Exploring the technology behind 4K MEMS IR emitters
Innovation tends to follow a familiar path: first, we invent something powerful. Then we shrink it. Only then does it become an everyday part of the infrastructure.
We’ve seen this evolution before:
Computers → Microprocessors → Smartphones
Cameras → CMOS sensors → Computer vision
Incandescent bulbs → LEDs → Smart lighting
But one layer is still missing in today’s technology: sensing beyond the visible.
Most consumer devices only exploit a tiny sliver of the visible electromagnetic spectrum. Infrared, though, reveals what visible light cannot: the chemistry of life, materials, gases, and signals hidden beneath the surface.
It’s already essential in science, space, and defense, but almost absent from the devices we use every day. Why? Traditional IR emitters are too large, power-hungry, slow, and expensive.
Modern sensors are remarkable at detecting motion, sound, temperature, pressure, and orientation. Yet they still overlook a deeper layer of information: what materials are made of, or what substances are present. Infrared sensing stands out because it can detect water content, gas concentrations, organic compounds, and even fat and sugar levels.
Infrared spectroscopy was once the domain of satellites and research facilities. The principle is simple: emit light, analyze what’s reflected or absorbed, and learn the chemical makeup of food, plastic, skin, or air. Science hasn’t changed — but the scale has.
Today, there’s a growing demand for insight in smaller contexts:
The bottleneck is the hardware. Traditional IR emitters are too bulky and power-intensive. The missing piece is a compact, programmable infrared light source — from a chip-scale package, operating at low power and high speed.
Over the past two decades, nearly every sensing technology has shrunk — accelerometers, gyroscopes, cameras, microphones. But infrared stayed big. Thermal sources require power, warm-up time, and optics. They work in research facilities, not in everyday devices.
Miniaturization isn’t cosmetic. It’s what makes intelligence scalable. The leap forward comes from a new class of infrared emitters — compact, broadband-capable, power-efficient, and designed for chip-scale integration.
When the invisible becomes embeddable, we don’t just improve sensing—we unlock intelligence at scale.
https://www.4kmems.ch
For most deep-tech entrepreneurs, a familiar fact: a deep-tech startup takes longer to commercialize than regular software-based and/or SaaS-based startups. The gap between proof of concept and actual revenue takes longer. The following graph provides some insight into why things take longer.
The TD Shepherd team is happy to congratulate the Qualinx B.V. team on successfully raising €20 million from Dutch investors. TD Shepherd has provided strategic support to Qualinx over the years (starting in 2018), witnessing each step of their journey; their growth and success, makes us truly proud of their outstanding achievements.
If there’s one thing we’ve learned about surviving the Valley of Death in deep tech, it’s this: don’t go it alone. This stage is all about leveraging relationships, and corporate partnerships can be your most valuable lifeline. The key is to think beyond customers.