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The core technology behind these dense 1728-high fibre count IBR Cables is individual Intermittently Bonded Ribbons, each made up of 12 optical fibres, which are securely bonded at specific intervals along their lengths. Unlike traditional flat ribbons, IBR Cables offer a unique blend of space efficient design with a fully backward- compatible cable design, allowing seamless upgradation of optical infrastructures and further making it a readily deployable innovation in the field of optical fibre technology.

well all can build !! i am just taking what this tiny company doing

Fiber count: HFCL makes IBR cables with up to 1728 fibers.
Cable diameter: HFCL's IBR cables are small in diameter, allowing them to fit into ducts and conduits of various sizes.
Flexibility and scalability: HFCL's cables are designed to be flexible and scalable to meet the needs of data centers.
Quality: HFCL uses state-of-the-art facilities and stringent quality checks to ensure the quality of their products.
Types of cables: HFCL makes both armored and unarmored cables.
Bend resistance: HFCL's micro-module cables have enhanced bend resistance to protect the fibers during installation and maintenance.

Is Railway comes under same category ?

Optical fiber sensing (OFS) technologies are used in the railway industry to monitor the condition of the tracks, rolling stock, and other components. Some of the best OFS technologies for the railway industry include:
Fiber Bragg Grating (FBG): These sensors are small, easy to handle, and have high resolution and accuracy. They are often used for local measurements, but multiple FBGs can be connected to create a quasi-distributed sensing element for longer distances.

Distributed Fiber Optic Sensing (DFOS): This technology uses optical fibers laid alongside the tracks to create a large array of distributed sensors. DFOS can monitor acoustic signals from events like train movements and wheel-rail interactions. This helps to identify problems early, which can improve safety and reduce the risk of failures.

Light scattering-based sensors: These sensors are suitable for continuous and long distance measurement.

Where Railway need?

1. Vibration Monitoring
Distributed Acoustic Sensing (DAS) uses fibre optics to sense and monitor vibrations. A railway line can install this fibre optic solution to help them detect obstacles on the track, wheel damage, and locate the train’s position, amongst other things.

2. Data Transmission
Optical fibre cables transfer data via pulses of light. The speed at which data is transmitted is substantially faster than those delivered electronically. High-speed data transmissions enable train staff to receive important information quickly, helping them to react and respond accordingly.

3. Long-Distance Communication
Fibre optic cables can provide information over long distances, enabling train drivers to learn about real-time events near the monitored area.

4. Security
Since fibre optic cables are non-metallic, they are immune to electromagnetic interference (EMI). In short, signals are unaffected by environmental electrical noise, so data remains strong and secure. Also, sensitive data is encrypted as ciphertext, making it difficult for hackers to access.

5. Safety and Reliability
As mentioned, fibre optic cables are weather resistant. They are a highly durable cable choice and can survive most weather conditions. The high immune levels of fibre optics mean they experience fewer outages, making them more reliable for networks and increasing railway signal connectivity.