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What Is an Optical Splitter?

Updated on Jun 24, 2024 by
120.7k

In today's optical network topologies, the advent of fiber optic splitter contributes to helping users maximize the performance of optical network circuits. Fiber optic splitter, also referred to as optical splitter, fiber splitter or beam splitter, is an integrated waveguide optical power distribution device that can split an incident light beam into two or more light beams, and vice versa, containing multiple input and output ends. Optical splitter has played an important role in passive optical networks (like EPON, GPON, BPON, FTTX, FTTH, etc.) by allowing a single PON interface to be shared among many subscribers.

What Is Optical Splitter?

In today's optical network topologies, the advent of fiber optic splitter contributes to helping users maximize the performance of optical network circuits. Fiber optic splitter, also referred to as optical splitter, fiber splitter or beam splitter, is an integrated waveguide optical power distribution device that can split an incident light beam into two or more light beams, and vice versa, containing multiple input and output ends. Optical splitter has played an important role in passive optical networks (like EPON, GPON, BPON, FTTX, FTTH, etc.) by allowing a single PON interface to be shared among many subscribers.

How Does Optical Splitter Work?

Generally speaking, when the light signal transmits in a single mode fiber, the light energy cannot be entirely concentrated in the fiber core. A small amount of energy will be spread through the cladding of the fiber. That is to say, if two fibers are close enough to each other, the transmitting light in an optical fiber can enter into another optical fiber. Therefore, the reallocation technique of optical signal can be achieved in multiple fibers, which is how fiber splitter comes into being.

How Does Optical Splitter Work

Specifically speaking, the passive optical splitter can split, or separate, an incident light beam into several light beams at a certain ratio. The 1x4 split configuration presented below is the basic structure: separating an incident light beam from a single input fiber cable into four light beams and transmitting them through four individual output fiber cables. For instance, a 1:4 splitter will equally divide the input optical signal energy into 4 parts, with each part having an optical power that is 1/4 of the original input signal power.

How Does Optical Splitter Work?

Currently, various types of splitters with multiple branches are available on the market, such as 2x8, 2x32, 2x64, etc. The optical splitter with 2x64 split configurations is a little bit more complicated than the 1x4 split configurations. There are two input terminals and sixty-four output terminals in the optical splitter in 2x64 split configurations. Its function is to split two incident light beams from two individual input fiber cables into sixty-four light beams and transmit them through sixty-four individual output fiber cables. With the rapid growth of FTTx worldwide, the requirement for larger split configurations in networks has increased to serve mass subscribers.

Normally, fiber splitters have an even split ratio. However, with the rapid development of splitter applications in various scenarios, such as in some FTTR or rural practical applications, equally splitting splitters are not necessarily the optimal choice. In order to further improve the utilization of customer ports and save fiber resources, unbalanced splitters with non-equal splitting ratios are also experiencing rapid growth. Taking the FS 1x5 unbalanced PLC splitter as an example, it can allocate 20%, 33%, 50%, 75%, or 95% optical power for CH1, while the remaining four channels evenly split the remaining optical power, thus maximizing resource utilization.

How Does Optical Splitter Work?

Optical Splitter Types

Classified by Package Style

The optical splitter can be terminated with different forms of connectors, and the primary package could be box type or stainless tube type. Fiber splitter box is usually used with 2mm or 3mm outer diameter cable, while the other is normally used in combination with 0.9mm outer diameter cables. Besides, it has variously different split configurations, such as 1x2, 1x8, 2x32, 2x64, etc. FS PLC splitters are mainly divided into six series: bare PLC splitter, blockless PLC splitter, ABS PLC splitter, LGX box PLC splitter, FHD Box PLC splitter, and 1U Rack Mount PLC splitter.

 Series  Photo  Advantage  Application
 Bare PLC  

PLC

Compact design, minimal space occupation, low installation cost Requires comprehensive protection, typically used in FTTH, PON, LAN, CATV, and testing equipment.
 Blockless PLC
 
 

PLC

Stainless steel tube packaging provides stronger fiber protection Mainly used for different connections above distribution boxes or network cabinets.
 ABS PLC  

PLC

Provides effective protection for internal optics and cables, adaptable to various installations. Widely used for outdoor fiber distribution boxes in PON, FTTH, FTTX, and GOPN networks.
 LGX box PLC  

PLC

 Equipped with a sturdy metal box, plug-and-play.
Can be used standalone or installed in standard fiber distribution frames or fiber enclosures.

PLC

Compact structure, can be integrated into a 1U platform for fiber management.
Commonly Found in POL, Datacom, LAN, CATV, LCP, FTTx projects.

PLC

Adhering to the 19-inch rack unit standard, it offers excellent optical performance and easy installation.
Suitable for high-density wiring environments, widely used in EPON, GPON, FTTX, FTTH, and other fields.

For more details, please refer to How Many Fiber Optic Splitter Types Are There?

Classified by Transmission Medium

According to the different transmission mediums, there are single mode optical splitter and multimode optical splitter. The multimode optical splitter implies that the fiber is optimized for 850nm and 1310nm operation, whereas the single mode one means that the fiber is optimized for 1310nm and 1550nm operation. Besides, based on working wavelength differences, there are single window and dual window optical splitters. The former is to use one working wavelength, while the latter fiber splitter is with two working wavelengths.

Classified by Manufacturing Technique

FBT splitter is based on traditional technology to weld several fibers together from the side of the fiber, featuring lower costs. The PLC splitter is based on planar lightwave circuit technology and offers a variety of split ratios. For example, the FS ABS PLC Splitter is available in configurations such as 1x2, 1x4, 1x16, 1x32, and 1x128.

Check the following PLC Splitter vs FBT Splitter Comparison Chart:

Type PLC Splitter FBT Coupler Splitters
Operating Wavelength 1260nm-1650nm (full wavelength) 850nm, 1310nm, 1490nm and 1550nm
Splitter Ratios Equal splitter ratios for all branches Splitter ratios can be customized
Performance Good for all splits, high level of reliability and stability Up to 1:8 (can be larger with higher failure rate)
Input/Output One or two inputs with an output maximum of 64 fibers One or two inputs with an output maximum of 32 fibers
Housing Bare, Blockless, ABS module, LGX Box, Mini Plug-in Type, 1U Rack Mount Bare, Blockless, ABS module
 

How to Choose the Right Fiber Splitter?

In general, a superior fiber optic splitter needs to pass a series of rigorous tests. The performance indicators that will affect the fiber optic splitter are as follows:

  • Insertion loss: Refers to the dB of each output relative to the input optical loss. Normally, the smaller the insertion loss value, the better the performance of the splitter.

  • Return loss: Also known as reflection loss, refers to the power loss of an optical signal that is returned or reflected due to discontinuities in the fiber or transmission line. Normally, the larger the return loss, the better.

  • Splitting ratio: Defined as the output power of the splitter output port in the system application, which is related to the wavelength of the transmitted light.

  • Isolation: Indicates a light path optical splitter to other optical paths of optical signal isolation.

Besides, uniformity, directivity, and PDL polarization loss are also crucial parameters that affect the performance of the beam splitter.

For the specific selections, FBT and PLC are the two main choices for the majority of users. The differences between FBT splitter vs PLC splitter normally lie in operating wavelength, splitting ratio, asymmetric attenuation per branch, failure rate, etc. Roughly speaking, the FBT splitter is regarded as a cost-effective solution. PLC splitter featuring good flexibility, high stability, low failure rate, and wider temperature ranges can be used in high-density applications. To know more about FBT and PLC splitter, you can read this article: FBT splitter vs PLC splitter.

For the expenses, the costs of PLC splitters are generally higher than the FBT splitter owing to the complicated manufacturing technology. In specific configuration scenarios, split configurations below 1×4 are advised to use FBT splitter, while split configurations above 1×8 are recommended for PLC splitters. For a single or dual wavelength transmission, FBT splitter can definitely save money. For PON broadband transmission, PLC splitter is a better choice considering future expansion and monitoring needs.

Learn more: FBT Splitter vs. PLC Splitter: What Are the Differences?

Concluding Remarks

Optical splitters enable a signal on an optical fiber to be distributed among two or more fibers. Since fiber splitters contain no electronics nor require power, they are an integral component and widely used in most fiber-optic networks. Thus, choosing fiber optic splitters to increase the efficient use of optical infrastructure is key to developing a network architecture that will last well into the future.

FS can provide high-quality, customized PON network solutions tailored to your needs. If you have any questions about PON networks or need assistance with selecting a fiber splitter, please feel free to contact us.

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