Things You Should Know About WDM Filter

Posted on by FS.COM

The optical devices most often used to selectively transmit certain wavelengths are called filter, which covers a broad range of devices, including attenuators. Filters play important roles in Wavelength Division Multiplexing(WDM) systems, although other technologies also may be used. WDM Filters can separate or combine optical signals carried on different wavelengths in a cost-effective manner.

In the world of optics, “filter” often is a broad term applied to components that filter out part of the incident light and transmit the rest. In WDM systems, the wavelengths that are not transmitted through the filter normally are reflected so they can go elsewhere in the system. Such filters are like mirror shades or one-way mirrors, which reflect most incident light, but transmit enough for you to see through them.

Common optical filters accommodate channel growth without service interruption. In addition, the filters’ low network-to-express loss allows stacking, which is essential for scaling new wavelengths. Most filters are equipped with an express port to pass through non-dropped/added WDM channels. Interconnecting express ports of two filters forms an Optical Add/Drop Multiplexer (OADM) with east/west fiber connections. High filter isolation eliminates disruptive “shadow” wavelengths and allows channels that have been dropped at a node to be used elsewhere downstream.

Interference filters and other technologies can be used to separate and combine wavelengths in WDM systems. Several approaches are now competing for WDM applications, some technologies appear to have advantages for certain types of WDM systems, but the field is still evolving, and no single approach dominates. Although these technologies work in different ways, they can achieve the common goal of optical multiplexing and demultiplexing.

There are three competing filtration technologies: Thin Film Filters (TFF), Array Waveguides (AWG), and Fiber Bragg Gratings (FBG). Thin film filters were adopted very early and have been widely deployed because they have the unique attributes that meet the stringent requirements of optical communication systems.

Wide band WDM filters – They are used in EDFAs as pump couplers and supervisory channel monitors. This family of filters covers a wide variety of other filters. Their applications range from CWDM (Coarse WDM), to bi-directional transceivers, to 1310/1490/1550 nm tri-band filters for fiber to the home (FTTH).

Fiber Bragg gratings work similarly by reflecting specific wavelengths. WDM applications require the use of many interference filters or fiber gratings, with each one picking off an individual wavelength or group of wavelengths.

FTTX Filter WDM module is based on thin film filter technology. FiberStore Filter-Based WDM product family covers following wavelength windows commonly used in optical fiber systems: 1310/1550nm (for WDM or DWDM optical communications), 1480/1550nm (for high-power DWDM optical amplifier/EDFA), 1510/1550nm (for DWDM multi-channel optical networks) and 980/1550nm (for high performance DWDM optical amplifier/EDFA) and 1310/1490/1550nm (for PON/FTTX/test instrument). Compared with fused fiber WDM couplers, filter-based WDM components have much wider operating bandwidth, lower insertion loss, higher power handling, high isolation, etc.

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