FPD-XXXS-976-YY-DBR ()
Manufacturer/Distributor: FLC
Laser Type: DBR
Description:
Manufacturer/Distributor: FLC
The Frankfurt Laser Company (FLC) is a renowned enterprise based in Germany, specializing in the development, production, and distribution of advanced laser technologies. Established in 1994, FLC has become a prominent player in the laser industry, known for its commitment to quality and innovation. The company's product portfolio focuses on three main areas: Laser Diodes, Laser Modules, and Diode-Pumped Solid-State (DPSS) Lasers. These cutting-edge products cater to a diverse range of applications, from industrial manufacturing and medical treatments to scientific research and defense. FLC's expertise and dedication to meeting the specific needs of its clients make it a trusted name in the world of laser technology.
Laser Type: CW-Laser-Diodes
Continuous-wave (CW) laser diodes excel in telecommunications, medical applications, industrial processing, and scientific research due to their ability to produce a continuous, stable laser beam, ensuring precise, reliable, and consistent performance. Their versatility and efficiency make them invaluable in various fields, including consumer electronics, printing, imaging, and metrology.
Laser Type: Fiber-Coupled-Laser-Diodes
Fiber coupled lasers ensure efficient and precise light delivery by integrating the laser source with an optical fiber, minimizing losses and maintaining beam quality over long distances. Their compact, robust design allows for flexible routing, easy system integration, superior beam quality, enhanced safety, and effective thermal management.
Laser Type: Laser-Diode
A laser diode is a semiconductor device that emits coherent light when an electrical current passes through it.
Laser Type: Wavelength-Stabilized-Laser-Diodes
Wavelength-stabilized laser diodes are critical components in numerous high-precision applications due to their ability to maintain a stable emission wavelength. This stability is achieved through the use of feedback mechanisms, temperature control, and precise design, ensuring consistent performance even under varying environmental conditions.
Laser Type: DBR
Distributed Bragg Reflector (DBR) laser diodes offer a combination of stability, precision, and efficiency that is highly beneficial for both industrial and research-oriented applications.
Wavelength Range: IR
Wavelength Range: Infrared radiation typically spans wavelengths from about 700 nanometers (nm) to 1 millimeter (mm). This range can be further subdivided into near-infrared (NIR), mid-infrared (MIR), and far-infrared (FIR). Near-Infrared (NIR): 700 nm to 1.4 micrometers (µm) Mid-Infrared (MIR): 1.4 µm to 3 µm Far-Infrared (FIR): 3 µm to 1 mm
Mode: singlemode
Singlemode lasers are particularly useful in applications requiring precise control of the light beam. In optical communication, their high coherence and narrow beam allow for efficient coupling into optical fibers, which reduces signal loss and enables long-distance communication. In high-precision measurement systems, singlemode lasers provide the accuracy needed for applications such as interferometry, spectroscopy, and metrology. They are also ideal for sensing and imaging applications due to their focused and coherent beam, making them suitable for high-resolution imaging and precise sensing applications, including LIDAR and biomedical imaging. Furthermore, singlemode lasers are frequently used in scientific research, particularly in laboratories for experiments requiring precise and stable light sources, such as atomic and molecular spectroscopy. The design of singlemode lasers typically involves specific structural considerations, such as a small core size or a precise refractive index profile, to support only the fundamental transverse mode and ensure high beam quality and coherence.
This article refers to: FPD-XXXS-976-YY-DBR () (Manufacturer/Distributor: FLC Laser Type: DBR Wavelength Range: IR Mode: singlemode ) - - singlemode DBR Wavelength 976nm (Nanometer) Power 0.28W (Watt)
- FLC
- DBR
- IR
- singlemode