Optical Fiber Cable (OFC): Advantages and Disadvantages

This page explores the advantages and disadvantages of Optical Fiber Cable (OFC).

Introduction

Optical fibers have become commonplace for providing broadband internet connectivity. Optical fiber communication uses OFC as a transport medium to carry modulated light waves from a transmitting end to a receiving end.

The OFC is made of plastic or glass. LEDs or laser diodes convert electrical signals to light signals at the transmitter, while photodiodes convert light signals back to electrical signals at the receiver.

What is OFC?

OFC consists of multiple bundles, each containing several optical fibers. These bundles are covered with protective layers and a strength member. Each bundle contains hair-like silicon core fibers, covered with cladding to prevent light leakage. An outer jacket protects the entire cable. This is illustrated in the figure below:

The core, made of thin glass, transports light between the two ends. The cladding reflects the light, enabling efficient transmission through the core.

There are two main types of OFCs: single-mode and multimode.

• Single-mode OFC: Uses a single strand of glass fiber, with a diameter of 8.3 to 10 microns. It carries a single mode of light and supports higher bandwidth than multimode OFC. Offers higher transmission rates and can transmit data up to 50 times farther than multimode. Single-mode OFC is commonly used for inter-city telephone lines and video applications. Light waves with wavelengths of 1300 to 1320 nm can propagate through single-mode fiber.

• Multimode OFC: Made of glass fibers with a diameter of 50 to 100 microns. Multimode OFC provides higher bandwidth at greater speeds over medium distances. Light waves with wavelengths of 850 or 1300 nm can travel through the core of multimode OFC.

Benefits or Advantages of OFC

Here are the key benefits of using OFC:

• High Bandwidth: Data can be transmitted at Gbps speeds over the glass threads of OFC in the form of light pulses. This is much higher than copper wire. OFC supports a much wider bandwidth (> 10 GHz).
• Immunity to EMI: Light waves in OFC are not affected by electromagnetic interference (EMI), making it a more secure transmission method.
• Electrical Isolation: OFCs provide complete electrical isolation.
• Long-Distance Transmission: Data can travel for miles without significant signal degradation using OFC. Repeaters or amplifiers can be used to further extend the transmission distance.
• Environmental Resistance: OFCs are highly resistant to various environmental factors like temperature, corrosive liquids, and gases.
• Safety: OFCs pose no shock hazards because they are non-conductors.
• Low Attenuation: OFCs attenuate signals less than other wired transmission mediums.
• Small Size and Light Weight: OFCs are smaller and lighter than traditional copper cables.
• Ease of Installation: OFC installation is generally easier.
• Cost-Effective: OFCs are less expensive compared to other cable-based systems.
• Long Lifespan: Offers a longer lifespan, typically 30-50 years.
• Energy Efficient: Energy consumption per user is lower compared to copper wires.
• Durability: OFCs are highly durable.

Drawbacks or Disadvantages of OFC

While OFC offers many advantages, there are also some drawbacks to consider:

• High Initial Cost: The initial installation cost of OFCs is relatively high.
• Difficult Splicing: Splicing OFCs is more complex than splicing wires, especially at the starting and ending joints. Specialized techniques, skilled manpower, and expensive equipment are required.
• Fragility: OFCs have weaker physical and tensile strength compared to copper cables.
• Remote Power Requirement: It requires remote electric power.
• Expensive Connectors and Tools: OFCs require expensive connectors and tools, making maintenance and repairs more difficult and costly.
• Increased Protection: OFCs require more protection around the cable compared to copper wires.