1550nm Single-mode Fiber Collimator (20mm Working Distance)

The fiber collimator from Idealphotonics is pre-aligned and designed to collimate light emitted from an FC/APC connector fiber, with diffraction-limiting performance. These fiber collimators have no moving parts, are compact in structure, and can be easily integrated into existing systems.

780nm AR-coated fiber optic patch cord

Fiber patch cords (also known as fiber connectors) are optical cables with connector plugs installed on both ends to achieve active connection of optical paths. Both ends of our fiber patch cords are high-quality, narrow-pin ceramic FC/AFC connectors. The fiber end faces of this fiber patch cord are coated with anti-reflection coating. Produced by our equipment, each patch cord is individually tested at the test wavelength listed on the specification label to ensure the extinction ratio and low back reflection (return loss) when connecting fibers to fibers.

1060nm ASE broadband light source 10mW

The 1060nm band ASE broadband light source is based on ytterbium-doped fiber and semiconductor pump laser, with a spectrum covering 1030~1080nm, and can also be extended to 1010nm and 1100nm bands, with high output power and good flatness. It can be used for fiber device testing, FBG grating production, etc.

Anti-Resonant Hollow Core Fibers

Optical signal in hollow core anti-resonant fibers propagates in an air core surrounded by single ring of anti-resonant tube elements. Guidance is based on an anti-resonance from the thin glass membranes constituted by the non-touching tubes surrounding the hollow core. The extremely low overlap of guided power with the surrounding silica, less than 2x10-5, added to the mode effective area, confers to these fibers design record material non-linearity.

1550nm Single Mode Standard Fiber Coupler Mini

Idealphotonics' mini 1x2 (2x2) single-window broadband fiber couplers provide high performance and high reliability over broadband with precise optical signal splitting ratios in a small or sub-miniature package. These couplers have excellent uniformity, low loss, and very low polarization sensitivity, and are available in a variety of splitting ratios, wavelength ranges, fiber types, and connector options. All devices can handle high optical powers up to 4W and are tested according to industry standard procedures. Reliability is guaranteed through rigorous testing to fully meet the requirements of Telcordia GR-1221. We can provide custom designs to meet specialized functional applications. We also offer full environmental testing options. This is a special option for fiber optic systems in aerospace grade applications.

635nm FC/PC Fixed Fiber Collimator with NA 0.37 and Focal Length of 10.1mm.

Idealphotonics' fiber collimators are pre-aligned and designed to collimate light emerging from FC/APC connector fibers, with the added feature of minimizing diffraction. These fiber collimators have no moving parts, making them compact and easy to integrate into existing setups. Due to the chromatic aberration caused by the aspherical lens, the effective focal length (EFL) is wavelength-dependent. The design wavelength corresponds to the wavelength that aligns with the ideal divergence angle of the beam. Collimators at certain design wavelengths may have different collimated beam diameters. When connected to specific single-mode fiber jumpers, they can collimate light at the design wavelength. Additionally, the aspherical lenses are coated with anti-reflection coatings on both sides to minimize surface reflection (please refer to the anti-reflection coating curve label). For certain applications, these collimators can also be used at other wavelengths within the anti-reflection coating's wavelength range. Please refer to the theoretical divergence angle curves for each collimator to determine if it suits your application. These collimators are stable within a temperature range from -40°C to 93°C. Please note that these collimators are not suitable for use in a vacuum. For custom alignment wavelengths, operating temperatures, or vacuum compatibility, please contact us for customizatio

635nm FC/APC Fixed Fiber Collimator with NA 0.37 and Focal Length of 10.1mm.

Idealphotonics' fiber collimators are pre-aligned and designed to collimate light emerging from FC/APC connector fibers, with the added feature of minimizing diffraction. These fiber collimators have no moving parts, making them compact and easy to integrate into existing setups. Due to the chromatic aberration caused by the aspherical lens, the effective focal length (EFL) is wavelength-dependent. The design wavelength corresponds to the wavelength that aligns with the ideal divergence angle of the beam. Collimators at certain design wavelengths may have different collimated beam diameters. When connected to specific single-mode fiber jumpers, they can collimate light at the design wavelength. Additionally, the aspherical lenses are coated with anti-reflection coatings on both sides to minimize surface reflection (please refer to the anti-reflection coating curve label). For certain applications, these collimators can also be used at other wavelengths within the anti-reflection coating's wavelength range. Please refer to the theoretical divergence angle curves for each collimator to determine if it suits your application. These collimators are stable within a temperature range from -40°C to 93°C. Please note that these collimators are not suitable for use in a vacuum. For custom alignment wavelengths, operating temperatures, or vacuum compatibility, please contact us for customizatio

760nm High Power Single Mode DFB Laser (20mW, TO39 Package, Oxygen Detection)

With optimized optical characteristics, the 760nm single-mode DFB laser is an ideal choice for high-demand sensor system applications. The innovative chip design suppresses higher-order longitudinal and transverse modes, while maintaining stable linear polarization. The laser offers high output power, narrow linewidth, and excellent consistency, making it highly favored by domestic research customers. Currently, we have stock of the 760nm DFB laser for TDLAS oxygen detection, the 795nm VCSEL for Rubidium atomic clock experiments, and the 852nm VCSEL for Cesium atomic cooling.

Single-mode wedge lens fiber (including Angle 75 degrees R Angle 5um mirror ridge chamfer 25um)

Lens fiber, also known as fiber lens or fiber microlens, is a type of product that is processed into a fiber end face with lens function. The main functions of lens fiber are to change the size and shape of the fiber mode field to improve the system coupling efficiency, change the optical transmission path, reduce refracted light, and change the tip shape to adapt to imaging and sensing in different environments. It has a wide range of applications in many fields. Idealphotonics can customize multiple types of optical fibers according to the different requirements of lens fibers in different fields and customize the surface metallization of optical fibers according to customer requirements. Compared with products on the market, Idealphotonics lens fiber has the advantages of smaller cone angle error and smaller eccentricity. At the same time, all lens fibers can be metallized + tube shell gold tin packaging according to customer requirements, as follows

1550nm tunable VCSEL vertical cavity surface emitting laser (with TEC)

1550nm VCSEL is a vertically emitting MOVPE grown GaAsP/AlGaAs single mode diode laser. Wavelength tuning can be achieved by laser current and temperature tuning. Built-in TEC and PD

1480/1550nm Single-Mode Wavelength Division Multiplexer FC/PC

IdealPhotonics’ tapered wavelength division multiplexing (WDM) products for optical communication feature low loss, low polarization-dependent loss, a wide operating wavelength and temperature range, and an epoxy-free optical path. This series of products is suitable for use in WDM systems, fiber sensing systems, and fiber optic testing equipment.

1X5 Single-mode Fiber Coupler Module 1392nm

IdealPhotonics' 1310nm/1392nm single-mode fiber coupler module adopts a method of multiple tapered single-mode fibers, effectively reducing the insertion loss of our module.