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Optical Add-Drop Multiplexer (OADM) Explained

optical network wdm multiplexer reconfigurable oadm fiber optic

An Optical Add-Drop Multiplexer (OADM) is a crucial component in Wavelength Division Multiplexing (WDM) optical networks. Let’s break down how it works.

As shown in the figure below, an optical multiplexer combines multiple wavelength signals into a single optical fiber. The same device acts as a de-multiplexer in the reverse direction and separates the signals of different wavelengths.

Optical multiplexer demultiplexer

Figure-1: Optical multiplexer demultiplexer

The core function of an OADM is to selectively add and drop specific wavelengths from a multi-wavelength optical signal, allowing other wavelengths to pass through unaffected. Think of it like a highway off-ramp, but for light signals!

As shown in the figure below, optical ADM drops and adds a selective number of Wavelengths from a WDM signal, while permitting remaining wavelengths to pass through itself. Optical ADM architectures are mainly of three types viz. parallel, serial and band drop.

ADM-Add Drop Multiplexer

Figure-2: ADM-Add Drop Multiplexer

OADM Architectures and Topologies

Optical ADM architectures are mainly of three types:

  • Parallel: (Details not provided in the original text)
  • Serial: (Details not provided in the original text)
  • Band Drop: (Details not provided in the original text)

Typically, OADMs are deployed in linear or ring topologies within optical networks. Figure-2 depicts a basic Add-Drop Multiplexer setup where 16 channels enter at PORT-1, 8 channels are dropped at PORT-4, and the remaining channels continue through PORT-2. Simultaneously, 4 new channels are introduced into PORT-3 and combined with the signal stream emerging from PORT-2.

Types of Optical ADMs: Fixed vs. Reconfigurable

There are two primary types of Optical ADMs used in WDM optical networks:

  • Fixed OADMs: These are designed to add or drop signals on specific, predetermined WDM channels. They offer a static configuration for dedicated wavelength management.
  • Reconfigurable OADMs (ROADMs): These more advanced OADMs provide the capability to dynamically alter the selected channel route via electronic control along the fiber optic network.

Benefits of Reconfigurable OADMs

ROADMs offer significant advantages:

  • Fault Tolerance: They can reroute optical streams in the event of network faults, minimizing service disruption.
  • Network Upgradability: ROADMs facilitate upgrades to optical networks based on new and different WDM technologies, offering flexibility in evolving network architectures.