How Fast Is Fiber Optic Internet?

Fiber optic internet is currently the fastest, most-reliable internet service available. Fiber increases download and upload speeds and offers users faster access to various media types and larger file sizes. When it comes to business communications, fiber optic internet can increase productivity while reducing latency. Typically, fiber service offers unlimited data usage, faster cloud access, high speed symmetric connectivity, and unparalleled scalability. For those reasons, fiber optic internet is often a better solution, when it is available.

Fiber internet is considered superior to traditional broadband (typically delivered via copper cables or coaxial cables) for several reasons:

1. Speed and Bandwidth: Fiber optic cables transmit data using light signals, allowing for much higher speeds and larger bandwidth capacities compared to traditional copper cables. Fiber internet can provide symmetrical upload and download speeds, meaning you can upload data as quickly as you can download it. This makes fiber internet ideal for activities such as video streaming, online gaming, and large file transfers.
2. Lower Latency: Fiber optic cables have lower latency (delay) compared to copper cables. This means that data can travel faster over fiber, resulting in a more responsive and lag-free internet experience. This is particularly important for real-time applications like online gaming, video conferencing, and cloud-based services.
3. Reliability: Fiber optic cables are less susceptible to interference and signal degradation over long distances. They are not affected by electromagnetic interference from nearby power lines or radio frequencies, which can disrupt traditional broadband signals. Fiber internet is also more resistant to environmental factors like inclement weather, providing a more reliable connection overall.
4. Future-Proof Infrastructure: Fiber optic networks have the potential to handle increasing data demands as technology advances. The ever-growing need for higher speeds and bandwidth makes fiber a future-proof choice for handling emerging technologies like virtual reality, augmented reality, 4K/8K video streaming, and the Internet of Things (IoT).
5. Scalability: Fiber internet infrastructure is highly scalable, meaning it can easily accommodate higher speeds and increased data demands. With fiber, internet service providers can upgrade their networks without the need for extensive physical infrastructure changes, allowing for faster and more efficient upgrades.

Fiber internet may not be widely available in all areas, especially in rural or remote regions. Additionally, the installation costs associated with deploying fiber optic cables can be higher than traditional broadband. However, as the demand for high-speed internet increases and fiber infrastructure expands, its advantages are becoming increasingly recognized and adopted.

As the name would suggest, fiber optic internet is internet that is provided through special fibers or strands that are bundled into optic cables. Unlike copper lines, which are typically used for cable or DSL services, fiber optic lines are composed of plastic or glass strands that are used to transmit light. Light moves and reflects along the bends and curves in the optical cable. The light transmits information through encoded light signals, or binary. This is then decoded to present information (images, text, sounds, etc.) to the end user. This particular transmission method can transport more data than copper, which was originally designed to transmit only voice (i.e., early telephone services). When it comes to today’s digital requirements, fiber optic internet is significantly quicker and more reliable than its predecessors. A fiber optic internet connection allows users to access, upload and transmit information at speeds that surpass traditional internet mediums, such as copper based DSL or cable connections.

Using fiber optic cables, which bundle glass strands to transmit data, a fiber optic internet connection offers high speed upload and download times. Fiber internet speed does not degrade over longer distances, like copper based internet connections. Additionally, a fiber connection allows for greater data capacity while limiting loss and interference. As it becomes more available and to satisfy user demands, fiber optic internet is becoming the main source of competition for broadband, DSL, cable, and satellite internet services

When viewed over time, fiber optic internet is considered to be a relatively new technology.

• The foundational innovations behind fiber optic internet actually date as far back as 2500 B.C. At that time, the Romans found it was possible to draw glass into fibers.
• Between the 1700s and the 1800s, the roots of fiber optic communication experienced significant growth, with the invention of the optical telegraph in 1790 (Claude Chappe) and the Photophone in 1880 (Alexander Graham Bell).
• Also during the mid-1800s, two valuable observations made by Daniel Colladon (1841) and John Tyndall (1854), both of which discovered the ability to conduct light through streams of water, further set the stage for fiber optic theory.
• By 1926, RCA Rocky point Laboratory in Long Island, NY, worked with Clarence Hansel to outline the principles (and later patents in the U.S.A and Britain) of, fiber-optic image bundling. Following that, the world experienced a surge of advancements in the design and use of communication fibers. Each advancement paved the way for the fiber optic service we know today.
• In the early 1970s, Corning Glass researchers invented Optical Waveguide Fibers, commonly known as fiber optic wire. This innovation allowed for the transfer of information via light wave patterns. This information could then be decoded at the final destination. The information transfer rate was 65,000 times faster than copper wire, showing researchers the true potential of fiber optics.

• 1975 – the U.S. government had used fiber optic cables to link two computers, reducing interference.
• 1977 – Chicago became home to the first fiber optic telephone communication systems, which were buried underneath the city. At that time, the optical fiber carried what is equivalent to 672 voice channels.
• 1988 – the first transatlantic fiber-optic cable, TAT-8, successfully transmitted data across the ocean floor from New Jersey to England and France. TAT-8 was less than 1 inch thick in diameter. It was capable of handling 40,000 simultaneous voice calls. At the close of the century, 80% of long-distance telephone traffic was traversing the globe via fiber optic cables.

Fiber optic internet is currently available in certain locations across the United States and in other countries around the world. However, only 25% of the USA’s population have access to fiber optic internet based service. Many United States based ISPs are working to increase availability every day. Typically, companies are focusing fiber optic installation efforts in highly populated urban locations. Fiber access relies on the installation of fiber optic cables in your area. Currently, in order to maximize the impact of fiber optic installations, fiber optic is typically limited to dense urban areas.

Depending on where you live in the USA, fiber optic internet may be available to you right now. With over two hundred fiber optic internet providers, fiber access is expanding. There are a variety of fiber providers across the United States of America. These include the large corporations such as Verizon, AT&T, Comcast and the more recent Google Fiber. Many Internet Service Providers (ISPs) including Fastmetrics, provide fiber optic internet availability maps. This fiber optic availability map can help you determine if fiber optic internet is available in the Bay Area or Los Angeles.

Fiber optic internet services are available worldwide. Residential and businesses are using high speed fiber internet across Asia (Japan, South Korea, etc.), Europe (Sweden, Norway, UK, Denmark, etc.), and the Middle East (Saudi Arabia, UAE, etc.), South America (Brazil, Argentina, Peru, etc.), Oceania (Australia and New Zealand), and North America (Canada, Mexico, etc.).

Though only a small percentage of California has access to fiber optic internet service, Fastmetrics offers fiber optic internet service to businesses in commercial buildings throughout San Francisco, San Jose, Mountain View, Redwood City, Fremont, Oakland, Palo Alto, Santa Clara, San Mateo, Menlo Park, Napa and to most commercial buildings in the wider San Francisco Bay Area and Los Angeles areas.

This fiber service is complemented with a growing network of fiber optic ready buildings, that compose our fiberIVY network. If you live outside of those areas, please call your local internet service provider to find out if fiber optic internet is available where you live.

Currently, there are over 200 internet service providers that offer fiber optic internet. Fastmetrics is proud to join major fiber providers like Verizon, AT&T, Comcast and Google Fiber.

One of the main reasons for the growing popularity of fiber optic internet services is the speed, or the much faster data transmission times.

Here is a quick overview of fiber optic internet download speeds;

• Fiber optics: Up to 10 Gbps (a data transfer rate up to 10 billion bits per second)
• Cable connections: 25 – 300 Mbps (a data transfer rate up to 300 million bits per second).
• Digital Subscriber Lines (DSL): 0.5 – 75 Mbps.
• Satellite: 5 – 25 Mbps.

Fiber optic internet is consistently faster than cable. Fiber optic internet speeds clearly surpass older internet connection technologies. Fiber speed can still vary, based on a variety of factors. Factors include location and the type of fiber connection available (FTTH, FTTN, etc).

Fiber optic internet offers a faster and more reliable way to connect and use the internet. As such, it is often more expensive than other connections types like cable and DSL. However, businesses may find that the additional costs of a fiber connection yield various benefits, including;

• A more productive workplace with higher output.
• Increased reliability and less costly downtime.
• Faster and more reliable access to cloud based services.
• Lower latency and faster data transfers.
• Higher quality, uninterrupted streaming and conferencing.

To find out more about fiber optic internet pricing and affordability, please call Fastmetrics toll-free; 1-800-724-100 or contact us via online chat.

If existing fiber optic internet cables are available in your city, town or neighborhood, fiber installation into a home or business can vary, based on unique locational needs. For Fiber To The Premise (FTTP) or Fiber To The Home (FTTH), installation may include the laying of fiber cable, splicing and provisioning of network equipment. Once a connection is made, an optical network terminal (ONT) will need to be installed. Once installed, a technician will connect the ONT to your router, switch or directly to a single computer. For a Fiber To The Node (FTTN) installation, fiber cable will terminate at a nearby off premise hub. The final distance from the fiber node or ‘hub’ to a home or business will be run with cable or DSL technology.

Be sure to ask your local internet service provider what type of fiber optic connection is available to you. Also ask about any costs and equipment requirements, associated with installation for your home or business.

Assuming FTTP or FTTH is available, you will not need a modem. You will likely need a similar device, such as a switch. In some cases, a fiber optic internet connection will require the use of an optical network terminal (ONT). This hardware translates the light signal into digital signals that can be used to terminate the line and provide a signal for telephone, television, and internet purposes.

For many gamers, internet speed and bandwidth is essential for productive gaming sessions. Because fiber optic internet provides lower latency and is capable of downloading games and movies at a faster rate when compared to other internet connections, many support fiber as the ideal solution for both gaming and HD video streaming.