Terrestrial and Submarine/Subsea Fiber Optic: A Comprehensive Guide

Introduction

Fiber optic technology has revolutionized the way we communicate, enabling the high-speed transfer of data across vast distances with minimal loss. Whether it’s terrestrial fiber optic cables crisscrossing cities or submarine cables stretching across oceans, this technology is the backbone of the modern internet and global telecommunications. In this article, we’ll dive deep into the intricacies of terrestrial and submarine fiber optics, exploring their structure, applications, and the challenges they face.

Types of Fiber Optic Cables: Subsea vs. Terrestrial

Fiber optic cables can be broadly classified into two categories: subsea (or submarine) cables and terrestrial cables. Subsea cables are laid on the ocean floor and connect countries, continents, while terrestrial cables are installed on land, connecting cities, towns, and other infrastructure. Both types of cables are vital for global connectivity, but they differ significantly in terms of deployment, maintenance, and applications.

Submarine cable map by Telegeography:

https://www.submarinecablemap.com

Terrestrial+Submarine cable map by ITU:

https://bbmaps.itu.int/bbmaps

1) What is Terrestrial Fiber Optic?

Terrestrial fiber optic refers to the network of fiber optic cables laid across land, connecting cities, towns, and even rural areas to the internet. These cables are designed to transmit data at incredibly high speeds using light signals, making them ideal for supporting the ever-growing demand for bandwidth in today’s digital age.

Structure of Terrestrial Fiber Optic Cables

Terrestrial fiber optic cables are composed of several key components:

1. Core: The core is the innermost part of the cable where the light signals travel. It’s made of pure glass or plastic, allowing light to pass through with minimal loss.
2. Cladding: Surrounding the core is the cladding, which is made of a material with a lower refractive index than the core. This helps to reflect light back into the core, ensuring it travels along the desired path.
3. Buffer Coating: This layer protects the core and cladding from moisture and other environmental factors. It’s typically made of a polymer material.
4. Strengthening Members: To prevent the cable from being damaged during installation or use, strengthening members like steel wires or Kevlar are added.
5. Outer Jacket: The outer jacket is the cable’s protective outer layer, shielding it from physical damage and environmental conditions.

How Terrestrial Fiber Optic Networks Work

Terrestrial fiber optic networks function by transmitting data through light signals. These signals are sent from a source, like a data center, and travel through the fiber optic cables to reach their destination. The network topology can vary, with common types including:

• Point-to-Point: Direct connections between two locations.
• Ring: A circular network where each point is connected to two others, providing redundancy.
• Mesh: A complex network where each node is connected to multiple others, ensuring reliability and high availability.

Applications of Terrestrial Fiber Optic

Terrestrial fiber optic cables are used to connect anything and everything on the land, mostly within the same country

• Telecom: These cables form the backbone of telephone & internet networks, enabling clear voice & high speed data communication across long distances.
• Internet Connectivity: Fiber optic cables are essential for providing high-speed internet to homes, businesses, and institutions.
• Government and Military Use: Fiber optics are used for secure communication and data transfer in government and military networks, thanks to their high speed and reliability.

---

2) What is Submarine/Subsea Fiber Optic?

Submarine or Subsea fiber optic cables are laid on the ocean floor, connecting countries, continents and enabling international communication. These cables are vital for the global internet infrastructure, as they carry the vast majority of intercontinental data traffic.

Structure of Submarine Fiber Optic Cables

Submarine fiber optic cables are similar in structure to terrestrial cables but are built to withstand the harsh conditions of the ocean:

1. Core: Like terrestrial cables, the core is where the light signals travel, made of high-purity glass.
2. Cladding: The cladding reflects light back into the core, just like in terrestrial cables.
3. Strengthening: Due to the challenging underwater environment, submarine cables have extra layers of steel wires for added strength.
4. Waterproofing: A layer of waterproof material protects the cable from seawater.
5. Armor: Submarine cables have an additional armor layer made of steel or other metals to protect against physical damage from marine life, anchors, or other hazards.
6. Outer Sheath: The outer sheath is the final protective layer, ensuring the cable’s integrity in the ocean’s depths.

How Submarine Fiber Optic Networks Work

Submarine fiber optic networks operate similarly to terrestrial networks but on a much larger scale. The cables transmit data using light signals, which travel through the core. Repeaters are placed at regular intervals along the cable to boost the signal, ensuring it can travel thousands of kilometers without significant loss.

Applications of Submarine/Subsea Fiber Optic

Submarine fiber optic cables are crucial for various applications:

• Global Internet Infrastructure: These cables carry over 99% of intercontinental data traffic, making them essential for the internet as we know it.
• International Communication: Submarine cables enable reliable communication between countries, supporting everything from phone calls to video conferences.
• Industry and Commerce: Businesses rely on submarine cables for secure and fast data transfer, enabling global trade and commerce.

Key Differences Between Terrestrial and Submarine Fiber Optic Cables

While both terrestrial and submarine fiber optic cables share the same basic principles, there are some key differences:

• Key differentiator is that Terrestrial is the land/earth fiber cable whereas Subsea fiber cable is the sea/ocean cable
• Structural Differences: Submarine cables are built with extra layers of protection to withstand the ocean environment, while terrestrial cables are designed for land-based conditions.
• Installation and Maintenance: Installing submarine cables is a complex and expensive process, often requiring specialized ships and equipment. Terrestrial cables are easier and cheaper to install but still require careful planning.
• Cost Considerations: Due to the challenges of laying and maintaining them, submarine cables are significantly more expensive than terrestrial cables.

Some more comparisons: Subsea vs. Terrestrial

Cost Considerations

Subsea cables are much more expensive to deploy and maintain due to the complexity of underwater installation and the need for specialized equipment. Terrestrial cables, on the other hand, are less costly to install and repair, but they require more frequent maintenance due to their exposure to environmental factors and human activity.

Speed and Latency

Both subsea and terrestrial cables offer high-speed data transmission, but subsea cables typically have lower latency to compensate for long-distance communication. This makes them ideal for international data traffic. Terrestrial cables, while fast, may experience higher latency when transmitting data over long distances, especially if repeaters are required.

Reliability and Durability

Subsea cables are generally more reliable and durable than terrestrial cables, as they are less exposed to environmental hazards. Another reason is that because subsea cables are far away from the reach of humans to interfere or vandalize. However, when subsea cables do experience faults, repairs are more challenging and costly. Terrestrial cables, while easier to repair, but are more prone to damage from natural disasters, construction, and vandalism.

Environmental Impact

The environmental impact of subsea and terrestrial cables varies significantly. Subsea cables can disturb marine ecosystems during installation, but once laid, they have minimal impact. Terrestrial cables, depending on how they are installed, can have a greater environmental footprint, particularly when forests or other natural areas are disrupted to lay the cables.

Security Concerns

Both subsea and terrestrial cables face security challenges. Subsea cables are vulnerable to underwater attacks and tapping, while terrestrial cables can be easily accessed and compromised by physical attacks. Ensuring the security of these cables is critical to protecting the data they transmit.

Challenges faced by Terrestrial and Submarine Fiber Optic Networks

Both terrestrial and submarine fiber optic networks face various challenges:

• Environmental Challenges: Submarine cables must withstand harsh underwater conditions, while terrestrial cables can be affected by natural disasters like earthquakes or floods.
• Technical Challenges: As data demands increase, the need for higher capacity and faster speeds pushes the limits of current fiber optic technology.
• Security Challenges: Fiber optic networks are vulnerable to physical attacks, cyber threats, and espionage, requiring robust security measures.

Advances in Fiber Optic Technology

Fiber optic technology continues to evolve, with several trends shaping its future:

• Innovations in Fiber Optic Materials: Researchers are developing new materials to increase the capacity and durability of fiber optic cables.
• Expansion of Global Fiber Optic Networks: As demand for data grows, more fiber optic networks are being laid, both on land and under the sea.
• The Role of Fiber Optics in 5G and Beyond: Fiber optics will play a crucial role in supporting 5G networks and future technologies, enabling faster and more reliable communication.

Conclusion

Fiber optic technology is the backbone of modern communication, connecting people and businesses across the globe. Whether it’s terrestrial cables delivering high-speed internet to homes or submarine cables enabling international communication, fiber optics are essential to our digital world. As technology continues to advance, fiber optics will remain at the forefront, driving innovation and connecting the world.

FAQs

1. What is the lifespan of fiber optic cables whether terrestrial or subsea?
   Fiber optic cables typically have a lifespan of 25 years or more, depending on environmental conditions and usage.
2. How are submarine fiber optic cables installed?
   Submarine cables are installed using specialized ships that carefully lay the cables on the ocean floor, often clamping them on the seabed for protection.
3. Can fiber optic cables be repaired if damaged?
   Yes, both terrestrial and submarine fiber optic cables can be repaired, although the process for submarine cables is more complex and costly.
4. What are the environmental impacts of fiber optic cable installation?
   While fiber optic cable installation can have some environmental impact, especially underwater, efforts are made to minimize damage to ecosystems during the installation process.