To meet the ever-increasing need for faster data transmission rates and improved network performance, fiber optics is a continuously developing technology. An example of this is the OM5 Wideband Multimode Fiber (WBMMF) optical cable. The OM5 cable has been designed to support Shortwave Wavelength Division Multiplexing (SWDM), which greatly increases its bandwidth capacity compared to previous versions. This paper will explore what sets OM5 apart from other types of multi-mode fiber in terms of technology, discuss how it is built and why this matters for operation, and look into future implications for network infrastructures. Such knowledge will enable industry professionals to make better decisions when designing and implementing high-performance optical networks, considering such disparities.
What is OM5 Fiber, and How is it Different from Other Multimode Fibers?
What is OM5 Fiber?
OM5 Fiber also called Wideband Multimode Fiber (WBMMF) is an upgraded version of multimode optical fiber that supports new multiplexing technologies mainly Shortwave Wavelength Division Multiplexing (SWDM). Unlike OM1, OM2, OM3, and OM4 fibers, which work at 850 nm wavelength conventionally, the operational range of OM5 fiber extends from 850nm to 953nm. With this extension in range, multiple wavelengths can be transmitted simultaneously over a single fiber, thus substantially increasing bandwidth capacity without additional fibers being required. Fundamentally, what this means is that with better data transmission rates offered by it and improved network efficiency, next-generation high-performance networks cannot do without this product.
How does OM5 Fiber Compare to OM3 and OM4 Fibers?
The main difference between OM5 fiber and OM3 or OM4 is that it supports Shortwave Wavelength Division Multiplexing (SWDM) and has a longer operating distance. Below are the key comparisons:
Wavelength Range:
- OM3 and OM4: Works well at 850 nm.
- OM5: Increases the operational wavelength range from 850 nm to 953 nm.
Bandwidth Capacity:
- OM3: Has a modal bandwidth of 2000 MHz*km at 850 nm.
- OM4: Provides a modal bandwidth of 4700 MHz*km at 850 nm.
- OM5: It provides the same modal bandwidth as OM4 of 4700 MHz*km at 850 nm but improves overall capacity through added wavelength range supporting SWDM.
Data Transmission Rates:
- OM3: Can support up to distances of 300 meters for speeds of 10 Gb/s.
- OM4: Can support up to distances of550 meters for speeds of10 Gb/s
- OM5: Supports higher data rates by allowing four wavelengths (from 850 nm to953nm) to transmit10 Gb/seach, thus delivering40Gb/sover the same length offiberoptic cable.
Future-Proofing and Network Efficiency:
- OM5: To this effect, it allows future network expansions more efficiently by reducing fibers required thereby optimizing current infrastructure for next-generation applications.
Why Choose OM5 Multimode Fiber?
The OM5 multimode fiber is a great improvement in data transmission technology that was created to address the needs of fast networks. The main feature that sets it apart from the others is its compatibility with Shortwave Wavelength Division Multiplexing (SWDM) which allows for more data capacity and faster transfer rates without using extra fibers. Because of this development, systems can process larger amounts of information quickly by utilizing several wavelengths across 850 nm to 953 nm – up to four times wider than what can be achieved with OM3 or OM4 fibers alone. What’s more, OM5 fiber also has the ability to future-proof network infrastructure, hence ensuring continued usefulness in line with advancing technologies, making it an essential investment for any business looking forward to optimizing their current and next-generation networking capabilities.
How Does OM5 Fiber Work in Data Transmission?
OM5 Fiber’s Transmission Capabilities
It is through Shortwave Wavelength Division Multiplexing (SWDM) technology that OM5 fiber is able to achieve data transmission efficiency. Specifically, this means that it can use many different waves to send information. This involves a range of 850nm – 953nm wavelengths being multiplexed so as to increase the amount of data that can be transmitted by OM5 fiber, which can be up to four times greater than what OM3 or OM4 fibers can provide in terms of throughput rates and bandwidth capacity. Moreover, while being backward compatible with currently deployed multimode fibers, OM5 also offers seamless integration into them, thereby ensuring better performance as well as readiness for future network requirements.
Bandwidth and Data Rates in OM5 Fiber
This technology works by using SwDM to achieve higher bandwidth and data rates through OM5 fiber. It is able to do this because OM5 can support four different wavelengths at 850 nm, 880 nm, 910 nm, and 953 nm. This means that it can transmit more information over the same cable at once. These are some of the technical characteristics produced by these new wavelengths:
- Range: 850nm-953nm.
- Wavelengths: Four.
- Capacity: Up to four times as much as an OM3 or OM4 fiber optic line.
- Speed Increase: From ten gigabits per second per wavelength (total forty gigabits) for one hundred meters on OM3 up to one hundred gigabit capacity over that distance with an OM5.
What these numbers mean is that you can push more data faster down a single strand of fiber with this stuff than ever before, making it perfect for current-day high-speed networks where we have insatiable appetites for bytes. Not only does it allow us to process bits more quickly, but it also guarantees we won’t experience any slowdowns on our end as demand continues its exponential growth pattern toward infinity and beyond! So if you’ve got lots of multicore cables lying around, don’t worry about them. Just grab some new ones designed specifically for use in environments like this; they’ll work great alongside whatever else is already there, too, so there is no need to tear everything down and start from scratch again, either.
OM5 Fiber in High-Speed Ethernet Networks
The high-speed Ethernet networks have included OM5 fiber to meet the requirement of higher bandwidth and quicker data rates. The capacity of the fiber to use Shortwave Wavelength Division Multiplexing (SWDM) technology is vital for satisfying these needs. In other words, using four different colors, OM5 can increase the amount of data that can be sent through one cable so that it could reach up to 100 Gbps per 100 meters.
This development is particularly useful in enterprise networks and data centers where there must be a fast transmission with a large capacity. Also, the backward compatibility of OM5 fibers with existing multimode fibers such as OM3 and OM4 means that no big changes have to be made in infrastructure during migration. At the present time, ethernet technologies are moving towards higher speeds like 200 Gbps or even more than double this number – 400 Gbps; therefore, we need an efficient solution that will allow us to grow further while meeting our current requirements but also being able to adapt easily when needed later on – this is what exactly om5 fiber provides us with today already.
What are the Compatible Transceivers for OM5 Fiber?
Multimode Transceivers and OM5 Fiber
The OM5 optic fiber is consistent with a number of multimode transceiver modules like those designed for OM4 and OM3 fibers. Below are typical compatible transceivers:
- Small Form-Factor Pluggable Plus (SFP+): Suitable for 10 Gbps Ethernet applications.
- Quad Small Form-Factor Pluggable Plus (QSFP+): Ideal for 40 Gbps Ethernet applications.
- QSFP28: Supports 100 Gbps Ethernet applications.
In so doing, these utilize SWDM or Shortwave Wavelength Division Multiplexing technologies as a way to make use of the increased bandwidth capacity of optical multimode fiber technology. This therefore leads to better rates in data transmission as well as compatibility with older multimode fiber infrastructures.
OM5 Fiber and SWDM Technology
The purpose of OM5 fiber is to improve the efficiency of Shortwave Wavelength Division Multiplexing (SWDM) technology. This means that multiple wavelengths can be sent through a single piece of glass at once, which saves money on installation because you don’t have to lay as many fibers. It’s all about being good for the environment and your wallet.
Here’s how it works:
Wavelength Range
- OM5 fiber supports everything from 850 nm to 953 nm. That’s four times more than any other kind of fiber out there right now! Four channels per strand, each carrying 25 Gbps or better.
Data Rates
- With SWDM integrated into the design specifications, data rates of up to 100 Gbps are possible with distances up to 150 meters – perfect for large data centers.
Capacity
- Imagine if you could take your existing network and make it four times bigger without laying any new cables. That’s what OM5 does when combined with SWDM – expands capacity by a factor of 4 compared to using traditional OM3/OM4 without WDM.
Backward Compatibility
- If you already have an older system running on OM3 or OM4 transceivers then don’t worry because this stuff is backward compatible too! You won’t need to rip everything out and start over again just because some shiny new cables came along…
Improved Link Reach
- What if I told you that you could use your existing links, but they would go twice as far? With OM3 fibers, links up to 550m@10Gbps will still work while allowing higher speeds with OM5… And don’t forget about those super long hauls at lower bandwidths either – up to 1000m is possible with OM4!
So now you’re probably thinking, “OK, where can I buy some?” Well, since its invention in June 2016 by the International Electrotechnical Commission (IEC), this new type of fiber has quickly become an industry standard for future-proofing networks. It’s all about scalability and backward compatibility with existing multimode fiber applications… And when combined with SWDM technology, you get even more performance and efficiency in high-demand data environments – what could be better!?
Using OM5 Fiber with Existing LC and MMF Transceivers
Utilizing OM5 fiber with current multimode fiber (MMF) transceivers and LC connectors is an easy and advantageous process. This compatibility allows operators to exploit the more advanced features of OM5 without having to completely rework their current infrastructures. Here are some key points about the integration:
Seamless Integration:
- The same LC connectors used for OM3 and OM4 fibers can be used to install OM5 fiber. This means that existing transceivers will not have to be replaced, which will lead to less downtime and lower transition costs.
Enhanced Transmission:
- OM5 fiber achieves this by supporting Shortwave Wavelength Division Multiplexing (SWDM) where data can be sent across multiple wavelengths using existing MMF transceivers thus multiplying bandwidth capacity without additional hardware modification.
Cost Efficiency:
- Upgrading from OM3 or OM4 transceiver modules into an enterprise’s network infrastructure incrementally is possible owing its backward compatibility with both types. This method spreads out investments over time hence reducing financial burden associated with complete overhauling of networks while at the same time improving their performance levels.
The use of LC connectors coupled with current MMF transceivers when incorporating OM5 fiber into already established network architectures ensures maximum performance as well as fiscal prudence thereby providing a future-proof solution capable of meeting growing data requirements.
How Does OM5 Fiber Compare to Other Fiber Types?
OM4 vs OM5 Fiber: What’s the Difference?
Both multimode fiber types – OM4 and OM5 can be utilized for high-speed data transmission, though they have significant differences in functionality as well as performance. In general, OM4 fiber is most suitable for use with 10 Gb/s, 40 Gb/s and 100 Gb/s at short ranges and operates mainly at the wavelength of 850 nm. For parallel optics it has a maximum reach of 150 meters for 100 Gb/s.
On the other hand, by adopting Shortwave Wavelength Division Multiplexing (SWDM), OM5 fiber further enhances these properties. This implies that within this type of cable, it becomes possible to send different signals over various wavelengths from 850 nm to 950 nm, thereby greatly increasing its capacity in terms of bandwidth. Additionally, this kind of technology allows for four wavelengths to be supported by OM5, which multiplies data rate without any extra fibers while utilizing SWDM extends its reach up to 150 meters for transmitting at speeds of up to 100Gb/s.
The main advantage offered by the use of multiple concurrent wavelengths on OM5 fibers over its counterparts such as OM4 lies in higher bandwidths provided thus improving efficiency within data centers besides being backward compatible with existing systems based on OM4.
OM1, OM2, OM3, OM4, and OM5: Understanding the Evolution
The growth of multimode fiber (MMF) from OM1 to OM5 represents a major breakthrough in data transmission. Here’s a brief comparison between these types of fibers, showing their technical parameters and justification.
OM1 Fiber:
- Core Diameter: 62.5 micrometers.
- Bandwidth: 200 MHzkm at 850 nm, 500 MHzkm at 1300 nm.
- Maximum Speed: Supports up to 1 Gb/s over shorter distances.
- Typical Uses: Legacy systems, often in older installations.
OM2 Fiber:
- Core Diameter:50 micrometers.
- Bandwidth: 500 MHzkm at 850 nm, 500 MHzkm at 1300 nm.
- Maximum Speed: Supports up to 1 Gb/s over longer distances compared to OM1.
- Typical Uses: Gradually phased out in modern installations.
OM3 Fiber:
- Core Diameter:50 micrometers.
- Bandwidth:1500 MHz*km at 850 nm.
- Maximum Speed: Supports Gb/s up to meters, Gb/s and Gb/s up to meters.
- Typical Uses: Data centers, high-speed networks.
OM4 Fiber:
- Core Diameter:50 micrometers.
- Bandwidth:3500 MHz*km at 850 nm.
- Maximum Speed: Supports Gb/s up to meters,40Gb/s, and Gb/s up to meters.
- Typical uses: High-performance data centers optimized for high-speed transmission.
OM5 Fiber:
- Core Diameter:50 micrometers.
- Bandwidth:2800MHz*km at 850nm, including SWDM capabilities from nm to nm.
- Maximum Speed: Supports multiple wavelengths (up to four) for higher combined data rates, extending capabilities of Gb/s over meters using SWDM.
- Typical uses: Advanced data centers requiring future-proof solutions with enhanced bandwidth.
Each version from OM1 through OM5 has shown substantial improvements in performance such as core diameter consistency, higher bandwidth capacity and maximum supported transmission speed. What sets OM5 apart is the Shortwave Wavelength Division Multiplexing which allows for higher data rates and offers scalability for modern day data environments that require future proofing.
Effective Modal Bandwidth in OM5 Fiber
The fiber’s effective modal bandwidth (EMB) is a very important parameter since it tells you how much data can be transmitted across that medium. It is worth noting that the OM5 fiber has been designed in such a way that it can accommodate Shortwave Wavelength Division Multiplexing (SWDM), which involves sending several wavelengths ranging from 850 nm to 950 nm at the same time. hence this feature alone gives an EMB of 2800 MHz*km when operating at 850 nm thereby allowing better performance over short distances. Additionally, this new type of optic cable has higher efficiency in terms of bandwidth compared to any other preceding model, thus making it suitable for use within high-speed, large-capacity data centers. This increase in capacity will help address current challenges faced by modern networks where demands keep growing every day.
What are the Practical Applications of OM5 Fiber in Modern Networks?
OM5 Fiber in Data Centers
Modern data centers rely on OM5 fiber to scale and meet the growing need for data storage and transmission. This is important because the fiber optic cable provides a high capacity, wide bandwidth solution that can be easily increased as required. Essentially, it makes use of its short wavelength division multiplexing (SWDM) abilities so as not to waste any already laid-down fiber. This increases the general capacity and flexibility of data center networks by a large percentage. It achieves this through supporting data speeds up to 400 Gbps, which allows for many different applications such as cloud computing or virtualization down large-scale analytic processing, among others. Additionally, its longer distance reaches with better modal bandwidth also means that it is perfect for densely populated areas where there are lots of server switches, etc., so reliability at all times should never be compromised due to the speed between devices needed for storage purposes, too.
OM5 Fiber in Telecom and Broadband Providers
For telecom and broadband providers, OM5 fibers offer huge benefits in terms of capacity and efficiency improvement. This means that many waves can be transmitted at once through one fiber by using SWDM technology, hence optimizing bandwidth use and cutting down on the physical infrastructure needed. This makes network expansion less expensive and easier to scale up, which should be considered the main advantage among others. The following are some important technical parameters:
- Bandwidth: Enhanced Modal Bandwidth (EMB) 2800 MHz*km at 850 nm.
- Data Rates: Supports up to 400 Gb/s.
- Wavelength Range: Operates within 850 nm to 950 nm spectrum.
- Reach: Longer reach than OM3 or OM4 fiber due to better modal dispersion properties.
These features enable high speed internet access with wide coverage areas for broadband connections as well as meeting demands for high quality video streaming services among other heavy data applications. With reliable performance characteristics like these, om5fiber will support future-proofing of telecommunications networks beyond today’s needs while still providing fast connection speeds required by current users.
Benefits of OM5 Fiber in Enterprise Networks
Organizations seeking efficient and scalable solutions should adopt OM5 fiber for their enterprise networks because it has many advantages over other types. These include:
- Increased bandwidth: OM5 fiber has an Enhanced Modal Bandwidth (EMB) of 2800 MHz*km which supports higher data rates necessary for high-speed connections and ensures that the network infrastructure remains viable even in future.
- Scalability: Shortwave Wavelength Division Multiplexing (SWDM) can be used to transmit multiple wavelengths through one fibre thus maximizing the utilization of existing cables and minimizing the need for extensive physical infrastructure; this enables businesses to expand their networks easily without disrupting them too much.
- Cost efficiency: Operational costs are diminished when using more efficient fibers such as OM5 since they require less hardware and fewer fibres for achieving similar speeds; hence there is substantial saving on capital expenditure too.
- Extended reach: Compared with predecessors like OM3 or OM4, modal dispersion characteristics of OM5 give it the ability to cover longer distances thus making it ideal for use across wide campuses or multi-building sites.
- Flexibility: Applications ranging from enterprise backbones up through data centers can be supported by wavelengths spanning between 850 nm – 950 nm, accommodative diverse networking requirements while also enabling good quality video streaming & other data-intensive apps.
Therefore, integrating robustness into connection performance by incorporating OM5 fibers into enterprise networks will enhance operational efficiency within organizations, leading to seamless scalability.
How is OM5 Fiber Installed and Maintained?
Installation Guidelines for OM5 Fiber Cable
Paying attention to detail during the installation is important so as to achieve maximum performance and durability of OM5 optical fiber. Below are some essential tips:
Pre-installation planning:
- Evaluate the site comprehensively for possible barriers and establish the shortest cable routes.
- Check that all materials, tools, and equipment used in the installation meet the required standards.
Handling and storage:
- Keep the OM5 optical fiber cables in a clean, dry room with temperature and humidity regulated to prevent spoilage.
- Be gentle with it, avoiding tight bends, extreme twisting, or pulling beyond allowable tension limits.
Cable routing:
- Observe correct methods of routing to avoid physical damage; where necessary use protective conduits or trays.
- The minimum bend radius should be maintained as indicated so as not to interfere with its integrity or affect functionality.
Splicing & Termination:
- For termination or splicing of OM5 fiber optic cables low loss connection should be achieved through precise machines’ application.
- It’s mandatory to test each joint after doing thorough verifications against expected standards performance requirements must be met before acceptance is granted.
Testing & certification:
- Use OTDRs (Optical Time Domain Reflectometers) among other testers to check how well an installed cable performs.
- Record findings as part of certifying that industry rules were followed during implementation while also meeting project specifications.
Labeling & documentation:
- Ensure clear identification labels on every cable, connector or distribution panel for easy identification during future maintenance activities troubleshooting exercises may arise at any given time therefore this information will come in handy .
- Maintain detailed records which include laying out diagrams showing where exactly they were placed along with results obtained from various tests done at different points.
Maintaining OM5 Fiber Networks
Maintenance methods which are effective for fiber networks of the 5th generation ensure continuous performance and durability of the system. Here are some maintenance activities and their technical parameters.
Regular inspection:
- Periodicity: Carry out visual inspections biannually to detect physical damage, wrong routing or environmental concerns.
- Technical Parameter: Look out for any sign showing that attenuation has gone beyond 0.3dB/km which would imply degradation.
Cleaning as well as Optical Hygiene:
- Procedure: Use appropriate cleaning tools for fiber optic cables such as lint-free wipes and isopropyl alcohol on connectors.
- Technical Parameter: An insertion loss of a cleaned connector should be less than 0.75 dB, while a return loss should be greater than 20 dB.
Environmental Monitoring:
- Monitoring: Follow temperature and humidity between 0°C to 70°C (32°F to 158°F) range and non-condensing humidity of between 5% to 95%.
- Technical Parameter: Polymer cable jacketing should not be allowed to degrade hence it is required that deviations from these limits should not be exceeded.
Connector & Splice Point Verification:
- Check Points: Periodically verify all connectors and splices using an OTDR device.
- Technical Parameter: Confirm that splice loss remains below 0.1 dB and connector losses below 0.3 dB.
Network Performance Testing:
- Testing Tools: Periodic tests may be performed using OTDRs, power meters, and light sources.
- Technical Parameter: Total network loss must never exceed design budget, which normally stands around 3.5 dB for OM5 over specified distances.
Documentation Updates:
- Record Keeping: Keep records for all inspections, cleanings, and tests carried out.
- Technical Parameter: Detailed graphs/logs showing before-after conditions, OTDR traces, certification test results proving compliance with TIA/EIA standards etc., need also to be included in this documentation update section.
If these activities are implemented while observing indicated technical parameters; then fiber optic networks based on OM5 will be reliable, perform well and last longer thereby reducing downtimes as well as extending life-span of network infrastructure.
Common Issues and Solutions with OM5 Fiber
Trouble: High Attenuation Loss
- Explanation: Overabundant fading can distort signals beyond comprehension over long distances.
- Answer: Perform regular calibration of equipment and check connectors’ integrity using an optical time domain reflectometer. To reduce insertion and return loss, all installations must be done according to the manufacturer’s instructions.
Problem: External Interference
- Description: Fiber optic performance may be affected by electromagnetic interference or physical obstacles.
- Solution: Shield fiber cables in conduits or trays away from sources of electromagnetism. Inspect the entire cabling pathway frequently for signs of physical damage or potential points of interference.
Problem: Fiber Bending
- Details: When the fiber is bent sharply or kinked, signal loss increases while breakage becomes more likely.
- Solution: Comply with minimum bend radius specified by manufacturer. Make sure to use cable management systems like bend radius control devices and ensure that there are no obstructions forcing fiber into tight bends along the pathway.
The intention behind these solutions is to detect and mitigate common issues so as to operate OM5 fiber network at its optimum level continuously.
Reference sources
- Fiber Optic Center (FOC)
- Article: “OM5 Multimode Fiber”
- Summary: The FOC article outlines the characteristics and advantages of OM5 multimode fiber, focusing on its plus points compared to other types of fibers.
- Corning Optical Communications
- Resource: “Understanding OM5 Multimode Fiber”
- Summary: Corning’s explanation of OM5 multimode fiber includes its performance anduses compared to traditional multimode fibers.
- The Fiber Optic Association (FOA)
- Guide: “OM4 vs. OM5 Fiber”
- Summary: This guide from FOA examines the differences between OM4 and OM5 fibers, providing a side-by-side analysis to help readers understand the distinctions and advantages of using OM5 wideband multimode fiber optic cables.
Frequently Asked Questions (FAQs)
Q: What is an OM5 wideband multimode fiber optic cable?
A: An OM5 wideband multimode fiber optic cable is a more advanced kind of multimode fiber that can support shortwave wavelength division multiplexing (SWDM) technology. This allows data to be sent over many different wavelengths in the 850-953 nm range, which increases bandwidth and distance compared to previous generations.
Q: How does OM5 fiber optic cable differ from OM3 fiber?
A: The main difference between OM5 fiber optic cable and OM3 fiber is the number of wavelengths through which they can send data. Although designed for 850 nm, OM3 only supports one wavelength while its successor supports many more (850-953 nm)– this provides higher bandwidths and longer distances.
Q: What are some advantages of using an OM5 cable instead of an OM4 one?
A: Some benefits of using an OM5 cable instead of an OM4 one include being able to use SWDM technology which enables faster data rates over longer links; also having higher bandwidths than what was possible with previous versions so it’s great for speedier networks like 400 Gigabit Ethernet or greater speeds.
Q: Can I use my old infrastructure with new cables made out of this stuff?
A: Yes, backward compatibility is possible when dealing with optical fibers such as these; therefore, you can use your existing infrastructure alongside them without much trouble – all you need do would be swapping some things here or there if need be but generally speaking everything should work just fine once integrated together because they offer high performance upgrades paths.
Q: How far can light travel down one length of this cool-looking wire thingy called “OM5”?
A: The maximum distance that light can travel through a single length (“fiber”) made from the material known as “OM5” will vary depending on factors like what type it is and how fast data needs to be sent over it. But under ideal conditions (including proper transceivers etc.), 400 meters for 40 GbE or even 150m for 100 Gigabit Ethernet are possible!
Q: What is the normal color of OM5 cables?
A: Normally, OM5 cables are lime green in color. This is to differentiate them from other multimode fibers like OM1, OM2, OM3, and OM4, which are commonly orange and aqua colored.
Q: What connectors work with fiber optic cables for OM5?
A: Commonly used for OM5 fiber optic cables are LC to LC duplex connectors. These connectors are widely adopted in network environments and provide a reliable connection for high-speed data transmission.
Q: What does optical transmission improvement by OM5 fiber mean?
A: Optical transmission is improved by OM5 fiber through support for multiple wavelengths between 850nm and 953 nm. This allows utilization of short wave wavelength division multiplexing that can increase bandwidth and enable higher data rates over longer distances.
Q: Which applications benefit the most from using fiber optic cables of OM5 standard?
A: Fiber optic cables based on the OM5 standard offer the greatest advantage in applications where there is heavy demand for bandwidth or extremely fast data transfer speeds. Such applications include large-scale enterprise networks, data centers as well as high-performance computing among others. They are especially useful in environments transitioning towards 40Gbps, 100Gbps or even 400Gbps Ethernet standards.
Q: Can optical transceivers be used with om5 cable?
A: Yes, typically, optical transceivers designed for use with multimode fibers should work fine when connected to an om5 cable. There are those optimized for 850nm wavelengths as well as those made specifically for SWDM, which makes it easier to upgrade existing network infrastructure so that it supports higher data rates。
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