Our customer Silicon Austria Labs (SAL) received the new DHM as the winning prize of Lyncee Challenge 2022! By integrating a motorized goniometer on their new DHM, they have fully automated the measurement of the micromirror:
Validate efficiently your simulations against experiment data and improve your MEMS design! Read more.
With experiments run in parallel our Digital Holographic Microscope (DHM®) will:
Find out more in our latest newsletter.
Silicon Austria Labs (SAL) won Lyncée Tec Challenge 2022 for their outstanding and innovative demonstration of measuring dynamic deformations of MEMS mirrors at all scanning angles using DHM’s unique full field vibration mode shape analysis. Their prize is a DHM Holographic MEMS Analyzer! Congratulations to the WINNER and to all participants!
Read our newsletter and check out the 5 best applications!
TWO new opportunities at Lyncée Tec. Come and join an innovative team !
Our first life science DHM was delivered 16 years ago.
The innovative data generated by the main user, Dr Pascal Jourdain, with his microscope triggered major contributions to the new research field of OPTICAL electrophysiology.
Find out more in our latest newsletter
We are very happy to officially launch Lyncée Tec Challenge 2022! The goal of the challenge is to encourage exploration of the potential of high laterally resolved vibration analysis with DHM and to reward the best application a DHM Holographic MEMS Analyzer! Register before July 30th 2022 and WIN a DHM! More details please visit https://challenge.lynceetec.com/
Congratulations to our DHM’s users at Silicon Austria Labs who present their latest achievement in SPIE Photonics Europe 2022. Their reported methods enable continuous dynamic deformation measurement of MEMS micromirror at any scan angle.
Find out more in our application page
DHM® up to 100’000 fps confirms the mechanism of sonogenetics
In a seminal publication, the group of James Friend at UCSD discovers the mechanism of ultrasound causing ion channel activation underpinning sonogenetics. For this application they use Lyncée Tec High-speed DHM®
Find our more in our latest newsletter
During the COVID-19 pandemic travel restriction period, trees were planted for DHM® purchased through remote demonstrations
Our users‘ forest has over 3000 trees
Lyncée is pleased to extend this action beyond the pandemic in the hope of limiting the ecological footprint of its activity
Read our newsletter and book a remote demo
Digital Holographic Microscopy (DHM®) quantitative phase images record the morphology (shape) and content (hemoglobin content) of Red Blood Cells and provide an important clinical readout on the health status of RBC without label as demonstrated in this latest publication in the International Journal of Molecular Sciences.
A nice publication in the Journal of Physics Photonics
retracing Lyncée path from pioneer work in 1999 to revolutionary and matured applications in 2021
in the field of optical metrology.
With DHM® by Lyncée, just measure and discover!
A new seminal publication reports real-time 4D topography measurements with our Digital Holography Microscopes (DHM®) SIMULTANEOUSLY to laser processing.
Explore cell health and physiopathological processes with the EVOLUTIVE DHM® T series by Lyncée Tec
Digital Holographic Microscopy (DHM®) records Quantitative Phase Images and measures cells morphology and intracellular protein content.
These two key biomarkers enable monitoring of living cells health status and of ongoing biological processes without perturbing them.
Discover unique in-situ 4D monitoring of electrochemical etching and surface dissolution in liquid with interferometric resolution by DHM®!
Combine Quantitative Phase Imaging (QPI) and fluorescence in a single instrument to open new perspectives for multimodal imaging.
DHM® is the world’s fastest 3D optical profilometer. It provides the most comprehensive MEMS vibration analysis up to 25MHz. And each measurement has a mega-data-points resolution!
Learn more about the latest cMUT, pMUT, and Surface Acoustic Waves (SAW) measurements.