Multi-Wavelength Laser

Item Code: 40A-52A-64A-78A-16-NT-NF
Diode SMA port
Preliminary
Product specifications are subject to change, delivery time is less predictable.
Full production
Product specifications are stable. Delivery time is predictable.
Replacement in due course
The product is to be replaced. Please contact us regarding forseeable changes
Not for new designs
The product is to be discontinued. Please contact us for production plans.
Orders still accepted, deliveries still possible
The product will be discontinued soon but we still have some stock of finished items or neccessary components.
No more orders accepted
Some products might be reserved for in-warranty replacement and outstanding orders.
Discontinued
The product is no longer available. Please contact us regarding alternatives or custom solutions.
Available (in stock) Not in stock

Description

A multi-wavelength laser featuring 4 laser diodes integrated within an ultra-compact 'Matchbox' housing with an SMA port (for MM fiber). Experience a breakthrough in research with our widely configurable 4-Wavelength Laser Combiner—a compact powerhouse set to transform life sciences and fluorescence applications. Seamlessly integrating four distinct wavelengths into a single housing, this device ensures unparalleled convenience without sacrificing performance.

Features:
  • Four wavelengths
  • Plug-and-play
  • Single user interface for all 4 wavelengths
Advantages:
  • Space-saving design
  • No optics realignment
  • Remote PC control

Last edited on: 21 May 2024
Parameter Minimum Value Typical Value Maximum Value
 Output power, mW - 405 nm - 100
520 nm - 70
638 nm - 100
785 nm - 100
-
 Wavelength tolerance, nm 400
515
635
782
405
520
638
785
410
530
641
788
 Longitudinal modes - Multiple -
 Spectral line width FWHM, nm - 1 2
 Fiber core diameter, μm - 105 μm, 200 μm, 400 μm (+/- 2 %) -
 Power stability, % (RMS, 8 hrs) 1 - 0.2 1
 Intensity noise, % (RMS, 20 Hz to 20 MHz) 2 - 0.2 1
 Transversal modes - multimode (top-hat-like) -
 Control interface type 3 - UART -
 Operation mode - ACC (CW) -
 Modulation bandwidth, MHz 4 - 10 -
 Input voltage, VDC 8 9 12
 External power supply requirement - +9 V DC, 1.5 A +12 V DC, 1.5 A
 Dimensions (WxDxH), mm - 50 x 30 x 18 -
 Heat-sinking requirement, °C/W - <0.5 -
 Optimum heatsink temperature, °C - 25 -
 Warm up time, mins (cold start) - < 1 min -
 Temperature stabilization - Internal TEC -
 Overheat protection - Yes -
 Storage temperature, °C (non-condensing) - - -
 Net weight, kg - 0.2 -
 Max. power consumption, W - 2 -
 Warranty, months (op. hrs) 5 - 14 (10000) -
 RoHS - Yes -
 CE compliance - - General Product Safety Directive (GPSD) 2001/95/EC - (EMC) Directive 2004/108/EC -
 OEM lasers are not compliant with - IEC60825-1:2014 (compliant using additional accessories) -

1 The long term power test is carried out at constant laser body temperature (+/-0.1 ‎°C) using an optical power meter with an input bandwidth of 10 Hz. The actual measurement rate has a period of about 20 seconds to 1 minute.

2 Noise level is measured with a fast photodiode connected to an oscilloscope. The overall system bandwidth is from 2 kHz to 20 MHz.

3 The break-out-box AM-C9 can be used for conversion of UART communication to USB.

4 TTL digital modulation up to 10 MHz.

5 Whichever occurs first.

Drawing

None

Drawing of Multi-Wavelength Laser

Flow Cytometry

Flow cytometry is a sophisticated analytical technique widely used in biomedical research and clinical diagnostics. It allows for the simultaneous analysis of multiple physical and chemical characteristics of cells or particles as they flow through a laser beam. By utilizing fluorescence and light-scattering principles, flow cytometry provides valuable insights into cell populations, allowing researchers to study cell morphology, identify cell types, and assess various cellular functions with high-throughput precision.

Confocal Microscopy

Confocal microscopy is a powerful imaging technique used in biological and materials science research. By employing point illumination and a spatial pinhole, confocal microscopy eliminates out-of-focus light, resulting in sharper, high-resolution images. This method enables three-dimensional imaging of specimens with exceptional optical sectioning, making it valuable for studying biological structures and dynamic processes at the cellular and subcellular levels.

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