Fiber optics

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High-speed data transmission for industrial applications

IDC predicts that by 2027, the volume of data created and replicated will reach 284 zettabytes, a 21-zero figure, threatening the Internet of Things without a nationwide broadband expansion, highlighting the need for significant data storage and replication.

The first transatlantic fiber-optic cable was operational in 1988, enabling high-speed data transmission between continents. The mid-1990s saw broadband expansion, adding more long-distance routes and moving fiberglass transmission paths closer to end devices like data centers, industrial plants, and personal computers, known as the “last mile.”

Data transmission across continents, countries, and municipalities requires high security and reliability. Speed, immunity to interference, and failsafe performance are basic requirements for industrial and semi-industrial data transmission.

The advantage of fiber optics

Fiber-optic cables (FO) transmit data in light over long distances by converting electrical signals into photon packets and sending them to the receiver via plastic or fiberglass. The light signals are then converted back into electrical signals for evaluation and processing.

This blog article explores the advantages of data transmission through fiber-optic cables over copper transmission, focusing on their characteristics.

Speed and distances

Fiber-optic cables use photons to transmit electrical signals, which are faster than electrons in copper conductors. Photons can travel up to 70% of the speed of light, with minimal signal loss. This allows for longer transmission distances of up to 50 km and data rates of up to 40 Gbps. The actual range depends on the chosen fiber-optic cable, making them suitable for long distances and large data volumes.

Reliability and security

Fiber-optic cables are reliable for data transmission due to their non-conductive cores made of glass or plastic, eliminating the need for complex shielding. They are metal-free, insensitive to EMC and ESD interference, allowing parallel use with other cables. Impedance problems and crosstalk are not issues. Fiber-optic cables with coatings protect against environmental influences in a much better way.

Fiber-optic cables offer enhanced cybersecurity due to their lack of external signals, requiring direct access via bend connectors or contact points, making them significantly more secure against eavesdropping than copper cables, despite not providing 100% protection against unauthorized access.

Costs

Fiber-optic technology has disadvantages such as complex assembly, precision, expensive equipment, complex measurement technology, and the need for well-trained specialists. Manufacturing and monitoring production are costly and require extensive expertise in this specialist field.

Which fiber for which application?

Fiber-optic data transmission cables are suitable for industrial and semi-industrial automation, spanning short, medium, and long distances, at speeds of 100 Mbps to 40 Gbps, and within bus or Ethernet structures. They can withstand harsh conditions, even on wind farms, and are up to 90% lighter and thinner than copper cables.

Fiber optic cables have various applications in vehicle technology, industrial cabling, data centers, wide area networks, and FTTH (Fiber To The Home). That is why, selecting the right type and fiber category is crucial.

Fiber types

Differentiating between fiber types is crucial, as singlemode and multimode fibers are not compatible due to different core and cladding diameters. The table provides a brief overview of fiber types.

POF for short transmission distances up to 100 m and up to 50 Mbps

POF cables, made of plastic core and cladding, are used in automotive engineering and industrial cabling for short transmission distances up to 100 meters and data rates of up to 50 Mbps. They are easy to assemble in the field due to their robustness, but not suitable for high data rates or long distances.

PCF for medium transmission distances up to max 2,000 m and up to 100 Mbps

Polymer-clad fibers (PCFs) are glass-coated fiber-optic cables, commonly used in industrial cabling with medium lengths of up to 500 meters and data rates of ≤100 Mbps. They are robust and easy to assemble, with applications in automotive, sensors, and medical technology.

Glass optical fiber (GOF) multimode for long transmission distances up to 550 m at up to 10 Gbps

Featuring a quartz core surrounded by reflective glass cladding, the multimode cables have core diameters of 50 µm or 62.5 µm and cladding diameters of 125 µm.

GOF multimode fibers, with larger core diameters, enable more light energy coupling at the fiber’s beginning but higher attenuation along its length, making them ideal for Local Area Networks and data centers where they can handle transmission distances of up to 550 m at 10 Gbps.

GOF singlemode for long transmission distances up to 50 km and up to 40 Gbps

The singlemode fibers have a smaller core diameter of 8 µm and a mode field diameter based on wavelength. They can transmit a large amount of signal light due to their single light mode and low attenuation coefficient. These fibers are ideal for distances up to 50 km and data rates up to 40 Gbps.

Cable types

Fibers are protected in robust cables to prevent mechanical stress and environmental influences. Indoor cables must be fire-resistant to prevent smoke and toxic gases. Outdoor fiber-optic cables need high robustness for long service life. They should be weatherproof, moisture-resistant, UV-resistant, and stable against mechanical strain. The cable type used depends on the application structure.

Loose tube cables

Loose tube cables

Loose tube cables contain numerous GOF fibers in one cable, protected by a coating and reaching a 250 µm diameter. These fibers are bundled in tubes, usually coated with a water-repellent gel, and can have up to 24 fibers combined in one tube, enabling high fiber density at a small diameter.

Unlike breakout cables, loose tube cables’ connectors cannot be directly mounted on fibers. Instead, they use fiber-optic pigtails for connection.

A pigtail is a fiber-optic connector with a preassembled plug on one end and spliced to the incoming cable’s fibers on the other open-end side

Loose tube cables, with their high tensile strength and well-decoupled fibers, are designed for harsh environments. They are suitable for temperature fluctuations and high-humidity environments. Available as outdoor and universal cables, they are suitable for both indoor and outdoor use.

Breakout cables

Breakout cable

Breakout cables are splitable fiber-optic cables with individual single-core elements housed in a shared protective cable cladding. In contrast to loose tube cables, all wires have their own cladding and their own strain relief. They were developed to avoid or replace on-site splicing work, as FO connectors can be mounted directly onto the cables. They can be used as patch cables or for laying cables by the meter between points in the field.

Mini breakout cables

Mini breakout cable

Mini breakout cables with GFO fibers feature 900 µm diameter wires in a shared cable cladding, providing protection from external influences. Ideal for future-proof cabling of distributors and junction boxes, these universal cables are suitable for both indoor and outdoor applications.

Duplex cables

Duplex cables

Fiber-optic duplex cables with GOF fibers consist of two 900 µm diameter wires, each routed separately. Preassembled at both ends, they allow direct connection to active and passive components. Wide connector combinations and fiber categories offer various applications.

Fiber categories

Fiber-optic cables are categorized into categories such as “OM3” and “OS2” based on their attenuation coefficient and bandwidth length product. Single mode fibers are in OS1 and OS2, while multimode fibers are in OM1, OM2, OM3, OM4, and OM5.

Transmission rates and ranges by category

Connection technologies and characteristics

Connection technologies

The table above provides an overview of various connection technologies and their characteristics for fiber-optic cables, including splices and connectors, which are suitable for connecting cables and other components.

Fusion splicing

Fusion splices are non-detachable connections between optical fibers, used for connecting loose tube cables to distributor boxes, repairing fiber breaks, and routing factory-assembled patch cables. They are durable and have minimal attenuation. However, they require trained specialists and special equipment, such as a fusion splicer with fiber processing tools, for proper handling.

Mechanical splicing/field assembly

Unlike fusion splicing, mechanical splicing do not permanently couple fibers. Instead, it involves connecting two fibers in a special V-groove or sleeve, ensuring clean and straight ends. or filling an index-matching gel between the fiber ends to match refractive indices. With identical GOF optical fibers and precise coupling, attenuation is approximately 0.2 dB. Mechanical splicing can be used in connectors for field assembly, end sockets, connection housings, and repair purposes, particularly for fiber-optic cables. This connection technology is particularly popular on end sockets, connection housings, and for repair purposes.

Plug-and-play connectors

These connectors are flexible, easy to disconnect, and secure, requiring no trained specialists or equipment. However, GOF connections have higher losses of 0.2 to 0.5 dB and lower durability compared to splice connections. There are various connectors with different characteristics and applications, with an overview of the most important ones.

Transmission rates and ranges by category

Applications

Communications engineering and IT primarily use fiber-optic cables for data transmission due to their long ranges and high transmission rates. These cables have been extensively tested and qualified for harsh ambient conditions. Due to their exceptional characteristics, small dimensions, and flexibility, fiber-optic cables are also attractive for other industries. Including building infrastructure, factory automation, and data centers. Applications include control signals, machine communication, Industry 4.0, and artificial intelligence.

Example application: Use of fiber-optic cables in wind farms

Fiber-optic cables are versatile tools for data transmission, with potential applications in medical technology, measurement technology, and even in harsh conditions like wind farms. They transmit data for monitoring usage, performance, and capacity utilization, ensuring reliable performance and efficiency in these critical applications.

Splice distributors, also known as splice boxes, are used for FO cabling, serving as a transfer point between passive and active components with corresponding FO interfaces. They also terminate loose tube cables, with fiber type selection based on link length and data rates.

Summary

Optical technologies are expected to advance in various applications, with fiber-optic cables being a robust alternative in data transmission, measurement technologies, medical, industrial, and lighting applications due to their small dimensions and flexibility.

Learn more about fiber optics or fill in your contact details in the fields below and one of our experts will provide you with comprehensive expertise and help you choose the right components for your FO cabling.

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