FLPD-1270-07-DFB-BTF
Manufacturer/Distributor: FLC Laser Type: DFB

Description:

Manufacturer/Distributor: FLC

Frankfurt Laser Company (FLC), established in 1994, has a rich history of success and innovation in the field of laser technology. FLC's success is driven by its commitment to innovation and its ability to deliver customized solutions tailored to specific customer needs, including hard-to-source and specialized laser diodes. Celebrating its 30th anniversary in 2024, the company reflects on a legacy of technological advancements that have significantly impacted the laser industry. Through consistent innovation and dedication to excellence, FLC has maintained its position at the forefront of laser technology, continually pushing the boundaries of what is possible in the field.

Laser Type: Fiber-Coupled-Laser-Diodes

Fiber coupled lasers are a type of laser system where the laser light is transmitted through an optical fiber. This design integrates a laser source with an optical fiber, allowing the light to be efficiently delivered to a specific location with minimal loss and high precision. The optical fiber acts as a conduit, guiding the laser beam from its source to the desired point of application.

Laser Type: DFB

Distributed feedback (DFB) laser diodes are distinct from other types of lasers, such as Fabry-Perot lasers, due to their ability to produce a single longitudinal mode. This single-mode operation is essential for applications requiring stable and precise wavelengths.

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: FLPD-1270-07-DFB-BTF (Manufacturer/Distributor: FLC Laser Type: DFB Wavelength Range: IR Mode: singlemode ) - FLPD-1270-07-DFB-BTF - singlemode DFB Wavelength 1270nm (Nanometer) Power 0.007W (Watt)