TR SCAN

Completely designed and manufactured in Switzerland by TRIMOS the TR Scan is used in workshops and laboratories worldwide. Accuracy, speed, ease of use and modular construction make it ideal for all types of surface measurements.

The TR Scan adapts to a large range of materials such as steel, aluminium, brass, titanium, silicon, gold, ceramics, glass etc. The system can be tailored to fit the requirements of many industries: Automotive, Aircraft, Machine Tool, Watch, Railway, Medical, Materials, Optics, Electronic...

The TR SCAN is an evolutionary machine which through its different technologies meets a wide range of varied applications.

CCML1

The chromatic confocal line sensor TRIMOS CCML1 offers an incredibly fast 3D measurement of 384.000 points per second with nanometric scale resolution.

A robust and compact design, as well as outstanding dynamic range and an excellent signal to noise ratio, make the TRIMOS CCML1 the best measuring tool for all materials – including polished and highly tilted surfaces. With its unrivaled performance/price ratio, TRIMOS CCML1 is the best choice for ultrafast 3D inspectio

WLI

White-light interferometry is among the proven optical measurement techniques for recording 3-D topographies with depth resolution in the lower nanometre range. The measurement points are acquired and processed in parallel, the height information can be gathered over a large area in a very short time.

Typical applications in research and in quality management are the characterisation of surfaces with different roughness values (wafer structures, mirrors, glass, metals), the determination of step heights and the precise measurement of curved surfaces, such as microlenses.

The product family WLI offers innovative solutions utilising this measurement principle. The control and analysis of the entire measurement process is done using the proven Trimos Nanoware software.

DHM

Digital Holographic Microscopy (DHM) is the generation of computer images of a sample using holographic techniques.

A hologram results from the interference between the object wave reflected from a sample and magnified by a microscope objective, and a reference wave.

Using a laser source, the small angle between the waves exhibits fringes that carry the phase and amplitude information in a single image - the hologram which is captured on a digital camera in a few microseconds.

The captured image is transmitted to a computer where numerical procedures are applied to reconstruct a 3D image of the sample. This process is called "image reconstruction". The innovation of the DHM™ patented technology is the intervention of digital processing at a level that had not been reached so far in microscopy.