In an additive manufacturing machine using a plurality of lasers, a reference laser is established that remains stationary and focused on a commanded point in a collection area. The reference laser uses one or more co-axial sensors to monitor emitted electromagnetic energy in the area. While the reference laser is monitoring the area, each non-reference laser in turn produces and moves a meltpool through the collection area in a known movement. For each non-reference laser, the electromagnetic energy collected and observed by the reference laser during positions of the known movement is compared with an expected electromagnetic energy for each position. For a given non-reference laser, the differences between the observed and expected electromagnetic energies can be used to determine differences between a coordinate system of the reference laser and a coordinate system of non-reference laser. The non-reference laser may then be realigned based on the determined differences.

There is provided a laser processing system including: a robot; a laser emission section provided on the robot; an irradiation path calculation section configured to calculate an irradiation path of a laser beam emitted from the laser emission section using information on a position of the robot; a determination section configured to determine whether the irradiation path calculated passes through an allowable irradiation region that is predetermined; and a laser-output reduction section configured to reduce output of the laser beam to be emitted to the irradiation path to a second output lower than a first output for processing in accordance with a determination by the determination section that the irradiation path does not pass through the allowable irradiation region.

The present invention relates to a method for process control in laser material processing and provides a method for process control and regulation in laser material processing, comprising generating at least two ST individual diagrams in the regions of interest of images of laser material processing and orienting the at least two ST individual diagrams in a previously determined pattern

An apparatus for layered manufacture of a three-dimensional product includes a build chamber having a window, a build platform within the build chamber, a calibration device that is physically separated from the build chamber, an optical system including a beam source and a scanning apparatus, and a mobile base. The mobile base is configured to position the scanning apparatus at two spaced part positions including a (1) production position and a (2) calibration position. At the production position the scanning apparatus is configured to receive an energy beam from the beam source and to reflect and scan the energy beam through the window and to a build surface over the build platform to create a layer of the three-dimensional product. At the calibration position the scanning apparatus is configured to reflect the energy beam to the calibration device but not through the window.

A laser annealing apparatus (1) according to the embodiment includes: a laser beam source (11) configured to emit a laser beam (L1) to crystallize an amorphous silicon film (101a) on a substrate (100) and to form a poly-silicon film (101b); a projection lens (13) configured to condense the laser beam to irradiate a silicon film (101); a probe beam source configured to emit a probe beam (L2); a photodetector (25) configured to detect the probe beam (L3) transmitted through the silicon film (101); a processing apparatus (26) configured to calculate a standard deviation of detection values of a detection signal output from the photodetector, and to determine a crystalline state of the crystallized film based on the standard deviation.

A control system for thermo optical control of focus position of an energy beam in an additive manufacturing apparatus has a first doped medium and a second doped medium, each of which is optically transparent and doped with a dopant. The first doped medium has a positive thermo-optical coefficient (dn/dT) and the second doped medium has a negative thermo-optical coefficient (dn/dT) and is in series with the first doped medium. An energy beam input or coupling is configured to generate or receive an energy beam that is required to be controlled, the energy beam being within a first wavelength range and directed towards the first and second doped mediums. An absorbed beam input or coupling is configured to generate or receive at least one absorbed beam in a second wavelength range which is different from the first wavelength range, the absorbed beam being directed towards the first and second doped mediums. The first and second doped mediums have a higher beam absorption characteristic in the second wavelength range than in the first wavelength range, causing the absorbed beam to have a higher absorption than the energy beam in the first and second doped mediums and the first and second doped mediums each have a coating which allows transmission at both the first and the second wavelength ranges.

The present disclosure relates to methods and systems for monitoring a welding process for welding at least one glass workpiece to another workpiece, e.g., also made of glass, wherein a weld seam is formed in the workpieces in a process zone that is exposed to a pulsed processing beam, e.g., to a pulsed laser beam, such as an ultra-short-pulse laser beam, wherein the radiation emitted by the process zone is detected in a time-resolved manner.

The present disclosure provides a laser cutting method. The laser cutting method is applied to cut a polarizer. The method includes: providing a non-linearly polarized light; adjusting the non-linearly polarized light to a first linearly polarized light by a polarization adjusting device; and cutting the polarizer by the first linearly polarized light.

A beam propagation camera has at least one beam-splitting optical arrangement (240) configured to split a beam, which is incident on the beam-splitting optical arrangement along an optical axis (OA) of the beam propagation camera, into a multiplicity of sub-beams, and a sensor arrangement (250) configured to detect the sub-beams. The beam-splitting optical arrangement has a diffractive structure (241) configured such that at least two of the sub-beams are spatially separated from one another on the sensor arrangement and have respective foci longitudinally offset from one another along the optical axis.

The invention relates to a device for roughening cylinder bores using a beam tool and offering a very high level of process reliability even for a large quantity.