Friday, June 15, 2018

TrinamiX Paper in Nature

Nature publishes BASF spin-off TrinamiX paper "Focus-Induced Photoresponse: a novel way to measure distances with photodetectors" by Oili Pekkola, Christoph Lungenschmied, Peter Fejes, Anke Handreck, Wilfried Hermes, Stephan Irle, Christian Lennartz, Christian Schildknecht, Peter Schillen, Patrick Schindler, Robert Send, Sebastian Valouch, Erwin Thiel, and Ingmar Bruder.

"We present the Focus-Induced Photoresponse (FIP) technique, a novel approach to optical distance measurement. It takes advantage of a universally-observed phenomenon in photodetector devices, an irradiance-dependent responsivity. This means that the output from a sensor is not only dependent on the total flux of incident photons, but also on the size of the area in which they fall. If probe light from an object is cast on the detector through a lens, the sensor response depends on how far in or out of focus the object is. We call this the FIP effect. Here we demonstrate how to use the FIP effect to measure the distance to that object. We show that the FIP technique works with different sensor types and materials, as well as visible and near infrared light. The FIP technique operates on a working principle, which is fundamentally different from all established distance measurement methods and hence offers a way to overcome some of their limitations. FIP enables fast optical distance measurements with a simple single-pixel detector layout and minimal computational power. It allows for measurements that are robust to ambient light even outside the wavelength range accessible with silicon.

In this paper, we demonstrated the measurement principle at distances up to 2 m and showed a resolution of below 500 ┬Ám at a distance of 50 cm. In the Supplementary Information S7, distance measurements up to 70 m can be found.


  1. So light sources get brighter because their light is being focused more? What's new about that? Any kid with a magnifying glass in the sun knows this...

    1. No, their idea is different. The exact same amount of photons generates different photocurrents depending on whether it's focused in a small spot or in a large spot.

    2. ... and that is not because the amount is concentrated on fewer sensing elements?

    3. They have only one sensing element - "single pixel sensor."


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