Add to ORKGApplications, such as pico-projectors need a rectangular beam distribution – so called flat hat distribution. SCHOTT presents a diffractive optical element (DOE) made out of glass that shapes the Gaussian light distribution of the laser source into a flat hat distribution. Design and measurements for different designs are compared showing the good performance of the SCHOTT DOEs.
An algorithm is reported for the design of a phase-only diffractive optical element (DOE) that resha...
Laser beam shaping has been promising for many applications, such as two-photon polymerization[1], a...
A Gaussian laser beam is reshaped to have specific irradiance distributions in many applications in ...
Uniform intensity of laser radiation is very important in holographic and interferometry technologie...
This paper presents theory, calculus and technical aspects concerning building up a diffractive opti...
Diffractive optical elements (DOEs) have been being used widely in the areas such as, optical imagin...
Diffractive optical elements (DOEs) for beam shaping of spatially incoherent light into an output sp...
This paper introduces a single lens laser beam shaper which is capable of redistributing a beam with...
Diffractive optical elements (DOEs) enable novel high performance and process-tailored scanning stra...
Beam shaping techniques have been widely used in optical engineering especially in projection optics...
The intensity distribution of a laser beam has a high impact on laser processing applications. In ma...
A set of laser beam shaping optics is designed by an iterative method using an adaptive additive alg...
A method for converting single mode Gaussian beams into beams with uniform irradiance profiles is de...
The task of transforming a given intensity distribution into a different, desired intensity distribu...
In this study, the circular Gaussian spot emitted by a laser light source is shaped into a rectangul...
An algorithm is reported for the design of a phase-only diffractive optical element (DOE) that resha...
Laser beam shaping has been promising for many applications, such as two-photon polymerization[1], a...
A Gaussian laser beam is reshaped to have specific irradiance distributions in many applications in ...
Uniform intensity of laser radiation is very important in holographic and interferometry technologie...
This paper presents theory, calculus and technical aspects concerning building up a diffractive opti...
Diffractive optical elements (DOEs) have been being used widely in the areas such as, optical imagin...
Diffractive optical elements (DOEs) for beam shaping of spatially incoherent light into an output sp...
This paper introduces a single lens laser beam shaper which is capable of redistributing a beam with...
Diffractive optical elements (DOEs) enable novel high performance and process-tailored scanning stra...
Beam shaping techniques have been widely used in optical engineering especially in projection optics...
The intensity distribution of a laser beam has a high impact on laser processing applications. In ma...
A set of laser beam shaping optics is designed by an iterative method using an adaptive additive alg...
A method for converting single mode Gaussian beams into beams with uniform irradiance profiles is de...
The task of transforming a given intensity distribution into a different, desired intensity distribu...
In this study, the circular Gaussian spot emitted by a laser light source is shaped into a rectangul...
An algorithm is reported for the design of a phase-only diffractive optical element (DOE) that resha...
Laser beam shaping has been promising for many applications, such as two-photon polymerization[1], a...
A Gaussian laser beam is reshaped to have specific irradiance distributions in many applications in ...