1 x 8PLC Fiber Splitter, Steel Tube, Bare Fiber 250μm, No Connector, Singlemode
SpecificationsSpecifications
|
Package Style |
Steel Tube,Bare Fiber |
Configuration Type |
1×8 |
|
Fiber Grade |
G.657A1 |
Fiber Mode |
Singlemode |
|
Connector Type |
None |
Split Ratio |
50/50 |
|
Fiber Type |
Ribbon Fiber |
Steel Tube Dimensions(HxWxD) |
0.16"×1.57"x0.16"(4x40x4mm) |
|
Input/Output Fiber Diameter |
250μm |
Input/Output Fiber Length |
1.5m |
|
Insertion Loss |
≤10.3dB |
Return Loss |
≥55dB |
|
Loss Uniformity |
≤0.8dB |
Directivity |
≥55dB |
|
Polarization Dependent Loss |
≤0.2dB |
Temperature Dependent Loss |
≤0.5dB |
|
Wavelength Dependent Loss |
≤0.3dB |
Operating Bandwidth |
1260-1650nm |
|
Operating Temperature |
-40 to 85°℃(-40 to 185°F) |
Storage Temperature |
-40 to 85°℃(-40 to 185°F) |
FeaturesFeatures
The working principle of PLC fiber optic splitter is based on optical waveguide technology. It consists of a series of optical waveguide arrays that achieve optical coupling and segmentation inside the waveguide through optical paths with different lengths. When the optical signal from the input port enters the PLC optical fiber splitter, the optical signal will be divided into multiple output ports according to a specific division method, thereby realizing distributed transmission of the optical signal.
PLC fiber optic splitters have a variety of features and advantages. First, it has low insertion loss and high return loss performance, which can effectively split and transmit optical signals without losing signal strength. Secondly, the PLC fiber optic splitter adopts an all-solid-state design, does not require any power supply and electronic component support, and has high stability and reliability. In addition, PLC fiber optic splitters have wide operating wavelength range and temperature stability, making them suitable for different fiber optic communication standards and environmental conditions.
PLC fiber optic splitters are widely used. First of all, it is often used in distributed sensing networks to distribute optical signals to different optical fiber sensors to monitor and measure different parameters. Secondly, PLC fiber optic splitter plays an important role in fiber optic communication systems, used to distribute optical signals to different receivers or transmitters to achieve distributed connections in fiber optic networks. In addition, PLC fiber optic splitters are widely used in fields such as passive optical networks (PON) and passive optical access networks (FTTH) to achieve efficient transmission and distribution.
In practical applications, PLC fiber optic splitters are available in various types and configurations. Usually, they are classified according to different split ratios and number of ports. Common PLC fiber optic splitters include 1x2, 1x4, 1x8, 1x16, 1x32 and 1x64, etc. Among them, "1x" represents an input port, and "x" represents the number of output ports.
It should be noted that PLC fiber optic splitters need to be handled with caution during use. First, the temperature and humidity of the storage environment should be controlled within an appropriate range to ensure its working stability. Secondly, during installation and connection, excessive bending and stretching of optical fibers should be avoided to avoid affecting the performance and life of the splitter. Finally, regularly inspect and maintain the PLC fiber optic splitter to keep it in good working condition.
To sum up, the PLC fiber optic splitter is an important fiber optic component that plays a key splitting and distribution role in fiber optic communications and network systems. It has the advantages of low insertion loss, high return loss performance, wide operating wavelength range and stability, and is widely used in distributed sensor networks, optical fiber communication systems, passive optical networks and passive optical access networks and other fields. By selecting the appropriate type and configuration, as well as correct installation and usage methods, the role of PLC fiber optic splitters can be fully utilized and the performance and functionality of the fiber optic network can be improved.