Cable Internet

Structured Cabling

Structured cabling is a complete cabling and hardware system that provides a comprehensive telecommunication infrastructure to help and organization run its networking tasks smoothly. It is the standardized equipment and architectural environment as presented by the commercial building telecommunication cabling standards. The standards are used as a guide by manufacturers to ensure interoperability. Structured cabling is used in a range of areas, including data centers, manufacturing facilities, offices, and others. The system serves a wide range of purposes, such as data transmission and telephone service.

A properly designed and well-maintain structured cabling infrastructure can provide the system predictable performance in addition to the flexibility to accommodate changes, provide redundancy, the capacity to maximize system availability, and the ability to improve the usability of the cabling system in the future.

How Structured Cabling System Is Established


A structured cabling system is an organized approach to cabling infrastructure using a series of patch panels and trunks. The overall design of the infrastructure is unique in each cabling system. The variations may come from the architectural design of the building or room housing cabling system, the function of the system, the cables and connection products used, the type of equipment the system will support, the configuration of the system, and the specific requirements of users. While there may be slight variations in the design of the system, each infrastructure is developed as per the standards of cabling design, installation, and maintenance to ensure acceptable system performance.

What are the Main Components of a Structured Cabling System?


A structured Network Cabling System typically comprises the following components:

  • Cable pathways, including raceways, conduits, shafts, and floor penetrations
  • The actual cables consisting of twisted copper, optical fiber, coaxial copper or a combination of these
  • Connecting hardware, such as connecting blocks, cross-connections, patch panels, interconnections, or a combination of these

What are the Benefits of Structured Cabling?

Allows Quick Adaptability

With the Main Distribution Area (MDA) data center, Moving, Adding, and Changing (MAC) may become quicker and simpler. MAC is required to keep the system up-to-date and aligned with the changing needs and requirements of users and the organization.

Reduces Downtime

A structured cabling system can drastically reduce human errors which may significantly minimize downtime and resulting losses.

Time Savings

By creating an organized cabling system, the infrastructure may allow uniform documentation, making cable and port tracing easier and less time-consuming. If you are looking to get a structured cabling system for your small business, Contact Us to get complete cabling installation and maintenance solutions. In addition to cabling service, we offered Managed IT Services, Surveillance Systems, Fiber Optic Installation, among others. Call us at 786-622-2221 to get expert guidance and a solution that fits your needs.

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Why schools should consider using fiber optics?

Thanks to the countless technological advances in recent years, humans all over our planet have embraced the digital changes that help them to stay in touch. Over half of the world’s population has internet access, smart devices are everywhere, and 5G networks are ready to support new users. All of this technology demands connections that can handle intense workloads maximum efficiency, and that’s where fiber optic internet comes in. These networks have allowed businesses to send and receive data faster than ever before. They have also given businesses the chance to incorporate lots of new forms of technology into their office spaces.

One of the benefits of a fiber-optic connection is that it’s a turn-key wireless solution when you go with the right company. In fact, most fiber optic systems can be installed within a matter of hours and are ready to be used as soon as the installation is finished. Your connection can also be specifically tailored to meet your needs, and you are guaranteed to establish a system that works for you. It now appears as though many schools are following the business world’s lead and taking advantage of using fiber optic cables and fiber-optic network in their buildings. If your school is not equipped with fiber optic cable you should take a time to learn about the many benefits of going with a fiber-optic network as opposed to one that still relies on old copper cables. It could help students in your school to learn better and keep them safer in the process.

Speed

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Fiber optic cabling is the most efficient form of network cables. Improving technologies, such as 5G and 4K video, force individuals and organizations to change with the improvements.

Security

data, security, keyboard

Traditional copper wires can be easily cut or intercepted because they emit signals naturally. Fiber optics do not radiate any signals, and they are most commonly installed underground and only link to the building through a conduit.

Learning Opportunities

child, kid, play

Schools are often considered early adopters in technology, and one of the reasons for this is because they must teach others about innovative technology.

Fiber optic Internet makes it easy for students to access information quickly while in school. Students at most schools use everything from smartphones, tablets, laptops, and desktop computers to access the information they need. Fiber optic cables use light to send and receive data, which makes them much faster than copper cables in this matter. Right now, most data centers are only producing 100 to 200 GBPS od data at any given time. This bandwidth is extremely fast on its own, but not so when it’s divided between the many users connected to wireless networks.

Allows teachers to use more videos as part of the teaching process. Students aren’t the only ones who will benefit from the installation of fiber optic cables in your school. Teachers will also be able to use them while teaching students. They’ll be able to include more videos that they find online in their lesson plans. Since fiber optic cables make it possible to send and receive data so quickly, teachers won’t have any problems pulling up a video at a moment’s notice so that they can share it with their students.

Helps police keep students and teachers safer during the school day. School safety has obviously become a huge issue in recent years with schools all over the country taking drastic measures to provide students and teachers with protection during the school day. Fiber optic cables might be able to help out with this initiative. These cables make it possible for schools to hook up security cameras throughout their buildings. They also make it possible for police to hook up to the security cameras to see what’s going on inside a school at any time.

Finally, empowers students and opens up a whole new world to them. At the end of the day, the main mission of your school should be to push students to become the best versions of themselves that they can be.

fiber optic splicing

Fiber Optic Splicing

Nowadays fiber optic splicing is widely deployed in telecommunications, LAN, and networking projects. Typically, fiber optic splices can be undertaken in two ways: fusion splices and mechanical splices. Fusion splicing is a permanent connection of two or more optical fibers by welding them together using an electronic arc. It is the most widely used method of splicing as it provides for the lowest loss, less reflectance, strongest, and most reliable joint between two fibers.

There are many occasions when fiber optic splices are needed when there is an available fiber optic cable is not long enough for the required distance. In this case is possible to make a permanent connection. Splicing is also designed to restore fiber optic cables when they are accidentally broken.

There are two available types of fiber optic cable splicing. Both methods provide much lower insertion loss compared to fiber connectors.

Fusion Splicing

Fiber optic cable fusion splicing provides the lowest-loss connection and has a longer life than mechanical splicing. The fusion method fuses the fiber cores together with less attenuation. Special equipment called fusion splicer is used to perform the fiber fusion splicing. The fusion splicer performs optical fiber fusion splicing in two steps:

  • Precisely align the two fibers.
  • Generate a small electric arc to melt the fibers and weld them together.

High precision fusion splicers are usually bulky and expensive. With proper training, a fiber splicing technician can routinely achieve less than 0.1 dB insertion loss splicing for both single-mode and multimode fiber cables. When adopting this method, fusion splicing machines are often used. Generally, there are four basic steps in the fusion splicing process:

1. Strip the fiber

The splicing process begins with the preparation for both fiber ends to be fused, and you need to strip all protective coating, jackets, tubes, strength members, and so on, just leaving the bare fiber showing.

2. Cleave the fiber

Cleave the fiber is crucial to a successful fusion splice. The cleaver just nicks the fiber and then pulls it to cause a clean break rather than cut the fiber.

3. Fuse the fiber

Aligning and melting are the main steps when fusing the fiber. First, the ends must be aligned within the fiber optic splicer, and once alignment is done an electrical arc must be used to melt the fibers and permanently weld the two fiber ends together.

4. Protect the fiber

A typical fusion splice has a tensile strength between 0.5 and 1.5 lbs and it is not easy to break during normal handling. However, it still requires protection from excessive bending and pulling forces. With the help of heat shrink tubing, silicone gel, and mechanical crimp protector, the splice can be protected from outside elements and breakage.

Mechanical Splicing

Mechanical splicing is an optical junction where the fibers are precisely aligned and held in place by a self-contained assembly, not a permanent bond. The mechanical splices are normally used when splices need to made quickly and easily. Like the fusion splice, there are four basic steps for the mechanical splice.

1. Strip the fiber

In this step, the protective coating, jacking, tubes, strength members must be removed to show the bare cores. It is noted that the cables should be cleaned.

2. Cleave the fiber

When cleaving the fiber, you need to obtain a very clean cut which is exactly at right angles to the axis of the fiber.

3. Mechanically join the fiber

You have to join the fibers mechanically with no heat. Simply connect the ends of fiber together inside the mechanical splice unit and the device will help couple the light between two fibers.

4. Protect the fiber

Once fibers are spliced, protection will be needed during light transmission. Typically, the completed mechanical splice provides its own protection for the splice.

Fusion and mechanical splicing both have their specific advantages and disadvantages. When it comes to choosing fusion or mechanical splicing that is up to the customer’s needs. The fusion splice offers a lower level of loss and a high degree of performance. It gives very low back reflections and is preferred for single-mode high-speed digital or CATV networks but it requires the use of expensive equipment. Mechanical splicing is deployed for applications where splices need to be made quickly. Choosing the appropriate method, whether the fusion splicing or mechanical splicing, can not only save money but also enhance work efficiency. Besides, when you are doing fiber optic splicing, it is necessary to follow the steps strictly and carefully.

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Why Fiber Optic Internet is Superior?

Fiber optic internet is known for providing the best last-mile broadband service in the 21st century. Fiber Internet is the best option for consumers today, and they are the only option that will allow expansive, efficient upgrades to America’s networks for a generation. Not to claim that no broadband technology will ever surpass fiber-optics and there are different limitations of the existing technologies. If fiber internet is installed to the home connections the transmitters at each end will get an upgrade without touching the underlying cables, low-latency, high-reliability connection.

While other means of delivering high-speed broadband are not too far behind fiber right now, the properties of each technology will allow fiber deployments to scale up quickly and easily while copper and wireless broadband networks will struggle to keep up.

This article provides a brief technical background and explains key concepts for understanding internet services such as bandwidth, latency, channel capacity, and noise. Understanding these concepts is essential in order to assess and compare broadband networks. This article focuses on the “last mile” of broadband connections because a vast majority of the internet infrastructure before the last mile has already transitioned to fiber. Lawmakers and regulators in positions of determining infrastructure policy must understand the realities of networking technologies in order to properly assess the capability of networks to absorb greater user demand.

This post does not explore policy mechanisms to address the fiber deficit currently facing the United States market. EFF intends to publish such material at a future date. The purpose of this paper is to educate policymakers as to the technological differences between different broadband networks and as to the future proof nature of fiber networks.

With the advent of cloud computing, virtual reality, gaming, telehealth, remote services, and high capacity services we have not yet imagined yet, policymakers must grapple with updating the Internet’s infrastructure for the 21st century so that the American people are not left behind.