In today’s modern era, we humans are being enslaved by every gadget prioritized by the Internet. In that context, now fiber optical communications have tremendously revolutionized the telecommunications industry. Fiber optics have become the preferred choice for Ethernet backbone infrastructure, high-speed internet services, and general data networking due to their consistent reliability over many years.
Although fiber optics communication costs are relatively high, almost all medium and large communication systems nowadays use this modern technology. The exceptional features of this technology clearly outweigh any cost and expertise in the first place. The ability to achieve a massive data transfer rate, high security, and tolerance to external influences and manipulations are the top priority.
Many networking networks use fiber optics as a backbone; why because it has infiltrated many traditionally wired-only industries. Today medical device manufacturers are acknowledging fiber optics’ superior capabilities in transmitting a wide array of communications signals, and it is now being incorporated into sensors, imaging, and microsurgical systems.
Since data rates for robotics and medical devices are rising exponentially, fiber optics has now become a better networking option for others too. The fiber optics sends data down the fiber cable in the form of light pulses rather than electrical pulses through copper wires. Fiber optics is much faster and has a much larger capacity than standard copper wire. Thinner, more flexible, generally stronger cables and require less maintenance than wired cables.
Gigabit Ethernet is perhaps the most prominent application of fiber optics. The migration of the Internet from obsolete copper cables to fiber-optic cables results in extremely high bandwidth, reliability, and speed. HD video streaming, interruption-free video chat, lag-free multiplayer online gaming, high-speed downloads, and much more are all possible thanks to this. Single-mode cables have a data rate of up to 10 Gbps. In addition, increased bandwidth and multiple modes enable a fiber-optic channel or cords for the Internet, landline, HD TV, and more.
In small to medium-sized business networks, fiber optics have become increasingly prevalent. In support of IP communications, it is necessary to increase bandwidth in demand for IP-based devices like VoIP phones, IP cameras, and video conferencing units. Fiber optics can easily accommodate bandwidth-intensive devices due to its high throughput capabilities.
This method of communication is used not only for large communication networks but also by many big companies and organizations in their respective factories and large offices. That is due to the fact that information that communicates through these cables not only faster but also remarkably reliable for heavy traffic usages.
Having this feature allows highly confidential and sensitive data to be transmitted over channels more quickly. In addition, large offices employ hundreds of staff, and data is sent and received during the entire time of operation. Fiber optics focuses on providing high bandwidth and notably fast speeds to ensure continuous and effective communication.
Fiber optics, however, are costly. The installation of traditional copper cables is still more expensive, and many companies do not still find that their networks require fiber installations. In this respect, the following four advantages certainly outweigh the cost of infrastructure.
Highly Secure but Fragile:
One of the safest means of communication is fiber optic cables and it is something that is impossible to infiltrate. Interception of transmission signaling is highly difficult due to the cabling’s structure, making them highly secure in today’s data-heavy environment. Whatever attempts to penetrate the glass cable will result in light leakage, which will lead to significant communication deterioration.
Compatible with Electromagnetic Fields:
Many of the external forces that degrade copper cabling do not affect fiber optic cabling. The recommendation of Fiber optic cabling is in those areas where large motors, controllers, and air conditioners are continually starting and stopping. Increased latency of data loss from packets and radio-frequency (EM/RFI) interference from devices across the network will result in data loss.
Higher in Speed with Less Latency:
Traditional copper cabling is several times slower than fiber-optic cabling. Glass fibers with a small diameter can support bandwidth rates of up to 10 gigabits per strand. Although copper cabling can support these speeds, a considerable amount of CAT 6 cables would be required to achieve the rates of a single fiber strand.
Covering Longer Distances:
Fiber cables are an ideal way for point-to-point hardline communications for covering over long distances. Traditional copper cabling is limited to 328 feet, limiting long-haul transmission and necessarily implies the fortification of such additional equipment to extend the signal. Attenuation will begin to set in as copper cables exceed their entire length, resulting in a marginal decrease in gigabit transmission speeds.
Conclusion:
Consider taking a short training course at The Versics that guides you step-by-step through the fiber optic cable optimization if fiber optic is a new concept for you. For those who set up and maintain fiber optical cables and connectors in the field, training should include hands-on expertise.
If you want to shape the future of fiber-optics, contact and join us!