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Laser Beam Profilers

The WinCamD-IR-BB laser beam profiler is an imaging solution for lasers in the MWIR and FIR range. With 17 µm pixels, a wavelength range of 2-16 µm, and an integrated shutter, the WinCamD-IR-BB beam profiler offers unparalleled beam profiling capabilities.  With a signal-to-noise ratio that exceeds 1000:1, the WinCamD-IR-BB ...

Specifications

Sensor Type: Microbolometer
Measurable Sources: CW, Pulsed
Wavelength Range: 2000-16000nm
# Pixels (Width): 640
# Pixels (Height): 480
BeamPro is the most comprehensive range of laser beam prolers available on the market. All the cameras have been carefully qualied and selected by laser experts to successfully address any beam proling requirement, based on decisive criteria like pixel size, detection area, wavelength range, compactness or budget. Powered by a ...

Specifications

Sensor Type: CMOS
Measurable Sources: CW, Pulsed
Wavelength Range: 375-1100nm
# Pixels (Width): 1.45
# Pixels (Height): 1.45
BeamPro is the most comprehensive range of laser beam prolers available on the market. All the cameras have been carefully qualied and selected by laser experts to successfully address any beam proling requirement, based on decisive criteria like pixel size, detection area, wavelength range, compactness or budget. Powered by a ...

Specifications

Sensor Type: CMOS, InGaAs
Measurable Sources: CW, Pulsed
Wavelength Range: 375-1100nm
# Pixels (Width): TBD
# Pixels (Height): TBD
BeamPro is the most comprehensive range of laser beam prolers available on the market. All the cameras have been carefully qualied and selected by laser experts to successfully address any beam proling requirement, based on decisive criteria like pixel size, detection area, wavelength range, compactness or budget. Powered by a ...

Specifications

Sensor Type: CMOS
Measurable Sources: CW, Pulsed
Wavelength Range: 375-1100nm
# Pixels (Width): TBD
# Pixels (Height): TBD
With experience measuring laser beam profiles using tedious scanning techniques to sample the beam across x and y axes; LOD has invented a novel method of measuring any laser beam with one click of the LOD Image Profiler.  PIN photodiodes, expensive translations stages, software to run the stages and 2-4 hours of time is simply ...

Specifications

Sensor Type: CMOS
Measurable Sources: CW
Wavelength Range: 400-1150nm
# Pixels (Width): 1440
# Pixels (Height): 1080
About Gentec-EO: Gentec Electro-Optics is specialized in laser beam and terahertz source measurement and analysis. Gentec-EO is an expert in the design and manufacture of light detection and measurement technologies and solutions with a 50-year history in the market. Gentec\'s offerings include laser beam profilers, ...

Specifications

Sensor Type: CMOS
Measurable Sources: CW, Pulsed
Wavelength Range: 350-1150nm
# Pixels (Width): 2048
# Pixels (Height): 2048
The BEAMAGE-4M-FOCUS is an advanced beam profiling camera designed for large beams, featuring a fiber optic taper. With a high-resolution 4.2 MPixel CMOS sensor, this camera is capable of ISO-compliant measurements in the spectral range of 350 to 1150 nm. Its pixel multiplication factor (PMF) of 1.8 (typical) ensures precise beam ...

Specifications

Sensor Type: CMOS
Measurable Sources: CW, Pulsed
Wavelength Range: 350-1100nm
# Pixels (Width): --
# Pixels (Height): --
The BEAMAGE-4M-FOCUS is an advanced beam profiling camera designed for large beams, featuring a fiber optic taper. With a high-resolution 4.2 MPixel CMOS sensor, this camera is capable of ISO-compliant measurements in the spectral range of 350 to 1150 nm. Its pixel multiplication factor (PMF) of 1.8 (typical) ensures precise beam ...

Specifications

Sensor Type: CMOS
Measurable Sources: CW, Pulsed
Wavelength Range: 350-1150nm
# Pixels (Width): 2048
# Pixels (Height): 1088
Phasics' wavefront sensors simultaneously provide both phase and intensity measurements with unrivalled high resolution. The SID4 wavefront sensor combined with its beam-analysis software delivers a complete diagnostic of the laser: laser beam quality parameters (M2, waist size, and position, ...), wavefront aberrations and intensity ...

Specifications

Sensor Type: CMOS, Microbolometer, InGaAs
Measurable Sources: CW, Pulsed
Wavelength Range: 190-14000nm
# Pixels (Width): up to 850
# Pixels (Height): up to 720
The laser beam profiler displays and records the spatial intensity profile of a laser beam at a particular plane transverse to the beam propagation path. Since there are many types of lasers - ultraviolet, visible, infrared, continuous wave, pulsed, high-power, low-power - there is an assortment of instrumentation for measuring laser ...

Specifications

Sensor Type: CMOS
Measurable Sources: CW
Wavelength Range: 300-1100nm
# Pixels (Width): 2400
# Pixels (Height): 2400

Frequently Asked Questions

A Laser Beam Profiler is a device used to measure and analyze the spatial intensity distribution, size, and shape of laser beams. It is crucial for optimizing the performance and safety of laser systems in various applications such as manufacturing, scientific research, and medical procedures.

Camera-Based Laser Beam Profilers utilize CCD or CMOS sensors to capture a two-dimensional image of the laser beam's intensity distribution. They offer real-time monitoring and are widely used due to their versatility and convenience.

Beam width is a critical metric as it provides information on the laser's focus and alignment. In applications like laser cutting or welding, controlling the beam width is essential for precision and material interaction.

Laser Beam Profilers are used across various sectors including industrial manufacturing for laser cutting and welding, scientific research for experiments involving lasers, medical procedures such as laser surgery, and in telecommunications to characterize optical fibers and laser sources.

Scanning Slit Laser Beam Profilers use a narrow slit that moves across the laser beam. The light passing through the slit is measured by a photodetector, and by scanning across the beam, a two-dimensional profile of the beam’s intensity is created.

Yes, certain types of Laser Beam Profilers like pyroelectric array profilers are designed to measure high-power beams. It is important to select a profiler that is compatible with the power levels of the laser you are working with.

When selecting a Laser Beam Profiler, consider the wavelength range, dynamic range and sensitivity, resolution and accuracy, and compatibility with existing systems. It's also important to evaluate whether the profiler meets the specific requirements of your application.

Understanding the intensity distribution across the laser beam is crucial for applications requiring uniformity or a specific intensity profile. It affects how the laser interacts with materials and is critical for achieving desired results in processes like laser engraving or medical treatments.

Laser Beam Profilers: A Comprehensive Overview

Laser Beam Profilers are indispensable tools for assessing and optimizing the spatial intensity distribution of laser beams. This detailed guide elucidates the critical aspects and applications of these sophisticated devices.

Introduction to Laser Beam Profilers

In the domain of lasers and photonics, beam profiling plays a pivotal role in ensuring the performance, reliability, and safety of laser systems. Laser Beam Profilers are specialized instruments that measure the spatial distribution and shape of laser beams. Understanding the beam profile is essential for optimizing laser systems for applications such as material processing, scientific research, medical procedures, and telecommunications.

How Laser Beam Profilers Work

Camera-Based Profilers: The most prevalent type of beam profiler is the camera-based profiler. These devices employ CCD or CMOS sensors, which provide a two-dimensional representation of the laser beam's intensity distribution. The major advantage of camera-based profilers is that they deliver real-time monitoring of the beam’s characteristics.

Scanning Slit Profilers: Scanning slit profilers use a narrow slit that moves across the laser beam. Photodetectors then measure the light that passes through the slit. By scanning across the beam, this type of profiler constructs a detailed two-dimensional representation of the beam’s intensity.

Knife-Edge Profilers: Knife-edge profilers involve a sharp edge that traverses through the laser beam while a photodetector measures the power. This method provides a one-dimensional profile, which can be utilized to build a full image by taking measurements at different angles.

Pinhole and Pyroelectric Profilers: Pinhole profilers analyze a beam by scanning it with a tiny aperture, whereas pyroelectric profilers are tailored for high-power beams, using a pyroelectric sensor instead of a standard camera sensor.

Key Metrics of Beam Profiling

Beam Width: One of the fundamental measurements made by a laser beam profiler is the beam width. This metric provides valuable information on the laser’s focus and alignment.

Beam Shape: Understanding the beam shape is essential for applications that require precise control over how the laser interacts with materials, such as in laser cutting or welding.

Intensity Distribution: This measurement provides insights into the variation of power across the beam. It is crucial for applications where uniformity or a specific intensity distribution is required.

Applications of Laser Beam Profilers

Industrial Applications: In the manufacturing sector, laser beam profilers are indispensable for optimizing laser cutting, welding, and marking processes. Ensuring a consistent and precise beam profile is key to achieving high-quality results.

Scientific Research: In scientific research, particularly in physics and material science, laser beam profilers are used to characterize lasers used in experiments. Precision in beam profiling is essential to ensure the accuracy of the results.

Medical Applications: Laser Beam Profilers are employed in various medical applications including laser surgery and therapeutic treatments. They ensure that the laser beam is optimized for safety and efficacy.

Telecommunications: In the field of optical communications, Laser Beam Profilers help in the characterization of optical fibers and the laser sources used for data transmission.

Selection Criteria and Considerations

When selecting a Laser Beam Profiler, several considerations should be taken into account, including:

  • Wavelength Range: It is imperative to choose a profiler that is compatible with the wavelength of the laser you are working with.
  • Dynamic Range and Sensitivity: The profiler should have the necessary dynamic range and sensitivity to accurately measure the intensities you are working with.
  • Resolution and Accuracy: The resolution should be high enough to provide the detail required, and the measurements should be accurate.
  • Compatibility and Integration: Ensure that the profiler can be easily integrated into your existing systems.

Conclusion

Laser Beam Profilers are critical tools for any application that involves the use of lasers. By providing detailed information on the spatial intensity distribution, shape, and size of laser beams, these devices play an indispensable role in optimizing performance and ensuring safety. Whether you are involved in industrial manufacturing, scientific research, medical procedures, or telecommunications, selecting the right Laser Beam Profiler is essential for achieving optimal results.

Did You know?

The CCD/CMOS camera based profilers provide a 3D representation of the beam. Camera-based beam profiling systems consist of a camera and analysis software. The software includes an extensive set of ISO quantitative measurements and features a rich graphical interface, for high accuracy measurements. The advantage of camera-based beam profiling is the real-time viewing and measuring of laser beam structure. The spatial resolution of a camera sensor is an important quantity. With silicon sensors, pixel sizes well below 10um are possible, allowing to measure beam diameters down to the order of 50um. Different wavelength regions require different sensor types. Silicon-based sensors are a good choice for wavelengths in the visible and near-infrared spectral region up to roughly 1 or 1.1um.