Understand the Doppler effect’s role in scanning laser vibrometers and laser Doppler vibrometry. Explain how the vibration information can be used to extract relative displacements. Discover Ommatidia’s Q1 & Q2 Laser RADAR innovations for reliable vibration measurement in automotive and industrial applications.
Stay up to date with the latest developments in LiDAR technology and products. From new releases and performance breakthroughs to industry trends and applications, here you'll find the most relevant LiDAR news and insights.
Explore innovations shaping the future of mapping, automation, and 3D sensing.
Ommatidia LiDAR has completed the delivery and hands-on training of our Q2 Laser Radar system at The University of Texas at Austin (UT Austin), where it will support experimental research requiring precise, repeatable, non-contact measurements.
Traditional modal analysis can take days of setup and scanning to capture vibration data point by point. With Ommatidia LiDAR’s Q2 Laser RADAR, full-field quantitative modal analysis is completed in just 20 minutes. This walkthrough explains how parallel-beam laser radar delivers precise, non-contact 3D metrology and vibrometry across hundreds of points simultaneously—transforming how researchers, engineers, and testing labs measure structural dynamics.
Ommatidia LiDAR is growing Europe’s next generation of photonics and deep-tech talent by creating skilled roles in optics, electronics, software and test engineering. This hiring effort is supported by the European Social Fund Plus (FSE+) via the Community of Madrid’s youth employment programme, co-financed at 40%.
Traditional scanning laser vibrometers capture one point at a time—slowing down measurements and missing critical vibration data. Parallel Beam Laser RADAR changes that. Using photonic integrated circuits to generate dozens of simultaneous laser channels, Ommatidia LiDAR’s Q1 and Q2 systems deliver faster, more accurate, and fully synchronized vibration and metrology measurements for aerospace, automotive, and industrial applications.
Remote Sound Sensing with Laser RADAR introduces a new way to capture acoustic information — not with microphones, but with light. Using Ommatidia LiDAR’s massively parallel FMCW technology, sound waves and vibrations can be detected remotely through precise laser interferometry. This enables real-time, contact-free analysis of structures, machinery, and environments, unlocking new possibilities in industrial diagnostics, aerospace testing, and acoustic research.
