What is straylight?
When designing imaging and illumination optical systems one normally starts assuming ideal
optical components. The design is then optimized with respect to the desired imaging or illumination system
performance. In reality these idealized conditions are never met. There will be always
a certain fraction of straylight (unwanted light) compromising the performance of the
Stray light deteriorates the system performance through reduced image quality, higher noise/measurement background,
damage of components, glare, etc.
The straylight performance often decides whether an optical system is operational or
not. In any case, it is a criterion for the quality of an optical instrument.
Reflection from glas or transparent plastic surfaces or from the image sensor; double reflection from optical surfaces leads
to so-called "ghosts" in the image plane
- Light is scattered from rough or contaminated optical components and mechanical
parts (fittings, housing, apertures etc.)
- Diffraction from aperture stops
- In the infrared, we also encounter thermal radiation from system components
in or near the optical path.
Analysis of straylight
Computer-based straylight analysis allows for the diagnosis of the straylight performance, before the
system is fabricated, and gives valuable hints how to avoid straylight, e.g., by using suitable baffles.
The earlier a straylight analysis is performed during the optical design process, the lower is the
risk for a deficient design.
Straylight analyses are standard in the following application fields:
- Space optics: In-field and out-of-field straylight
(Straylight sources: Sun, Earth, Moon, ...), diffraction analysis and thermal radiation analysis
- Optical industry: analysis of high-end imaging systems for lithography, camera systems, projection optics, microscopes etc.
- Illumination system design: Glare analysis for luminaires, automotive headlamps etc.
Reducing and avoiding stray light
A thorough analysis of stray light is the prerequisite for desiging counter measures.
In general, there three three approaches to stray light reduction:
- Re-direct stray light such that it cannot reach the sensor plane anymore—
for instances by use of reflecting surfaces like in the Stavroudis baffle shown here.
- Block stray light such that it cannot enter the optical system. This is achieved
by baffle structures.
- Absorb straylight using black coatings.
Our Know-how and competence
Our team consists of straylight experts with a long experience in analyzing lenses for UV-lithography, camera systems, astronomical telescopes. The main market for straylight analysis is, however, space industry,
where our team has successfully accomplished many straylight projects, ranging from star trackers to telescope systems, spectrometers and more. Dr. Bernhard Michel, the founder of Hembach Photonik, is a renowned straylight expert with more than
20 years experience in the field of light scattering.
Particularly in space industriy, straylight analysis is simply a must. We'd be happy to assist you with our know-how as an external partner for straylight analysis: ghost analysis, analysis of scattered light, diffraction from aperture, thermal emission analysis. Based on the results or our analysis, we develop measures against straylight (baffle design, coating recommendations etc). For our analyses we count on the time-proven optical software ASAP. For the post processing of the giant amounts of data that are often produced during an analysis we use our own sofware.
ASAP is a registered trademark of the Breault Research Organization (USA).
Last changed: January 13, 2017 © 2011–2016 Hembach Photonik GmbH