IMU & AHRS
Inertial Navigation Systems
IMU / AHRS
The VN-210 datasheet provides an extensive review of the VN-210 specifications and offers guidance for the successful integration of the VN-210 into your system.
The VN-200 datasheet provides an extensive review of the VN-200 specifications and offers guidance for the successful integration of the VN-200 into your system.
The VN-110 datasheet provides an extensive review of the VN-110 specifications and offers guidance for the successful integration of the VN-110 into your system.
The VN-100 datasheet provides an extensive review of the VN-100 specifications and offers guidance for the successful integration of the VN-100 into your system.
VN-200 and 210 GNSS-Aided Inertial Navigation Systems
Red Bull Air Race required a GNSS/INS to drive their augmented reality solution know as the Ghost Plane as well as provide highly accurate data for judging. The VN-300 rose to the challenged and enabled Red Bull Air Race to achieve a world first.
The Epsilon 140 uses VN-200 GNSS-Aided INS for reliable and accurate navigation data.
VN-100 IMU/AHRS and VN-200 GNSS/INS
LidarUSA’s ScanLook Revolution features an integrated VN-300 Dual-Antenna Inertial Navigation System. The combined system provides easy-to-use, efficient and cost effective LiDAR mapping capabilities targeted at applications such as law enforcement for accident scene reconstruction, archeology and encroachment monitoring.
Hydra S45 medium-range UAV uses VN-200 GNSS/INS for primary navigation.
VN-200 GNSS-Aided Inertial Navigation System for Satcom On the Move
Overwatch Imaging uses VN-200 GNSS/INS for accurate georeferencing
This note walks through the pointing requirements for SATCOM applications and provides guidance for choosing the best inertial sensor for such applications.
This note goes through the advantages of LIDAR over other surveying methods, the practical implementation of using LIDAR for surveying, and the impact of GNSS/INS precision on LIDAR accuracy.
The Gimballed EO/IR Systems application note provides a detailed analysis for choosing the right GNSS/INS system for such applications, alongside other integration considerations that will determine total system performance. The error budget is derived and an example provided to demonstrate the impact of various design choices.
This note introduces the variety of applications and design considerations relevant to all gimballed systems, alongside recommendations on navigation sensors for optimal performance.
This application note goes through the advantages and limitations of photogrammetry, the practical implementation of using photogrammetry for surveying and the impact of GNSS/INS precision on the photogrammetric process.