Throughput vs. Speed – Basics of Copper and Fiber Optic Cables for Superior Data Transmission AnD Cable Products

Copper cables have been a staple for data transmission for decades, with their roots tracing back to the telegraph and telephone. Fiber optic cables, introduced in the 1950s, have grown in popularity since the early 1970s. When choosing between copper and fiber optic cables for your applications, understanding the differences in throughput and speed is crucial. Let’s explore the history, transmission methods, and practical applications of these two types of cables.

The History of Data Cables

Copper cables have been the backbone of long-distance electricity and communication transmission for many years. Fiber optic cables emerged in the 1970s and rapidly gained popularity due to their unique capabilities. While both cable types serve similar purposes, their underlying technology differs significantly.

Copper cables transmit data through electrical impulses, which travel over short and long distances. However, copper has its limitations, including durability, signal loss, security vulnerabilities, and susceptibility to interference.

For more on this you can read our Whitepaper on copper cables below:

WHITEPAPER – Understanding Ethernet Patch Cords in Modern Networks

This whitepaper explores the differences in ethernet cable and connector properties, the relevant Standards and provides a guide to best use cases within data center environments

• Ethernet Patch Cords and RJ-45 Connectors
• Ethernet Patch Cords and UTP Cabling
• Twisted Conductor Pairs – What’s All the Twisting About?
• Straight-Through and Crossover Patch Cord Cables

Fiber optic cables utilize light pulses for data transmission, produced by an LED and transmitted through strands of specialized glass or plastic. Light and electricity can travel at near-light speeds, theoretically allowing global data transmission within seconds. Advances in fiber optic technology continue to improve data transfer rates.

Read our Whitepaper on fiber optic cables for more below:

WHITEPAPER – Understanding Fiber Optic Cables and Connectors in Modern Networks

This whitepaper takes a deeper look into the various fiber optic cable and connector types used in modern networks, their specifications, benefits and draw-backs. It details typical applications and use in data center settings.

• Fiber Optic Cable Types and Attributes
• Fiber Optic Connector Types and Attributes
• Fiber Optic Measurements and Classifications

Data Transmission Techniques

Understanding the methods of data transmission is essential, as it directly affects the cable’s reliability, speed, and maximum distance.

Copper cables rely on electrical pulses, which a decoder then interprets back into the original data. Over longer distances, signal attenuation, or deterioration, occurs due to resistance.

Fiber optic cables employ binary-coded light pulses, with a pulse representing a 1 and no pulse a 0. Optical receivers decode these pulses back into electronic data. The cable’s protective cladding and materials help maintain signal strength over long distances.

Speed vs. Throughput

Although both electrical and light pulses transmit data at near-light speeds, fiber optic cables are faster. The critical difference between copper and fiber optic cables is throughput, or the volume of data transmitted within a specific period.

For example, a legacy copper telephone line supports 3,000 simultaneous calls, while modern fiber optic network cables can handle up to 31,000 calls. As data transmission demands increase, the shift towards fiber optic cables is essential.

Throughput in data transmission refers to the cable’s ability to handle a specific data volume within a given time. For instance, some fiber optic cables can transmit up to 10Gbps, while copper cables manage only 25-300 Mbps. This significant difference stems from the cable’s frequency range, with higher frequencies enabling greater throughput.

Copper cables suffer from signal attenuation at both longer distances and higher frequencies. Additionally, their metal construction makes them prone to noise and electromagnetic interference, unlike fiber optic cables.

Selecting the Right Cable for Your Application

The primary factors to consider when selecting a cable are data volume, transmission frequency, distance, and potential interference.

Copper cables still have their place in data centers and other applications, primarily due to their lower cost. They are suitable for power and minimal data transmission across short distances in protected environments.

While copper cables have improved in durability and insulation, fiber optic cables have also advanced, now supporting even higher frequencies in thinner cables. The reduced size of fiber optic cables enhances airflow around server racks, mitigating tangling and breakage issues.

For expert guidance on fiber optic cables for new installations, moves, or changes, reach out to AnD Cable Products. Our team specializes in remote monitoring systems, Zero U cable management installations, and more. We are committed to supporting your business at every stage of development.