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These reflective microscope objectives are optimized for chromatic aberration over a bandwidth of 350 nm to 7 µm.
With their long acting infinity correction function, these objectives can be used for a laser system and coaxial observation.
With these objectives, the user can focus a visible laser or microscopic observation of objects from a distance.
With its long working distance and field curvature correction, a natural observation image is achieved to the periphery of the field of view.
With its long working infinity correction function, this objective can be used for a laser system and coaxial observation. It is also used for near UV light observation.
These are infinity corrected objectives with high NA for laser processing.
These Objective lenses provide high transmittance at three harmonic wavelengths of YAG.
F-Theta Lenses are used for laser marking, bar code reader, laser micromachining and other laser applications.
F-Theta Lenses are used for laser marking, bar code reader, laser micromachining and other laser applications.
The F-Theta Lenses for CO2 laser are made by a single lens of zinc selenide.
Designed specifically for fundamental and harmonic wavelengths of YAG and Fiber lasers. OSE-TL-Y3: Compatible with wavelengths from fundamental to 3rd harmonic.
Popular Products
This laser beam profiler features a CMOS sensor that guarantees frame rates of up to 60 Hz with high dynamics and is suitable for large beam diameters up to 11 mm.
The beam analysis camera WinCamD-IR-BB with integrated microbolometer array enables analyzes on long-wave lasers in the range of 2 μm to 16 μm.
This Laser Beam Profiler from DataRay is equipped with a CQD sensor and offers a spectral response in the SWIR range of 400 - 1700 nm with resolutions up to 1920 x 1080 pixel.
DataRay's ILM system is used for beam profile monitoring of high power lasers consisting of an attenuator for high powers, an imaging lens system and a camera system. The measurement of very small laser beams with diameters of less than micrometers is possible despite often high laser powers.