Novatel OM-20000141 user manual  Logging Restriction Important Notice

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SPAN OperationChapter 3

Logging Restriction Important Notice

Logging excessive amounts of high rate data can overload the system. When configuring the output for SPAN, NovAtel recommends that only one high rate (>50 Hz) message be configured for output at a time. It is possible to log more than one message at high rates, but doing so could have negative impacts on the system. Also, if logging 125 or 200 Hz data, always use the binary format and, if possible, the short header binary format (available on most INS logs).

For optimal performance, log only one high rate output at a time. These logs could be:

Raw data for post processing RAWIMUXSB ONNEW (125 or 200 Hz)

-RAWIMU logs are not valid with the ONTIME trigger. The raw IMU observations contained in these logs are sequential changes in velocity and rotation. As such, you can only use them for navigation if they are logged at their full rate. See details of these logs in the SPAN on OEM6 Firmware Reference Manual (OM-20000144).

Real time INS solution

INSPVASB ONTIME 0.005 (maximum rate equals the IMU rate)

-Other possible INS solution logs available at high rates are: INSPOSSB, INSVELSB, INSATTSB

Specific logs need to be collected for post-processing. See Data Collection for Post-Processingon page 36.

To store data from a SPAN-IGM, connect the SPAN-IGM to a computer running NovAtel Connect or other terminal program capable of recording data.

3.2.4Vehicle to SPAN Frame Angular Offsets Calibration Routine

Kinematic alignment requires that the angular offset between the vehicle and SPAN frame is known approximately. If the angles are simple (that is, a simple rotation about one axis) the values can easily be entered manually through the VEHICLEBODYROTATION command. If the angular offset is more complex (that is, rotation is about 2 or 3 axis), then the calibration routine provides a more accurate estimation of the values. The vehicle to SPAN frame angular offset calibration requires RTK GPS. The steps for the calibration routine are:

1.Apply power to the SPAN-IGM.

2.Configure the IMU, see SPAN IMU Configuration on page 24.

3.Ensure that an accurate lever arm has been entered into the system.

4.Allow the system to complete an alignment, see System Start-Up and Alignment Techniques on page 30.

5.Enable the vehicle to body calibration using the RVBCALIBRATE ENABLE command.

6.Start to move the system. Movement of the system is required for the observation of the angular offsets.

Drive a series of manoeuvres such as figure eights if the driving surface is not level, or a straight course if on level ground (remember that most roads have a crown resulting in a constant roll of a few degrees). Avoid driving on a surface with a constant, non-zero, slope to prevent biases in the computed angles. Vehicle speed must be greater than 5 m/s (18 km/hr) for the calibration to complete.

SPAN-IGM User Manual Rev 2

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Contents OM-20000141 Rev September SPAN-IGMReturn Instructions Proprietary Notice WarrantyTable of Contents Frequently Asked Questions Replacement Parts Figures Tables Contact Information NovAtel Knowledge Base Before Contacting Customer SupportIndustry Canada FCC NoticesCE Notice Weee NoticeWhat is the hazard? Lightning Protection Installation and Grounding ProcedureHazard Impact Actions to Mitigate Lightning HazardsUSA Primary and Secondary Lightning Protection Ref # DescriptionFundamentals of Gnss + INS IntroductionScope System ComponentsSPAN-IGM Integrated Gnss + INS unit Gnss antenna PC softwareConventions Connector Type Connections Span InstallationRequired Equipment SPAN-IGM Hardware Use a USB cable to log raw data SPAN-IGM CablesSPAN-IGM Cables NovAtel Port PurposeTypical SPAN-IGM Set Up Serial Port Radio Hardware Set UpTypical SPAN-IGM Set Up USB Port Radio Mount the SPAN-IGM Mount the AntennaConnect the Antenna to the SPAN-IGM Connect PowerConnect a Computer to the SPAN-IGM Connect a Computer Using a Serial ConnectionConnect a Computer Using a USB Connection Connect I/O Strobe SignalsO Strobe Signals Signal Description aEnable the COM3 Serial Port Enable RS-422 serial connectionsDisable the COM3 Serial Port 8 COM3 Serial PortOdometer Requirements Odometer connectionGnss Configuration Software ConfigurationSpan IMU Configuration Pin M12 Connector Function J2 Wire Bundle On Cwpt SensorConfigure Span with Connect SPAN-IGM LEDs SPAN-IGM LEDsOff Flashing Slow 1Hz Flashing Fast 1Hz Communicating with the Span System Span OperationChapter Span Operation INS Window in NovAtel ConnectSpan Operation Chapter Real-Time OperationAscii System Start-Up and Alignment TechniquesKinematic Alignment Manual AlignmentDual Antenna Alignment Inssolutiongood Navigation ModeSolution Parameters Data CollectionVehicle to Span Frame Angular Offsets Calibration Routine  Logging Restriction Important NoticeWheel Sensor Update Logic Span Wheel Sensor MessagesMeasurement Timing and Frequency Azimuth Sources on a Span System Set up a Wheel SensorCourse Over Ground Inertial AzimuthLog Azimuth Source Format Data Collection for Post-ProcessingVariable Lever Arm SPAN-IGM Dual Antenna InstallationConfiguring Align with SPAN-IGM Alignment on a Stationary Vehicle Aided Static Alignment Alignment on a Moving Vessel Aided Transfer AlignmentSpan Align Attitude Updates Automatic Alignment Mode Automatic Alignment defaultUnaided Alignment Reference Frames Within Span Local-Level Frame ENUSpan Body Frame Span Vehicle Frame Enclosure FrameFirmware Updates and Model Upgrades Firmware UpdatesNovAtel Firmware and Software Model Upgrades Authorization CodeUpdating or Upgrading Using the WinLoad Utility Transferring Firmware FilesTypes of Firmware Files Open a File to Download Using the WinLoad UtilitySearching for Card Updating using SoftLoad CommandsSoftloadsrec S-RECORD Working with S-RecordsUpgrading Using the Auth Command Upgrade ProcedureXXXXXX,XXXXXX,XXXXXX,XXXXXX,XXXXXX,MODEL,EXPDATE SPAN-IGM-A1 Technical Specifications Technical SpecificationsSPAN-IGM-A1 Mechanical Drawings SPAN-IGM-A1 Environmental SpecificationsSPAN-IGM-S1 Physical Specifications SPAN-IGM-S1 Technical SpecificationsSPAN-IGM-S1 Gnss Performance SPAN-IGM-S1 Data RatesSPAN-IGM-S1 Mechanical Drawings SPAN-IGM-S1 Environmental SpecificationsMain Port Pinout SPAN-IGM PortsPin # Label Description AUX Port PinoutSPAN-IGM Interface Cable Pin-Out Descriptions SPAN-IGM Interface CableMIC Port User PortSPAN-IGM Align Interface Cable Pin-Out Descriptions SPAN-IGM Align Interface CableCOM3 Port SPAN-IGM Auxiliary Port Interface CablePin # Labels Varf DgndAppendix B Frequently Asked QuestionsAccessories and Options Replacement PartsSpan System Part Description NovAtel PartIndex Index OM-20000141 Rev September

OM-20000141 specifications

The Novatel OM-20000141 is a high-performance multi-GNSS (Global Navigation Satellite System) receiver designed for various applications including precision agriculture, autonomous vehicles, and surveying. This state-of-the-art device combines cutting-edge technologies to provide accurate and reliable positioning data, making it an indispensable tool for professionals in fields that rely on geolocation.

One of the standout features of the Novatel OM-20000141 is its multi-frequency support, allowing it to receive signals from GPS, GLONASS, Galileo, and BeiDou systems. This capability significantly enhances the accuracy and reliability of positioning information, particularly in challenging environments where signal interference can occur. By utilizing multiple frequencies, the OM-20000141 can mitigate errors caused by atmospheric disturbances and multi-path signals, resulting in improved precision.

In addition to its multi-GNSS capabilities, the receiver incorporates advanced RTK (Real-Time Kinematic) technology, enabling centimeter-level accuracy. This is particularly beneficial for applications that require pinpoint geolocation, such as precision agriculture, where farmers need to optimize crop yields and resource usage. The RTK technology allows users to achieve real-time positioning corrections, making it a vital tool for surveying and construction projects that demand high precision.

The Novatel OM-20000141 also features built-in connectivity options, including Bluetooth and USB interfaces, facilitating seamless integration with other devices and systems. This connectivity is crucial for enabling real-time data sharing and remote monitoring, enhancing the usability of the device in various operational environments.

Robustness is another significant characteristic of the OM-20000141. Designed to withstand harsh conditions, the receiver features a durable housing that protects it from dust, moisture, and extreme temperatures. This resilience ensures that the device operates effectively in all weather conditions, making it suitable for outdoor applications.

Furthermore, the receiver is equipped with intelligent positioning algorithms that optimize performance in urban canyons and dense foliage areas, where traditional GNSS receivers may struggle. By leveraging these algorithms, the OM-20000141 can maintain reliable positioning even in challenging environments.

Overall, the Novatel OM-20000141 stands out as a versatile and reliable GNSS receiver, merging advanced technologies to deliver high accuracy and reliability. Its exceptional features make it an invaluable asset for professionals in various industries, enhancing their ability to achieve precise geolocation and optimize their operations.