As bandwidth usage intensifies, costs of fiber optic cable continue to decrease and emerging technologies demand faster speeds and more reliable connectivity, fiber cable is becoming a practical solution for many cabling projects.
Before you decide for sure that fiber is the right way to go for your project, there’s another decision to make: Do you need singlemode or multimode fiber?
One isn’t superior to the other – each has its own place within the right applications. But knowing the differences can prevent you from investing in the wrong type of cable or using a cable that isn’t compatible with your optical fiber devices, which can negatively impact the signal.
Here, we’ll walk you through the differences when comparing singlemode vs. multimode fiber to help you make the best choice.
When comparing how singlemode and multimode fiber are manufactured, there’s one big differentiator: Singlemode fiber’s core size is smaller and carries light directly down the fiber (it only allows the fundamental mode of light to transmit down the fiber). As a result, light reflection created during light transmission decreases, lowering attenuation and allowing the signal to successfully travel over longer distances.
Multimode’s core size is five to six times larger in diameter than singlemode, which allows for much greater light-gathering capacity and facilitates the use of cheaper electro-optic devices. Multiple modes or light paths travel down the fiber at once, which has traditionally limited transmission distance and bandwidth – but this is being considered as a modulation format for “few-mode” fiber, which we aren’t discussing here.
Because multiple modes/light paths travel down a multimode fiber cable, it only offers high bandwidth over a short distance.
When run over longer distances, modal dispersion (distortion) becomes an issue. This is typically expressed in a fiber’s “effective modal bandwidth” characteristic, which is an inverse relation between fiber bandwidth and reach distance. As signaling bandwidth increases, the reach distance decreases – and vice versa – due to the modal dispersion effect.
In singlemode fiber, all light from a pulse travels at about the same speed and arrives at roughly the same time, eliminating the effects of modal dispersion found in multimode fiber. This supports higher bandwidth levels with less signal loss over longer distances. It’s ideal for long-haul signal transmission applications, such as across or between campuses, undersea or in remote offices. There are essentially no distance limitations.
Currently, singlemode fiber is typically less expensive than multimode fiber, but it’s important to keep other price factors in mind as well.
Most fiber systems use transceivers, which combine a transmitter and receiver into a single module using fiber optic technology to send and receive data over an optical network. Right now, the price of multimode transceivers is two or three times lower than the price of singlemode transceivers.
As transceiver prices come down, however, singlemode is starting to be used more often in shorter-distance applications as a cost-effective choice.
Each type of singlemode fiber features its own characteristics. Depending on operating wavelengths, distance and transmission link architecture (which may include various amplification methods), there are different considerations to take into account before making a selection.
As fiber electronics technology changes and improves – including modulators, lasers, PHYs, transceivers, etc., which make up a complete fiber cable system – singlemode and multimode fiber cables must improve as well.
To ensure you get exactly what you need, we recommend working with a systems architect that can help you design a fiber system based on length budgets, number of network clients and where your data sources will be hosted.
Have questions about your next fiber project? Send us a note. We’ll provide the answers you need!
Jim Zimnicki has worked with Belden for more than seven years in cable manufacturing, engineering and product development. After serving as an intern at Belden, he joined the team full time in August 2017. As a product development engineer, Jim oversees designs to meet customer and new business criteria, assesses test data for standards compliance and supports Belden manufacturing trials. He has a Bachelor of Electrical Engineering and recently earned his Master of Science in Electro-Optics from University of Dayton.