septentrio_gnss_driver

ROSaic: C++ driver for Septentrio’s GNSS and INS receivers

README

ROSaic = ROS + mosaic

Overview

This repository hosts drivers for ROS 1 (Melodic and Noetic) and ROS 2 (Foxy, Galactic, Humble, Iron, Rolling, and beyond) - written in C++ - that work with mosaic and AsteRx - two of Septentrio’s cutting-edge GNSS and GNSS/INS receiver families - and beyond. Both ROS 1 and ROS 2 are supported within one repository.

Main Features:

  • Supports Septentrio’s single antenna GNSS, dual antenna GNSS and INS receivers

  • Supports serial, TCP/IP and USB connections, the latter being compatible with both serial (RNDIS) and TCP/IP protocols

  • Supports several ASCII (including key NMEA ones) messages and SBF (Septentrio Binary Format) blocks

  • Reports status of AIM+ (Advanced Interference Mitigation including OSNMA) anti-jamming and anti-spoofing.

  • Can publish nav_msgs/Odometry message for INS receivers

  • Can blend SBF blocks PVTGeodetic, PosCovGeodetic, ChannelStatus, MeasEpoch, AttEuler, AttCovEuler, VelCovGeodetic and DOP in order to publish gps_common/GPSFix and sensor_msgs/NavSatFix messages

  • Supports optional axis convention conversion since Septentrio follows the NED convention, whereas ROS is ENU.

  • Easy configuration of multiple RTK corrections simultaneously (via NTRIP, TCP/IP stream, or serial)

  • Can play back PCAP capture logs for testing purposes

  • Tested with the mosaic-X5, mosaic-H, AsteRx-m3 Pro+, AsteRx-SB Pro+ and the AsteRx-SBi3 Pro receiver

  • Easy to add support for more log types

Please let the maintainers know of your success or failure in using the driver with other devices so we can update this page appropriately.

Usage

Important notes

Notes Before Usage
  • The driver assumes that our anonymous access to the Rx grants us full control rights. This should be the case by default, and can otherwise be changed with the setDefaultAccessLevel command. If user control is in place user credentials can be given by parameters login.user and login.password.

  • Note for serial connection: Make sure the user is part of the dialout group to have full access to the serial ports. If not, add it for example with sudo adduser [username] dialout.

  • Note for setting hw_flow_control: This is a string parameter, setting it to off without quotes leads to the fact that it is not read in correctly.

  • Note for setting ant_(aux1)_serial_nr: This is a string parameter, numeric only serial numbers should be put in quotes. If this is not done a warning will be issued and the driver tries to parse it as integer.

  • Note for usage of NTRIP via USB with virtual ethernet (RNDIS): RNDIS provides a virtual network connection only between the receiver and the PC. First outgoing network access via USB has to be activated, which is explained here. Next setup internet sharing under Linux by setting the connection of the virtual network interface (the name should be something like enx1a3202991545) to “Shared to other computers”.

  • Once the build or binary installation is finished, adapt the config/rover.yaml file according to your needs or assemble a new one, examples for GNSS specific parameters config/gnss.yaml and INS config/ins.yaml are also available. Specify the communication parameters, the ROS messages to be published, the frequency at which the latter should happen etc.
    ROS 1: Launch the launch/rover.launch to use rover.yaml or add param_file_name:=xxx to use a custom config.
    ROS 2: Launch as composition with ros2 launch septentrio_gnss_driver rover.launch.py to use rover.yaml or add file_name:=xxx.yaml to use a custom config. Alternatively launch as node with ros2 launch septentrio_gnss_driver rover_node.launch.py to use rover_node.yaml or add file_name:=xxx.yaml to use a custom config. Specify the communication parameters, the ROS messages to be published, the frequency at which the latter should happen etc.

  • Besides the aforementioned config file rover.yaml containing all parameters, specialized launch files for GNSS config/gnss.yaml and INS config/ins.yaml respectively contain only the relevant parameters in each case.

  • NOTE: Unless configure_rx is set to false, this driver will overwrite the previous values of the parameters, even if the value is left to zero in the “yaml” file.

  • The driver was developed and tested with firmware versions >= 4.10.0 for GNSS and >= 1.3.2 for INS. Receivers with older firmware versions are supported but some features may not be available. Known limitations are:

    • GNSS with firmware < 4.10.0 does not support IP over USB.

    • GNSS with firmware < 4.12.1 does not support OSNMA.

    • GNSS with firmware < 4.14 does not support PTP server clock.

    • INS with firmware <= 1.2.0 does not support velocity aiding.

    • INS with firmware <= 1.2.0 does not support setting of initial heading.

    • INS with firmware < 1.3.2 does not support NTP.

    • INS with firmware < 1.4 does not support OSNMA.

    • INS with firmware < 1.4.1 does not support improved VSM handling allowing for unknown variances.

    • INS does not support PTP server clock as of now.

  • Known issues:

    • UDP over USB: Blocks are sent twice on GNSS with firmware <= 4.12.1 and INS with firmware <= 1.4. For GNSS it is fixed in version 4.14 (released on June 15th 2023), for INS is fixed in 1.4.1 (released November 2023).

  • If use_ros_axis_orientation to true axis orientations are converted by the driver between NED (Septentrio: yaw = 0 is north, positive clockwise) and ENU (ROS: yaw = 0 is east, positive counterclockwise). There is no conversion when setting this parameter to false and the angles will be consistent with the web GUI in this case. :

# Example configuration Settings for the Rover Rx

device: tcp://192.168.3.1:28784

serial:
  baudrate: 921600
  hw_flow_control: "off"

stream_device:
  tcp:
    ip_server: ""
    port: 0
  udp:
    ip_server: ""
    port: 0
    unicast_ip: ""

configure_rx: true

custom_commands_file: ""

login:
  user: ""
  password: ""

osnma:
  mode: "off"
  ntp_server: ""
  keep_open: true

frame_id: gnss

imu_frame_id: imu

poi_frame_id: base_link

vsm_frame_id: vsm

aux1_frame_id: aux1

vehicle_frame_id: base_link

insert_local_frame: false

local_frame_id: odom

get_spatial_config_from_tf: true

lock_utm_zone: true

use_ros_axis_orientation: true

receiver_type: gnss

datum: Default

poi_to_arp:
  delta_e: 0.0
  delta_n: 0.0
  delta_u: 0.0

att_offset:
  heading: 0.0
  pitch: 0.0

ant_type: Unknown
ant_aux1_type: Unknown
ant_serial_nr: Unknown
ant_aux1_serial_nr: Unknown

leap_seconds: 18

polling_period:
  pvt: 500
  rest: 500

use_gnss_time: false
ntp_server: false
ptp_server_clock: false
latency_compensation: false

rtk_settings:
  ntrip_1:
    id: "NTR1"
    caster: "1.2.3.4"
    caster_port: 2101
    username: "Asterix"
    password: "password"
    mountpoint: "mtpt1"
    version: "v2"
    tls: true
    fingerprint: "AA:BB:56:78:90:12: ... 78:90:12:34"
    rtk_standard: "RTCMv3"
    send_gga: "auto"
    keep_open: true
  ntrip_2:
    id: "NTR3"
    caster: "5.6.7.8"
    caster_port: 2101
    username: "Obelix"
    password: "password"
    mountpoint: "mtpt2"
    version: "v2"
    tls: false
    fingerprint: ""
    rtk_standard: "RTCMv2"
    send_gga: "auto"
    keep_open: true
  ip_server_1:
    id: "IPS3"
    port: 28785
    rtk_standard: "RTCMv2"
    send_gga: "auto"
    keep_open: true
  ip_server_2:
    id: "IPS5"
    port: 28786
    rtk_standard: "CMRv2"
    send_gga: "auto"
    keep_open: true
  serial_1:
    port: "COM1"
    baud_rate: 230400
    rtk_standard: "auto"
    send_gga: "sec1"
    keep_open: true
  serial_2:
    port: "COM2"
    baud_rate: 230400
    rtk_standard: "auto"
    send_gga: "off"
    keep_open: true

publish:
  # For both GNSS and INS Rxs
  auto_publish: false
  publish_only_valid: false
        navsatfix: false
  gpsfix: true
  gpgga: false
  gprmc: false
  gpst: false
  measepoch: false
  pvtcartesian: false
  pvtgeodetic: true
  basevectorcart: false
  basevectorgeod: false
  poscovcartesian: false
  poscovgeodetic: true
  velcovcartesian: false
        velcovgeodetic: false
  atteuler: true
  attcoveuler: true
  pose: false
  twist: false
  diagnostics: false
  aimplusstatus: true
  galauthstatus: false
  # For GNSS Rx only
  gpgsa: false
  gpgsv: false
  # For INS Rx only
  insnavcart: false
  insnavgeod: false
  extsensormeas: false
  imusetup: false
  velsensorsetup: false
  exteventinsnavcart: false
  exteventinsnavgeod: false
  imu: false
  localization: false
  tf: false
  localization_ecef: false
  tf_ecef: false

# INS-Specific Parameters

ins_spatial_config:
  imu_orientation:
    theta_x: 0.0
    theta_y: 0.0
    theta_z: 0.0
  poi_lever_arm:
    delta_x: 0.0
    delta_y: 0.0
    delta_z: 0.0
  ant_lever_arm:
    x: 0.0
    y: 0.0
    z: 0.0
  vsm_lever_arm:
    vsm_x: 0.0
    vsm_y: 0.0
    vsm_z: 0.0

ins_initial_heading: auto

ins_std_dev_mask:
  att_std_dev: 5.0
  pos_std_dev: 10.0

ins_use_poi: true

ins_vsm:
  source: "twist"
  config: [true, false, false]
  variances_by_parameter: true
  variances: [0.1, 0.0, 0.0]
  ip_server:
    id: "IPS2"
    port: 28787
    keep_open: true
  serial:
    port: "COM3"
    baud_rate: 115200
    keep_open: true

# Logger

activate_debug_log: false

In order to launch ROSaic, the launch command for ROS 1 reads roslaunch septentrio_gnss_driver rover.launch param_file_name:=rover and for ROS 2 reads ros2 launch septentrio_gnss_driver rover.py file_name:=rover.yaml. If multiple port are utilized for RTK corrections and/or VSM, which shall be closed after driver shutdown (keep_open: false), make sure to give the driver enough time to gracefully shutdown as closing the ports takes a few seconds. For ROS 2, this can be accomplished in the launch files by increasing the timeout of SIGTERM (e.g. sigterm_timeout = '10',), see example launch filesrover.launch.pyand rover_node.launch.py respectively.

Dependencies

ROS This driver functions on ROS 1 [Melodic](https://wiki.ros.org/melodic/Installation/Ubuntu) and [Noetic](https://wiki.ros.org/noetic/Installation/Ubuntu) or ROS 2 [Foxy](https://docs.ros.org/en/foxy/Installation.html), [Galactic](https://docs.ros.org/en/galactic/Installation.html), [Humble](https://docs.ros.org/en/humble/Installation.html) [Iron](https://docs.ros.org/en/iron/Installation.html), [Jazzy](https://docs.ros.org/en/jazzy/Installation.html), and [Rolling](https://docs.ros.org/en/rolling/Installation.html) (Ubuntu 18.04, 20.04, 22.04, or 24.04 respectively). It is thus necessary to install the ROS version that has been designed for your Linux distro.

Installation via apt

Binary Install

The binary release is available for ROS 1 (Melodic and Noetic) and ROS 2 (Foxy, Galactic, Humble, Iron, Jazzy, and Rolling). Since Melodic, Foxy, and Galactic are EOL, only Noetic, Humble, Iron, Jazzy, and Rolling will get updated versions. To install the binary package, simply run sudo apt-get install ros-$ROS_DISTRO-septentrio-gnss-driver.

Build from source

Build
  • Building ROSaic only works from C++17 onwards due to the usage of std::any() etc.

Dependencies for development

Additional ROS packages have to be installed for the NMEA and GPSFix messages.

ROS 1: sudo apt install ros-$ROS_DISTRO-nmea-msgs ros-$ROS_DISTRO-gps-common.

ROS 2: sudo apt install ros-$ROS_DISTRO-nmea-msgs ros-$ROS_DISTRO-gps-msgs.

The serial and TCP/IP communication interface of the ROS driver is established by means of the Boost C++ library. In the unlikely event that the below installation instructions fail to install Boost on the fly, please install the Boost libraries via

sudo apt install libboost-all-dev.

Conversions from LLA to UTM are incorporated through GeographicLib. Install the necessary headers via

sudo apt install libgeographic-dev

or

sudo apt install libgeographiclib-dev

since Ubunutu 24.04. respectively.

Compatiblity with PCAP captures are incorporated through pcap libraries. Install the necessary headers via

sudo apt install libpcap-dev.

ROS 1

For ROS 1, the package can be built from source using catkin_tools, where the latter can be installed using the command sudo apt-get install python-catkin-tools for Melodic or sudo apt-get install python3-catkin-tools for Noetic. The typical catkin_tools workflow should suffice:

source /opt/ros/${ROS_DISTRO}/setup.bash                            # In case you do not use the default shell of Ubuntu, you need to source another script, e.g. setup.sh.
mkdir -p ~/septentrio/src                                           # Note: Change accordingly depending on where you want your package to be installed.
cd ~/septentrio
catkin init                                                         # Initialize with a hidden marker file
catkin config --cmake-args -DCMAKE_BUILD_TYPE=RelWithDebInfo        # CMake build types pass compiler-specific flags to your compiler. This type amounts to a release with debug info, while keeping debugging symbols and doing optimization. I.e. for GCC the flags would be -O2, -g and -DNDEBUG.
cd src
git clone https://github.com/septentrio-gnss/septentrio_gnss_driver
rosdep install . --from-paths -i                                    # Might raise "rosaic: Unsupported OS [mint]" warning, if your OS is Linux Mint, since rosdep does not know Mint (and possible other OSes). In that case, add the "--os=ubuntu:saucy" option to "fool" rosdep into believing it faces some Ubuntu version. The syntax is "--os=OS_NAME:OS_VERSION".
catkin build                                                        # If catkin cannot find empty, tell catkin to use Python 3 by adding "-DPYTHON_EXECUTABLE=/usr/bin/python3".
echo "source ~/septentrio/devel/setup.bash" >> ~/.bashrc            # It is convenient if the ROS environment variable is automatically added to your bash session every time a new shell is launched. Again, this works for bash shells only. Also note that if you have more than one ROS distribution installed, ~/.bashrc must only source the setup.bash for the version you are currently using.
source ~/.bashrc
ROS 2

For ROS 2, The package has to be built from source using colcon:

source /opt/ros/${ROS_DISTRO}/setup.bash                            # In case you do not use the default shell of Ubuntu, you need to source another script, e.g. setup.sh.
mkdir -p ~/septentrio/src                                           # Note: Change accordingly depending on where you want your package to be installed.
cd ~/septentrio/src
git clone https://github.com/septentrio-gnss/septentrio_gnss_driver
git checkout ros2                                                   # Install mentioned dependencies (`sudo apt install ros-$ROS_DISTRO-nmea_msgs ros-$ROS_DISTRO-gps-msgs libboost-all-dev libpcap-dev libgeographic-dev`)
colcon build --packages-up-to septentrio_gnss_driver                # Be sure to call colcon build in the root folder of your workspace. Launch files are installed, so changing them on the fly in the source folder only works with installing by symlinks: add `--symlink-install`
echo "source ~/septentrio/devel/setup.bash" >> ~/.bashrc            # It is convenient if the ROS environment variable is automatically added to your bash session every time a new shell is launched. Again, this works for bash shells only. Also note that if you have more than one ROS distribution installed, ~/.bashrc must only source the setup.bash for the version you are currently using.
source ~/.bashrc

Run tests

colcon test --packages-select septentrio_gnss_driver --event-handlers console_direct+

Inertial Navigation System (INS): Basics

  • An Inertial Navigation System (INS) is a device which takes the rotation and acceleration solutions as obtained from its Inertial Measurement Unit (IMU) and combines those with position and velocity information from the GNSS module. Compared to a GNSS system with 7D or 8D (dual-antenna systems) phase space solutions, the combined, Kalman-filtered 9D phase space solution (3 for position, 3 for velocity, 3 for orientation) of an INS is more accurate, more precise and more stable against GNSS outages.

  • The IMU is typically made up of a 3-axis accelerometer, a 3-axis gyroscope and sometimes a 3-axis magnetometer and measures the system’s angular rate and acceleration.

    Measure and Compensate for IMU-Antenna Lever Arm
    • The IMU-antenna lever-arm is the relative position between the IMU reference point and the GNSS Antenna Reference Point (ARP), measured in the vehicle frame.

    • In case of AsteRx SBi3, the IMU reference point is clearly marked on the top panel of the receiver. It is important to compensate for the effect of the lever arm, otherwise the receiver may not be able to calculate an accurate INS position.

    • The IMU/antenna position can be changed by specifying the lever arm’s x,yand z parameters in the config.yaml file under the ins_spatial_config.ant_lever_arm parameter.

      Screenshot from 2021-08-03 09-23-19 (1)

    Compensate for IMU Orientation
    • It is important to take into consideration the mounting direction of the IMU in the body frame of the vehicle. For e.g. when the receiver is installed horizontally with the front panel facing the direction of travel, we must compensate for the IMU’s orientation to make sure the IMU reference frame is aligned with the vehicle reference frame. The IMU position and orientation is printed on the top panel, cf. image below.

    • The IMU’s orientation can be changed by specifying the orientation angles theta_x,theta_yand theta_z in the config.yaml file under ins_spatial_config.imu_orientation

    • The below image illustrates the orientation of the IMU reference frame with the associated IMU orientation for the depicted installation. Note that for use_ros_axis_orientation: true sensor_default is the top left position.

    Capture (1)

  • These Steps should be followed to configure the receiver in INS integration mode:

    • Specify receiver_type: INS

    • Specify the orientation of the IMU sensor with respect to your vehicle, using the ins_spatial_config.imu_orientation parameter.

    • Specify the IMU-antenna lever arm in the vehicle reference frame. This is the vector starting from the IMU reference point to the ARP of the main GNSS antenna. This can be done by means of the ins_spatial_config.ant_lever_arm parameter.

    • Specify ins_spatial_config.vsm_lever_arm if measurements of a velocity sensor is available.

    • Alternatively the lever arms may be specified via tf. Set get_spatial_config_from_tfto true in this case.

    • If the point of interest is neither the IMU nor the ARP of the main GNSS antenna, the vector between the IMU and the point of interest can be provided with the ins_solution/poi_lever_arm parameter.

  • For further more information about Septentrio receivers, visit Septentrio support resources or check out the user manual and reference guide of the AsteRx SBi3 receiver.

ROSaic Parameters

The following is a list of ROSaic parameters found in the config/rover.yaml file. Note, that in the following nested parameters are depicted in ROS 2 style, i.e., using a . as delimiter, whereas in ROS 1 the delimiter is a /.

  • Parameters Configuring Communication Ports and Processing of GNSS and INS Data

    Connectivity Specs
    • device: location of main device connection. This interface will be used for setup communication and VSM data for INS. Incoming data streams of SBF blocks and NMEA sentences are recevied either via this interface or a static IP server for TCP and/or UDP. The former will be utilized if section stream_device.tcp and stream_device.udp are not configured.

      • serial:xxx format for serial connections,where xxx is the device node, e.g. serial:/dev/ttyS0. If using serial over USB, it is recommended to specify the port by ID as the Rx may get a different ttyXXX on reconnection, e.g. serial:/dev/serial/by-id/usb-Septentrio_Septentrio_USB_Device_xyz.

      • file_name:path/to/file.sbf format for publishing from an SBF log. When reading from a file, use_gnss_time is automatically set to true, since constructing the time stamps from ROS time would not match the data. If the sbf log does not contain ReceiverTime, parameterleap_seconds must be set manually.

      • file_name:path/to/file.pcap format for publishing from PCAP capture. When reading from a file, use_gnss_time is automatically set to true, since constructing the time stamps from ROS time would not match the data. If the pcap log does not contain ReceiverTime, parameterleap_seconds must be set manually.

        • Regarding the file path, ROS_HOME=`pwd` in front of roslaunch septentrio... might be useful to specify that the node should be started using the executable’s directory as its working-directory.

      • tcp://host:port format for TCP/IP connections

        • 28784 should be used as the default (command) port for TCP/IP connections. If another port is specified, the receiver needs to be (re-)configured via the Web Interface before ROSaic can be used.

        • An RNDIS IP interface is provided via USB, assigning the address 192.168.3.1 to the receiver. This should work on most modern Linux distributions. To verify successful connection, open a web browser to access the web interface of the receiver using the IP address 192.168.3.1.

      • default: tcp://192.168.3.1:28784

    • serial: specifications for serial communication

      • baudrate: serial baud rate to be used in a serial connection. Ensure the provided rate is sufficient for the chosen SBF blocks. For example, activating MeasEpoch (also necessary for /gpsfix) may require up to almost 400 kBit/s.

      • rx_serial_port: determines to which (virtual) serial port of the Rx we want to get connected to, e.g. USB1 or COM1

      • hw_flow_control: specifies whether the serial (the Rx’s COM ports, not USB1 or USB2) connection to the Rx should have UART hardware flow control enabled or not

        • off to disable UART hardware flow control, RTS|CTS to enable it

      • default: 921600, USB1, off

    • stream_device: If left unconfigured, by default device is utilized for the data streams. Within stream_device static IP servers may be defined instead. In config mode (configure_rx set to true), TCP will be prioritized over UDP. If Rx is pre-configured, both may be set simultaneously.

      • tcp: specifications for static TCP server of SBF blocks and NMEA sentences.

        • ip_server: IP server of Rx to be used, e.g. “IPS1”.

        • port: UDP destination port.

      • udp: specifications for low latency UDP reception of SBF blocks and NMEA sentences.

        • ip_server: IP server of Rx to be used, e.g. “IPS1”.

        • port: UDP destination port.

        • unicast_ip: Set to computer’s IP to use unicast (optional). If not set multicast will be used.

    • login: credentials for user authentication to perform actions not allowed to anonymous users. Leave empty for anonymous access.

      • user: user name

      • password: password

    • custom_commands_file: path to a file containing custom commands to be sent to the Rx. The file shall contain one command per line. Be very careful using this command, since commands are sent to the Rx without further checks.

    OSNMA
    • osnma: Configuration of the Open Service Navigation Message Authentication (OSNMA) feature.

      • mode: Three operating modes are supported: off where OSNMA authentication is disabled, loose where satellites are included in the PVT if they are successfully authenticated or if their authentication status is unknown, and strict where only successfully-authenticated satellites are included in the PVT. In case of strict synchronization via NTP is mandatory.

        • default: off

      • ntp_server: In strict mode, OSNMA authentication requires the availability of external time information. In loose mode, this is optional but recommended for enhanced security. The receiver can connect to an NTP time server for this purpose. Options are default to let the receiver choose an NTP server or specify one like pool.ntp.org for example.

        • default: “”

      • keep_open: Wether OSNMA shall be kept active on driver shutdown.

        • default: true

    Receiver Configuration
    • configure_rx: Wether to configure the Rx according to the config file. If set to false, the Rx has to be configured via the web interface and the settings must be saved. On the driver side communication has to set accordingly to serial, TCP or UDP (TCP and UDP may even be used simultaneously in this case). For TCP communication it is recommended to use a static TCP server (stream_device.tcp.ip_server and stream_device.tcp.port), since dynamic connections (device is tcp) are not guaranteed to have the same id on reconnection. It should also be ensured that obligatory SBF blocks are activated (as of now: ReceiverTime if use_gnss_time is set to true; PVTGeodeticor PVTCartesian if latency compensation for PVT related blocks shall be used). Further, if ROS messages compiled from multiple SBF blocks, it should be ensured that all necessary blocks are activated with matching periods, details can be found in section ROS Topic Publications. The messages that shall be published still have to be set to true in the NMEA/SBF Messages to be Published section. Also, parameters concerning the connection and node setup are still relevant (sections: Connectivity Specs, receiver type, Frame IDs, UTM Zone Locking, Time Systems, Logger).

      • default: true

    Receiver Type
    • receiver_type: This parameter is to select the type of the Septentrio receiver

      • gnss for GNSS receivers.

      • ins for INS receivers.

      • default: gnss

    • multi_antenna: Whether or not the Rx has multiple antennas.

      • default: false

    Frame IDs
    • frame_id: name of the ROS tf frame for the Rx, placed in the header of published GNSS messages. It corresponds to the frame of the main antenna.

      • In ROS, the tf package lets you keep track of multiple coordinate frames over time. The frame ID will be resolved by tf_prefix if defined. If a ROS message has a header (all of those we publish do), the frame ID can be found via rostopic echo /topic, where /topic is the topic into which the message is being published.

      • default: gnss

    • imu_frame_id: name of the ROS tf frame for the IMU, placed in the header of published IMU message

      • default: imu

    • poi_frame_id: name of the ROS tf frame for the POI, placed in the child frame_id of localization if ins_use_poi is set to true.

      • default: base_link

    • vsm_frame_id: name of the ROS tf frame for the velocity sensor.

      • default: vsm

    • aux1_frame_id: name of the ROS tf frame for the aux1 antenna.

      • default: aux1

    • vehicle_frame_id: name of the ROS tf frame for the vehicle. Default is the same as poi_frame_id but may be set otherwise.

      • default: base_link

    • local_frame_id: name of the ROS tf frame for the local frame.

      • default: odom

    • insert_local_frame: Wether to insert a local frame to published tf according to ROS REP 105. The transform from the local frame specified by local_frame_id to the vehicle frame specified by vehicle_frame_id has to be provided, e.g. by odometry. Insertion of the local frame means the transform between local frame and global frame is published instead of transform between vehicle frame and global frame.

      • default: false

    • get_spatial_config_from_tf: wether to get the spatial config via tf with the above mentioned frame ids. This will override spatial settings of the config file. For receiver type ins with multi_antenna set to true all frames have to be provided, with multi_antenna set to false, aux1_frame_id is not necessary. For type gnss with dual-antenna setup only frame_id, aux1_frame_id, and poi_frame_id are needed. For single-antenna gnss no frames are needed. Keep in mind that tf has a tree structure. Thus, poi_frame_id is the base for all mentioned frames.

      • default: false

    • use_ros_axis_orientation Wether to use ROS axis orientations according to ROS REP 103 for body related frames and geographic frames. Body frame directions affect INS lever arms and IMU orientation setup parameters. Geographic frame directions affect orientation Euler angles for INS+GNSS and attitude of dual-antenna GNSS. If use_ros_axis_orientation is set to true, the driver converts between the NED convention (Septentrio: yaw = 0 is north, positive clockwise), and ENU convention (ROS: yaw = 0 is east, positive counterclockwise). There is no conversion when setting this parameter to false and the angles will be consistent with the web GUI in this case.

      • If set to false Septentrios definition is used, i.e., front-right-down body related frames and NED (north-east-down) for orientation frames.

      • If set to true ROS definition is used, i.e., front-left-up body related frames and ENU (east-north-up) for orientation frames.

      • default: true

    UTM zone locking + `lock_utm_zone`: wether the UTM zone of the initial localization is locked, i.e., this zone is kept even if a zone transition would occur. + default: `true`
    Datum
    • datum: With this command, the datum the coordinates should refer to is selected. With setting it to Default, the datum depends on the positioning mode, e.g. WGS84 for standalone positioning.

      • Since the standardized GGA message does only provide the orthometric height (= MSL height = distance from Earth’s surface to geoid) and the geoid undulation (distance from geoid to ellipsoid) for which non-WGS84 datums cannot be specified, it does not affect the GGA message.

      • default: Default

    POI-ARP Offset
    • poi_to_arp: offsets of the main GNSS antenna reference point (ARP) with respect to the point of interest (POI = marker). Use for static receivers only.

    • The parameters delta_e, delta_n and delta_u are the offsets in the East, North and Up (ENU) directions respectively, expressed in meters.

    • All absolute positions reported by the receiver are POI positions, obtained by subtracting this offset from the ARP. The purpose is to take into account the fact that the antenna may not be located directly on the surveying POI.

    • default: 0.0, 0.0 and 0.0

    Antenna Attitude Offset
    • att_offset: Angular offset between two antennas (Main and Aux) and vehicle frame

    • heading: The perpendicular (azimuth) axis can be compensated for by adjusting the heading parameter

    • pitch: Vertical (elevation) offset can be compensated for by adjusting the pitch parameter

    • default: 0.0, 0.0 (degrees)

    Antenna Specs
    • ant_type: type of your main GNSS antenna

      • For best positional accuracy, it is recommended to select a type from the list returned by the command lstAntennaInfo, Overview. This is the list of antennas for which the receiver can compensate for phase center variation.

      • By default and if ant_type does not match any entry in the list returned by lstAntennaInfo, Overview, the receiver will assume that the phase center variation is zero at all elevations and frequency bands, and the position will not be as accurate.

      • default: Unknown

    • ant_serial_nr: serial number of your main GNSS antenna

    • ant_aux1_type and ant_aux1_serial_nr: same for Aux1 antenna

    Leap Seconds
    • leap_seconds: Leap seconds are automatically gathered from the receiver via the SBF block ReceiverTime. If a log file is used for simulation and this block was not recorded, the number of leap seconds that have been inserted up until the point of ROSaic usage can be set by this parameter.

      • At the time of writing the code (2020), the GPS time, which is unaffected by leap seconds, was ahead of UTC time by 18 leap seconds. Adapt the leap_seconds parameter accordingly as soon as the next leap second is inserted into the UTC time or in case you are using ROSaic for the purpose of simulations.

    Polling Periods
    • polling_period.pvt: desired period in milliseconds between the polling of two consecutive PVTGeodetic, PosCovGeodetic, PVTCartesian and PosCovCartesian blocks and - if published - between the publishing of two of the corresponding ROS messages (e.g. septentrio_gnss_driver/PVTGeodetic.msg). Consult firmware manual for allowed periods. If the period is set to a lower value than the receiver is capable of, it will be published with the next higher period. If set to 0, the SBF blocks are output at their natural renewal rate (OnChange).

    • polling_period.rest: desired period in milliseconds between the polling of all other SBF blocks and NMEA sentences not addressed by the previous parameter, and - if published - between the publishing of all other ROS messages

      • default: 500 (2 Hz)

    Time Systems
    • use_gnss_time: true if the ROS message headers’ unix epoch time field shall be constructed from the TOW/WNC (in the SBF case) and UTC (in the NMEA case) data, false if those times shall be taken by the driver from ROS time. If use_gnss_time is set to true, it is imperative that the ROS system is synchronized to an NTP time server or PTP clock either via internet or ideally via the Septentrio receiver since the latter serves as a Stratum 1 time server not dependent on an internet connection. If this is not followed, the time stamps may drift apart!

      • default: false

    • ntp_server: Wether the NTP server shall be activated.

      • default: false

    • ptp_server_clock: Wether the PTP server slcok hall be activated.

      • default: false

    • latency_compensation: Rx reports processing latency in PVT and INS blocks. If set to truethis latency is subtracted from ROS timestamps in related blocks (i.e., use_gnss_time set to false). Related blocks are INS, PVT, Covariances, and BaseVectors. In case of use_gnss_time set to true, the latency is already compensated within the RX and included in the reported timestamps.

      • default: false

    RTK corrections
    • rtk_settings: determines RTK connection parameters

      • There are multiple possibilities to feed RTK corrections to the Rx. They may be set simultaneously and the Rx will choose the nearest source.

        • a) ntrip_# if the Rx has internet access and is able to receieve NTRIP streams from a caster. Up to three NTRIP connections are possible.

        • b) ip_server_# if corrections are to be receieved via TCP/IP for example over Data Link from Septentrio’s RxTools is installed on a computer. Up to five IP server connections are possible.

        • c) serial_# if corrections are to be receieved via a serial port for example over radio link from a local RTK base or over Data Link from Septentrio’s RxTools installed on a computer. Up to five serial connections are possible.

      • ntrip_#: for receiving corretions from an NTRIP caster (# is from 1 … 3).

        • id: NTRIP connection NTR1, NTR2, or NTR3.

          • default: “”

        • caster: is the hostname or IP address of the NTRIP caster to connect to.

          • default: “”

        • caster_port: IP port of the NTRIP caster.

          • default: 2021

        • username: user name for the NTRIP caster.

          • default: “”

        • pasword: password for the NTRIP caster. The receiver encrypts the password so that it cannot be read back with the command “getNtripSettings”.

          • default: “”

        • mountpoint: mount point of the NTRP caster to be used.

          • default: “”

        • version: argument specifies which version of the NTRIP protocol to use (v1 or v2).

          • default: “v2”

        • tls: determines wether to use TLS.

          • default: false

        • fingerprint: fingerprint to be used if the certificate is self-signed. If the caster’s certificate is known by a publicly-trusted certification authority, fingerprint should be left empty.

          • default: “”

        • rtk_standard: determines the RTK standard, options are auto, RTCMv2, RTCMv3, or CMRv2.

          • default: “auto”

        • send_gga: specifies whether or not to send NMEA GGA messages to the NTRIP caster, and at which rate. It must be one of auto, off, sec1, sec5, sec10 or sec60. In auto mode, the receiver automatically sends GGA messages if requested by the caster.

          • default: “auto”

        • keep_open: determines wether this connection shall be kept open. If set to true the Rx will still be able to receive RTK corrections to improve precision after driver is shut down.

          • default: true

      • ip_server_#: for receiving corretions via TCP/IP (# is from 1 … 5).

        • id: specifies the IP server IPS1, IPS2, IPS3, IPS4, or IPS5. Note that ROSaic will send GGA messages on this connection if send_gga is set, such that in the Data Link application of RxTools one just needs to set up a TCP client to the host name as found in the ROSaic parameter device with the port as found in port. If the latter connection were connection 1 on Data Link, then connection 2 would set up an NTRIP client connecting to the NTRIP caster as specified in the above parameters in order to forward the corrections from connection 2 to connection 1.

          • default: “”

        • port: its port number of the connection that ROSaic establishes on the receiver. When selecting a port number, make sure to avoid conflicts with other services.

          • default: 0

        • rtk_standard: determines the RTK standard, options are auto, RTCMv2, RTCMv3, or CMRv2.

          • default: “”

        • send_gga: specifies whether or not to send NMEA GGA messages to the NTRIP caster, and at which rate. It must be one of auto, off, sec1, sec5, sec10 or sec60. In auto mode, the receiver sends with sec1.

          • default: “auto”

        • keep_open: determines wether this connection shall be kept open. If set to true the Rx will still be able to receive RTK corrections to improve precision after driver is shut down.

          • default: true

      • serial_#: for receiving corretions via serial connection (# is from 1 … 5).

        • port: Serial connection COM1, COM2, COM3, USB1, or USB2 on which corrections could be forwarded to the Rx from a serially connected radio link modem or via Data Link for example.

          • default: “”

        • baud_rate: sets the baud rate of this port for genuine serial ports, i.e., not relevant for USB connection.

          • default: 115200

        • rtk_standard: determines the RTK standard, options are auto, RTCMv2, RTCMv3, or CMRv2.

          • default: “auto”

        • send_gga: specifies whether or not to send NMEA GGA messages to the NTRIP caster, and at which rate. It must be one of auto, off, sec1, sec5, sec10 or sec60. In auto mode, the receiver sends with sec1.

          • default: “auto”

        • keep_open: determines wether this connection shall be kept open. If set to true the Rx will still be able to receive RTK corrections to improve precision after driver is shut down.

          • default: true

    INS Specs
    • ins_spatial_config: Spatial configuration of INS/IMU. Coordinates according to vehicle related frame directions chosen by use_ros_axis_orientation (front-left-up if true and front-right-down if false).

      • imu_orientation: IMU sensor orientation

        • Parameters theta_x, theta_y and theta_z are used to determine the sensor orientation with respect to the vehicle frame. Positive angles correspond to a right-handed (clockwise) rotation of the IMU with respect to its nominal orientation (see below). The order of the rotations is as follows: theta_z first, then theta_y, then theta_x.

        • The nominal orientation is where the IMU is upside down and with the X axis marked on the receiver pointing to the front of the vehicle. By contrast, for use_ros_axis_orientation: true, nominal orientation is where the Z axis of the IMU is pointing upwards and also with the X axis marked on the receiver pointing to the front of the vehicle.

        • default: 0.0, 0.0, 0.0 (degrees)

      • poi_lever_arm: The lever arm from the IMU reference point to a user-defined POI

        • Parameters delta_x,delta_y and delta_z refer to the vehicle reference frame

        • default: 0.0, 0.0, 0.0 (meters)

      • ant_lever_arm: The lever arm from the IMU reference point to the main GNSS antenna

        • The parameters x,y and z refer to the vehicle reference frame

        • default: 0.0, 0.0, 0.0 (meters)

      • vsm_lever_arm: The lever arm from the IMU reference point to the velocity sensor

        • The parameters vsm_x,vsm_y and vsm_z refer to the vehicle reference frame

        • default: 0.0, 0.0, 0.0 (meters)

    • ins_initial_heading: How the receiver obtains the initial INS/GNSS integrated heading during the alignment phase

      • In case it is auto, the initial integrated heading is determined from GNSS measurements.

      • In case it is stored, the last known heading when the vehicle stopped before switching off the receiver is used as initial heading. Use if vehicle does not move when the receiver is switched off.

      • default: auto

    • ins_std_dev_mask: Maximum accepted error

      • att_std_dev: Configures an output limit on standard deviation of the attitude angles (max error accepted: 5 degrees)

      • pos_std_dev: Configures an output limit on standard deviation of the position (max error accepted: 100 meters)

      • default: 5 degrees, 10 meters

    • ins_use_poi: Whether or not to use the POI defined in ins_spatial_config.poi_lever_arm

      • If true, the point at which the INS navigation solution (e.g. in insnavgeod ROS topic) is calculated will be the POI as defined above (poi_frame_id), otherwise it’ll be the main GNSS antenna (frame_id). Has to be set to true if tf shall be published.

      • default: true

    • ins_vsm: Configuration of the velocity sensor measurements. IP server may be used to receive velocity information from ROS or from an external device. Serial connection may be used to receive velocity information from an external device only.

      • ros: VSM info received from ROS msgs

        • source: Specifies which ROS message type shall be used, options are odometry or twist. Accordingly, a subscriber is established of the type nav_msgs/Odometry.msg or geometry_msgs/TwistWithCovarianceStamped.msg listening on the topics odometry_vsm or twist_vsm respectively. Only linear velocities are evaluated. Measurements have to be with respect to the frame aligned with the vehicle and defined by ins_spatial_config.vsm_lever_arm or tf-frame vsm_frame_id, see also comment in nav_msgs/Odometry.msg that twist should be specified in child_frame_id.

          • default: “”

        • config: Defines which measurements belonging to the respective axes are forwarded to the INS. In addition, non-holonomic constraints may be introduced for directions known to be restricted in movement. For example, a vehicle with Ackermann steering is limited in its sidewards and upwards movement. So, even if only motion in x-direction may be measured, zero-velocities for y and z may be sent. Only has to be set if ins_vsm.ros.sourceis set to odometry or twist.

          • default: []

        • variances_by_parameter: Wether variances shall be entered by parameter ins_vsm.ros.variances or the values from inside the ROS messages are used. Only has to be set if ins_vsm.sourceis set to odometry or twist.

          • default: false

        • variances: Variances of the respective axes. Only have to be set if ins_vsm.variances_by_parameter is set to true. Values must be > 0.0, else measurements cannot not be used.

          • default: []

      • ip_server:

        • id: IP server to receive the VSM info (e.g. IPS1). If a TCP stream device (device.stream_device.tcp) is set up, this device may be used here, i.e, id my be set to the same.

          • default: “IPS5”

        • port: TCP port to receive the VSM info. When selecting a port number, make sure to avoid conflicts with other services.

          • default: 24786

        • keep_open determines wether this connections to receive VSM shall be kept open on driver shutdown. If set to true the Rx will still be able to use external VSM info to improve its localization.

          • default: true

      • serial:

        • port: Serial port to receive the VSM info.

          • default: “”

        • baud_rate: Baud rate of the serial port to receive the VSM info.

          • default: 115200

        • keep_open determines wether this connections to receive VSM shall be kept open on driver shutdown. If set to true the Rx will still be able to use external VSM info to improve its localization.

          • default: true

    Logger
    • activate_debug_log: true if ROS logger level shall be set to debug.

  • Parameters Configuring (Non-)Publishing of ROS Messages

    NMEA/SBF Messages to be Published
    • publish.auto_publish: true to automatically publish messages for which SBF blocks and NMEA sentences are available. Only applicable if conigure_rx is false. If tf_ecef shall be published, this must be explicitily set to true, else tf in UTM is published if available.

    • publish.publish_only_valid: true to publish SBF blocks only if timestamp (TOW) is valid.

    • publish.gpgga: true to publish nmea_msgs/GPGGA.msg messages into the topic /gpgga

    • publish.gprmc: true to publish nmea_msgs/GPRMC.msg messages into the topic /gprmc

    • publish.gpgsa: true to publish nmea_msgs/GPGSA.msg messages into the topic /gpgsa

    • publish.gpgsv: true to publish nmea_msgs/GPGSV.msg messages into the topic /gpgsv

    • publish.measepoch: true to publish septentrio_gnss_driver/MeasEpoch.msg messages into the topic /measepoch

    • publish.galauthstatus: true to publish septentrio_gnss_driver/GALAuthStatus.msg messages into the topic /galauthstatus and corresponding /diganostics

    • publish.aimplusstatus: true to publish septentrio_gnss_driver/RFStatus.msg messages into the topic /rfstatus, septentrio_gnss_driver/AIMPlusStatus.msg messages into /aimplusstatus and corresponding /diganostics. Some information is only available with active OSNMA.

    • publish.pvtcartesian: true to publish septentrio_gnss_driver/PVTCartesian.msg messages into the topic /pvtcartesian

    • publish.pvtgeodetic: true to publish septentrio_gnss_driver/PVTGeodetic.msg messages into the topic /pvtgeodetic

    • publish.basevectorcart: true to publish septentrio_gnss_driver/BaseVectorCart.msg messages into the topic /basevectorcart

    • publish.basevectorgeod: true to publish septentrio_gnss_driver/BaseVectorGeod.msg messages into the topic /basevectorgeod

    • publish.poscovcartesian: true to publish septentrio_gnss_driver/PosCovCartesian.msg messages into the topic /poscovcartesian

    • publish.poscovgeodetic: true to publish septentrio_gnss_driver/PosCovGeodetic.msg messages into the topic /poscovgeodetic

    • publish.velcovcartesian: true to publish septentrio_gnss_driver/VelCovCartesian.msg messages into the topic /velcovcartesian

    • publish.velcovgeodetic: true to publish septentrio_gnss_driver/VelCovGeodetic.msg messages into the topic /velcovgeodetic

    • publish.atteuler: true to publish septentrio_gnss_driver/AttEuler.msg messages into the topic /atteuler

    • publish.attcoveuler: true to publish septentrio_gnss_driver/AttCovEuler.msg messages into the topic /attcoveuler

    • publish.gpst: true to publish sensor_msgs/TimeReference.msg messages into the topic /gpst

    • publish.navsatfix: true to publish sensor_msgs/NavSatFix.msg messages into the topic /navsatfix

    • publish.gpsfix: true to publish gps_msgs/GPSFix.msg messages into the topic /gpsfix

    • publish.pose: true to publish geometry_msgs/PoseWithCovarianceStamped.msg messages into the topic /pose

    • publish.twist: true to publish geometry_msgs/TwistWithCovarianceStamped.msg messages into the topics /twist and /twist_ins respectively

    • publish.diagnostics: true to publish diagnostic_msgs/DiagnosticArray.msg messages into the topic /diagnostics

    • publish.insnavcart: true to publish septentrio_gnss_driver/INSNavCart.msg message into the topic/insnavcart

    • publish.insnavgeod: true to publish septentrio_gnss_driver/INSNavGeod.msg message into the topic/insnavgeod

    • publish.extsensormeas: true to publish septentrio_gnss_driver/ExtSensorMeas.msg message into the topic/extsensormeas

    • publish.imusetup: true to publish septentrio_gnss_driver/IMUSetup.msg message into the topic/imusetup

    • publish.velsensorsetup: true to publish septentrio_gnss_driver/VelSensorSetup.msgs message into the topic/velsensorsetup

    • publish.exteventinsnavcart: true to publish septentrio_gnss_driver/ExtEventINSNavCart.msgs message into the topic/exteventinsnavcart

    • publish.exteventinsnavgeod: true to publish septentrio_gnss_driver/ExtEventINSNavGeod.msgs message into the topic/exteventinsnavgeod

    • publish.imu: true to publish sensor_msgs/Imu.msg message into the topic/imu

    • publish.localization: true to publish nav_msgs/Odometry.msg message into the topic/localization

    • publish.tf: true to broadcast tf of localization. ins_use_poi must also be set to true to publish tf. Note that only one of publish.tf or publish.tf_ecef may be true.

    • publish.localization_ecef: true to publish nav_msgs/Odometry.msg message into the topic/localization related to ECEF frame.

    • publish.tf_ecef: true to broadcast tf of localization related to ECEF frame. ins_use_poi must also be set to true to publish tf. Note that only one of publish.tf or publish.tf_ecef may be true.

ROS Topic Publications

A selection of NMEA sentences, the majority being standardized sentences, and proprietary SBF blocks is translated into ROS messages, partly generic and partly custom, and can be published at the discretion of the user into the following ROS topics. All published ROS messages, even custom ones, start with a ROS generic header std_msgs/Header.msg, which includes the receiver time stamp as well as the frame ID, the latter being specified in the ROS parameter frame_id.

Available ROS Topics
  • /gpgga: publishes nmea_msgs/Gpgga.msg - converted from the NMEA sentence GGA.

  • /gprmc: publishes nmea_msgs/Gprmc.msg - converted from the NMEA sentence RMC.

  • /gpgsa: publishes nmea_msgs/Gpgsa.msg - converted from the NMEA sentence GSA.

  • /gpgsv: publishes nmea_msgs/Gpgsv.msg - converted from the NMEA sentence GSV.

  • /measepoch: publishes custom ROS message septentrio_gnss_driver/MeasEpoch.msg, corresponding to the SBF block MeasEpoch.

  • /galauthstatus: publishes custom ROS message septentrio_gnss_driver/GALAuthStatus.msg, corresponding to the SBF block GALAuthStatus.

  • /rfstatus: publishes custom ROS message septentrio_gnss_driver/RFStatus.msg, compiled from the SBF block RFStatus.

  • /aimplusstatus: publishes custom ROS message septentrio_gnss_driver/AIMPlusStatus.msg, reporting status of AIM+. Converted from SBF blocks RFStatus and optionally GALAuthStatus. For the latter OSNMA has to be activated.

  • /pvtcartesian: publishes custom ROS message septentrio_gnss_driver/PVTCartesian.msg, corresponding to the SBF block PVTCartesian (GNSS case) or INSNavGeod (INS case).

  • /pvtgeodetic: publishes custom ROS message septentrio_gnss_driver/PVTGeodetic.msg, corresponding to the SBF block PVTGeodetic (GNSS case) or INSNavGeod (INS case).

  • /basevectorcart: publishes custom ROS message septentrio_gnss_driver/BaseVectorCart.msg, corresponding to the SBF block BaseVectorCart.

  • /basevectorgeod: publishes custom ROS message septentrio_gnss_driver/BaseVectorGeod.msg, corresponding to the SBF block BaseVectorGeod.

  • /poscovcartesian: publishes custom ROS message septentrio_gnss_driver/PosCovCartesian.msg, corresponding to SBF block PosCovCartesian (GNSS case) or INSNavGeod (INS case).

  • /poscovgeodetic: publishes custom ROS message septentrio_gnss_driver/PosCovGeodetic.msg, corresponding to SBF block PosCovGeodetic (GNSS case) or INSNavGeod (INS case).

  • /velcovcartesian: publishes custom ROS message septentrio_gnss_driver/VelCovCartesian.msg, corresponding to SBF block VelCovCartesian (GNSS case).

  • /velcovgeodetic: publishes custom ROS message septentrio_gnss_driver/VelCovGeodetic.msg, corresponding to SBF block VelCovGeodetic (GNSS case).

  • /atteuler: publishes custom ROS message septentrio_gnss_driver/AttEuler.msg, corresponding to SBF block AttEuler.

  • /attcoveuler: publishes custom ROS message septentrio_gnss_driver/AttCovEuler.msg, corresponding to the SBF block AttCovEuler.

  • /gpst (for GPS Time): publishes generic ROS message sensor_msgs/TimeReference.msg, converted from the PVTGeodetic (GNSS case) or INSNavGeod (INS case) block’s GPS time information, stored in its block header.

  • /navsatfix: publishes generic ROS message sensor_msgs/NavSatFix.msg, converted from the SBF blocks PVTGeodetic,PosCovGeodetic (GNSS case) or INSNavGeod (INS case)

  • /gpsfix: publishes generic ROS message gps_msgs/GPSFix.msg, which is much more detailed than sensor_msgs/NavSatFix.msg, converted from the SBF blocks PVTGeodetic, PosCovGeodetic, ChannelStatus, MeasEpoch, AttEuler, AttCovEuler, VelCovGeodetic, DOP (GNSS case) or INSNavGeod, ChannelStatus, MeasEpoch, DOP (INS case). In order to publish heading information, the field dip is diverted from its intended meaning an populated with the heading angle and err_dip with its uncertainty.

    • INS case: Beware, in order to allow a high update rate, ChannelStatus, MeasEpoch, and DOP are not time aligned, i.e., they might contain outdated information.

  • /pose: publishes generic ROS message geometry_msgs/PoseWithCovarianceStamped.msg, converted from the SBF blocks PVTGeodetic, PosCovGeodetic, AttEuler, AttCovEuler (GNSS case) or INSNavGeod (INS case).

    • Note that GNSS provides absolute positioning, while robots are often localized within a local level cartesian frame. The pose field of this ROS message contains position with respect to the absolute ENU frame (longitude, latitude, height), i.e. not a cartesian frame, while the orientation is with respect to a vehicle-fixed (e.g. for mosaic-x5 in moving base mode via the command setAttitudeOffset, …) !local! NED frame or ENU frame if use_ros_axis_directions is set true. Thus the orientation is !not! given with respect to the same frame as the position is given in. The cross-covariances are hence set to 0.

  • /twist: publishes generic ROS message geometry_msgs/TwistWithCovarianceStamped.msg, converted from the SBF blocks PVTGeodetic and VelCovGeodetic.

  • /twist_ins: publishes generic ROS message geometry_msgs/TwistWithCovarianceStamped.msg, converted from SBF block INSNavGeod.

  • /insnavcart: publishes custom ROS message septentrio_gnss_driver/INSNavCart.msg, corresponding to SBF block INSNavCart

  • /insnavgeod: publishes custom ROS message septentrio_gnss_driver/INSNavGeod.msg, corresponding to SBF block INSNavGeod

  • /extsensormeas: publishes custom ROS message septentrio_gnss_driver/ExtSensorMeas.msg, corresponding to SBF block ExtSensorMeas.

  • /imusetup: publishes custom ROS message septentrio_gnss_driver/IMUSetup.msg, corresponding to SBF block IMUSetup.

  • /velsensorsetup: publishes custom ROS message septentrio_gnss_driver/VelSensorSetup.msg corresponding to SBF block VelSensorSetup.

  • /exteventinsnavcart: publishes custom ROS message septentrio_gnss_driver/INSNavCart.msg, corresponding to SBF block ExtEventINSNavCart.

  • /exteventinsnavgeod: publishes custom ROS message septentrio_gnss_driver/INSNavGeod.msg, corresponding to SBF block ExtEventINSNavGeod.

  • /diagnostics: accepts generic ROS message diagnostic_msgs/DiagnosticArray.msg, converted from the SBF blocks QualityInd, ReceiverStatus and ReceiverSetup

  • /imu: accepts generic ROS message sensor_msgs/Imu.msg, converted from the SBF blocks ExtSensorMeas and INSNavGeod.

    • The ROS message sensor_msgs/Imu.msg can be fed directly into the robot_localization of the ROS navigation stack. Note that use_ros_axis_orientation should be set to true to adhere to the ENU convention.

  • /localization: accepts generic ROS message nav_msgs/Odometry.msg, converted from the SBF block INSNavGeod and transformed to UTM.

    • The ROS message nav_msgs/Odometry.msg can be fed directly into the robot_localization of the ROS navigation stack. Note that use_ros_axis_orientation should be set to true to adhere to the ENU convention.

  • /localization_ecef: accepts generic ROS message nav_msgs/Odometry.msg, converted from the SBF blocks INSNavCart and INSNavGeod.

    • The ROS message nav_msgs/Odometry.msg can be fed directly into the robot_localization of the ROS navigation stack. Note that use_ros_axis_orientation should be set to true to adhere to the ENU convention.

Suggestions for Improvements

Some Ideas
  • Equip ROSaic with an NTRIP client such that it can forward corrections to the receiver independently of Data Link.

Adding New SBF Blocks or NMEA Sentences

Steps to Follow

Is there an SBF or NMEA message that is not being addressed while being important to your application? If yes, follow these steps:

  1. Find the log reference of interest in the publicly accessible, official documentation. Hence select the reference guide file, e.g. for mosaic-x5 in the product support section for mosaic-X5, Chapter 4, of Septentrio’s homepage.

  2. SBF: Add a new .msg file to the ../msg folder. And modify the ../CMakeLists.txt file by adding a new entry to the add_message_files section.

  3. Add msg header and typedef to typedefs.hpp.

  4. Parsers:

    • SBF: Add a parser to the sbf_blocks.hpp file.

    • NMEA: Construct two new parsing files such as gpgga.cpp to the ../src/septentrio_gnss_driver/parsers/nmea_parsers folder and one such as gpgga.hpp to the ../include/septentrio_gnss_driver/parsers/nmea_parsers folder.

  5. Processing the message/block:

    • SBF: Extend the SbfId enumeration in the message_handler.hpp file with a new entry.

    • SBF: Extend the SBF switch-case in message_handler.cpp file with a new case.

    • NMEA: Extend the nmeaMap_ in the message_handler.hpp file with a new pair.

    • NMEA: Extend the NMEA switch-case in message_handler.cpp file with a new case.

  6. Create a new publish/.. ROSaic parameter in the ../config/rover.yaml file and create a boolean variable publish_xxx in the struct in the settings.h file. Parse the parameter in the rosaic_node.cpp file.

  7. Add SBF block or NMEA to data stream setup in communication_core.cpp (function configureRx()).