Distance sensors provide distance measurement that can be used for terrain following, precision hovering (e.g. for photography), warning of regulatory height limits, collision avoidance etc.
The sensors can usually be connected to either a serial (PWM) or I2C port (depending on the device driver), and is enabled on the port by setting a particular parameter.
This section lists the distance sensors supported by PX4 (linked to more detailed documentation), the generic configuration required for all rangefinders, testing, and simulation information.
Lidar-Lite is a compact, high-performance optical distant measurement rangefinder. It has a sensor range from (5cm - 40m) and can be connected to either PWM or I2C ports.
The MaxBotix I2CXL-MaxSonar-EZ range has a number of relatively short-ranged sonar based rangefinders that are suitable for assisted takeoff/landing and collision avoidance. These can be connected using an I2C port.
The rangefinders are enabled using the parameter SENS_EN_MB12XX.
Lightware SFxx Lidar provide a range of lightweight "laser altimeters" that are suitable for many drone applications:
- SF10/A (25 m)
- SF10/B (50 m)
- SF10/C (100m) (Discontinued)
- SF11/C (120 m)
- SF/LW20 (100 m) - Waterproofed (IP67) with servo for sense-and-avoid applications
Drivers exist for both I2C and serial ports (not all devices are supported for both serial and I2C).
TeraRanger provide a number of lightweight distance measurement sensor based on infrared Time-of-Flight (ToF) technology. They are typically faster and have greater range than sonar, and smaller and lighter than laser-based systems. PX4 supports:
- TeraRanger One (0.2 - 14 m) (Requires an I2C adapter)
- TeraRanger Evo 60m (0.5 – 60 m)
- TeraRanger Evo 600Hz (0.75 - 8 m)
All TeraRanger sensors must be connected via the I2C bus. While TeraRanger One requires an I2C adapter any sensor from TeraRanger Evo series can be connected directly to the autopilot.
The sensors are enabled using the parameter SENS_EN_TRANGER (you can set the type of sensor or that PX4 should auto-detect the type).
If using auto-detect for Evo sensors the minimum and maximum values for the range are set to the lowest and highest possible readings across the Evo family (currently 0.5 - 60 m). In order to use the correct max/min values the appropriate model of the Evo sensor should be set in the parameter (instead of using autodetect).
The Terranger One is used in the Qualcomm Snapdragon Flight.
The Aerotenna uLanding Radar is compact microwave rangefinder that has been optimised for use on UAVs. It has a sensing range of 45m. A particular advantages of this product are that it can operate effectively in all weather conditions and over all terrain types (including water).
LeddarOne is small Lidar module with a narrow, yet diffuse beam that offers excellent overall detection range and performance, in a robust, reliable, cost-effective package. It has a sensing range from 1cm to 40m and needs to be connected to a UART/serial bus.
The Benewake TFmini Lidar is a tiny, low cost, and low power LIDAR with 12m range.
PX4 also supports the Bebop rangefinder.
The rangefinder is configured using EKF2RNG* parameters. These configure information about the offset of the rangefinder from the centre of the vehicle body, the approximate delay of data reaching the estimator from the sensor, etc.
The rangefinder can be enabled in two ways:
- Set EKF2_HGT_MODE to Range finder (
2). This makes the rangefinder the primary source of height estimation (the default altitude sensor is the barometer).
- Set EKF2_RNG_AID to
1. This makes the vehicle use the rangefinder as the primary source when it is safe to use, but will otherwise use the sensor specified in
The easiest way to test the rangefinder is to vary the range and compare to the values detected by PX4. The sections below show some approaches to getting the measured range.
The QGroundControl Analyze Tool tool and QGroundControl MAVLink Inspector let you view messages sent from the vehicle, including
DISTANCE_SENSOR information from the rangefinder. The main difference between the tools is that the Analyze tool can plot values in a graph.
The messages that are sent depend on the vehicle configuration. You will only get
DISTANCE_SENSORmessages if the connected vehicle has a rangefinder installed and is publishing sensor values.
To view the rangefinder output:
Open the menu Widgets > Analyze:
Select the message
DISTANCE_SENSOR.current_value. The tool will then plot the result:
You can also use the QGroundControl MAVLink Console to observe the
distance_sensor uORB topic:
listener distance_sensor 5
The QGroundControl MAVLink Console works when connected to Pixhawk or other NuttX targets, but not the Simulator. On the Simulator you can run the commands directly in the terminal.
For more information see: Sensor/Topic Debugging using the Listener Command (PX4 Development Guide).
Lidar and sonar rangefinders can be used in the Gazebo Simulator (PX4 Development Guide). To do this you must start the simulator using a vehicle model that includes the rangefinder.
The iris optical flow model includes a Lidar rangefinder:
make px4_sitl gazebo_iris_opt_flow
The typhoon_h480 includes a sonar rangefinder:
make px4_sitl gazebo_typhoon_h480
If you need to use a different vehicle you can include the model in its configuration file. You can see how in the respective Iris and Typhoon configuration files:
xml <include> <uri>model://sonar</uri> </include> <joint name="sonar_joint" type="revolute"> <child>sonar_model::link</child> <parent>typhoon_h480::base_link</parent> <axis> <xyz>0 0 1</xyz> <limit> <upper>0</upper> <lower>0</lower> </limit> </axis> </joint>
xml <include> <uri>model://lidar</uri> <pose>-0.12 0 0 0 3.1415 0</pose> </include> <joint name="lidar_joint" type="revolute"> <child>lidar::link</child> <parent>iris::base_link</parent> <axis> <xyz>0 0 1</xyz> <limit> <upper>0</upper> <lower>0</lower> </limit> </axis> </joint>
- Rangefinder (Pixhawk.org) - Rangefinders supported by Pixhawk