Dieses schlitzbasierte M2 Messgerät analysiert Laser mit Wellenlängen von UV bis Fernem IR sehr präzise mittels unterschiedlicher Messköpfe - Silizium, Germanium oder pyroelektrisch. Es bietet ein kompaktes Design, sofortige Ergebnisse, ISO-konforme Messungen und arbeitet in CW- oder kHz- Pulsmodi. Damit eignet sich das Messgerät ideal für die aussagekräftige Analyse von Lasern der meisten Wellenlängen.
Verfahrweg des Messkopfs: 500 mm; USB 2.0-Schnittstelle; M2 Analyse-Software inbegriffen
Model 1740 ModeScan with NanoScan 2s Silicon (Si ) Detector 9mm aperture 5μm slits Si detector 63.5mm diameter head, 9mm entrance aperture, and matched pair of 5.0μm wide slits. Use from 190 to 1100nm wavelengths.Angebot anfragen
Model 1740 ModeScan with NanoScan 2s Germanium (GE) Detector 9mm aperture 5.0μm slits Germanium detector, 63.5mm diameter head, 9mm entrance aperture, and matched pair of 5.0μm wide slits. Use from 700nm to 1.8μm wavelength.Angebot anfragen
Model 1740 ModeScan with NanoScan 2s Pyroelectric Detector 9.0mm aperture 5μm slits. Pyroelectric detector, 63.5mm diameter head, 9mm entrance aperture, and matched pair of 5µm wide slits.Angebot anfragen
When in the laser life cycle is the M2 measurement the most important?
M² measurement is important if the stability of your laser is important to your process. Taking M² measurements on a frequent basis allows you to see if your laser is stable from time to time. If the results of the M² measurement fluctuate and a noticeable change happens over time, this could help identify problems with consistency in the laser and help prevent negative results to your process where the laser is being utilized.Close
Why doesn’t the NanoModeScan “ModeScan Configuration” program remember the COM setting?
It has been observed that on networked computers with security, that in order to keep the COM setting in the NanoModeScan “ModeScan Configuration” program persistent, it needs to be launched with a right-mouse-key-click and select “Run as administrator” in order for it to work OK.Close
Can you change the rotation frequency of the NanoModeScan?
Why does my profile work well while running the NanoScan software but the profile diminishes in the NanoModeScan software?
The NanoScan software starts at a rotation frequency of 10 Hz while the NanoModeScan starts at a rotation frequency of 20 Hz. At the frequency of 20 Hz, less signal is getting to the detector because of the speed of the slit passing over the detector. This makes it look like you are not getting as strong of signal. The NanoModeScan starts at this higher rotation frequency because the NanoScan is meant to pass through the focus of the beam, making the power or energy density higher. This higher power or energy density can over-saturate the NanoScan at 10 Hz.Close
Can the NanoModeScan software export 2D/3D images?
The 2D and 3D profiles are NOT exportable.The NanoScan and NanoModeScan's 2D and 3D images are not actual 2D and 3D profiles of the beam. They are mathematically generated profiles calculated from the 1D profile information. Thus they are not completely accurate profiles.Close
Can a NanoModeScan unit be triggered to capture a pulsed source?
The NanoScan can capture a high repitition rate pulsed laser source but it can not be triggered from the laser itself. To capture a pulsed source on the NanoScan you must choose one of the pulsed settings under the Capture tab. The laser pulse rate must also be greater than 100 kHz.
Why can my M2 unit have an M2 measurement less than 1?
There are two common occurrences when M² results are less than 1. The first and most common of these results from the operator entering the wrong wavelength value. In this case the results are often well below 1, in the .8-.9 range. The second most common cause is due to nominal accuracy tolerances. These are normal and expected. With a 5% M² tolerance results from ~.95 to ~1.05 are possible. Averaging runs will normally return a mean value to something > 1, but not always.
It has been suggested that if the M² results are computed to be < 1 we should display a 1 as the answer. However the algorithms in the NanoModeScan software make computations and report results as the input settings and the beam samples dictate. This is done to provide useful information to the operator rather than to try and conceal the issue.Close
I’ve acquired a NanoModeScan system and I’m trying to operate it on a Windows 10 computer, but it is not working. Why not?
The NanoModeScan systems are not compatible with Windows 10. The software has not been updated yet to support Windows 10. The NanoScan that came with it, though, is supported on Windows 10 64-bit through the NanoScan V2 software. The connection to move the scan head down the rail does not work with Windows 10 yet.Close
What wavelength can the NanoModeScan measure?
The wavelengths that can be measured with the NanoModeScan are limited by the NanoScan detector that is used.
- The Silicon NanoScan’s can measure wavelengths from 190 – 1,100nm
- The Germanium NanoScan’s can measure wavelengths from 700 – 1,800nm
- The Pyroelectric NanoScan’s can measure wavelengths from 190 – 20,000nm
Does the NanoModeScan operate with Windows 10?
This tutorial is presented by Ophir-Spiricon sales engineers - the experts in the field of measuring lasers and in helping you get the most out of your laser beam.
Is your laser's beam profile shaped correctly for your application?
This video teaches the fundamentals of laser beam profiles and discusses the benefits of profiling your laser beam.
Several case studies are presented showing before and after laser beam profiles.
Modern production facilities must constantly increase throughput, at less cost, with less scrap, and with minimum downtime. In this video overview, you will learn how application of new, advanced technology in measurement devices, can help both designers and users of industrial laser systems to optimize and control their processes, so they can accomplish these goals and achieve consistently good results – both in quality and quantity. Read the full article
See for yourself how easy it is to use a NanoScan to measure your laser beam. This 3-minute video shows the NanoScan profiling both a HeNe and a high power laser.
Reducing Production Bottlenecks Using Real Time Laser Beam Measurements
Upgrading NS v2 software from Standard to Professional
What is M Squared? See What Determines the Size of Your Beam Waist
M2 Beam Propagation: Why So Many Different Approaches to Measurement Instrumentation?
LENS 200mm VISPH00237
200mm focal length lens for use 400-700nm wavelength
LENS 400mm VISPH00238
400mm focal length lens for use 400-700nm wavelength
LENS 100 VISPH00093
100 mm focal length lens for use 400–700nm wavelength
LENS 100 NIRPH00094
100 mm focal length lens for use 650–1000 nm wavelength
LENS 200mm NIRPH00239
200mm focal length lens for use 650-1000nm wavelength
LENS 400mm NIRPH00240
400mm focal length lens for use at 650-1000nm wavelength
LENS 100 LIRPH00095
100 mm focal length lens for use 1000–1550nm wavelength
LENS 200mm LIRPH00241
200mm focal length lens for use at 1000-1550nm wavelength
LENS 400mm LIRPH00242
400mm focal length lens for use at 1000-1550nm wavelength
LENS 400 2umPH00224
400mm focal length lens for use at @2μm wavelength
LENS 190 10.6PH00092
7.5-inch focal length lens for use at 10.6μm wavelength
LENS 200 UV-XXXPH00090
200mm quartz lens for use between 245-440 nm wavelengths. Specify use wavelenght in the XXX
LENS 350 UV-XXXPH00091
Optional 350mm quartz lens for use between 245-440 nm wavelengths. Specify use wavelenght in the
XXX item description.
1740 LENS MNTPH00075
Lens mount for users wanting to use their own 25mm diameter lens.
Model 1740 ModeScanPH00447
Rail w/o scan head, small scan head
1740 LENS PREPPH00076
ModeScan custom lens