with an operating system, flight controllers, and other boards with programmable codes, they can also be hacked into. There are Drones that have been developed to fly around seeking other drones and hacking into the drone wireless network, which then disconnects the owner and takes over that drone. However, there are some ways to protect your drone from hackers [17, 18].
1.3.4.9 3D Maps and Models With Drone Sensors
Multispectral, LIDAR & Photogrammetry sensors are used to build 3D models of landscapes and buildings. Thermal vision and low light night vision sensors are used by drones to scan landscapes, building to assist in agriculture,