What is Hollow Core Fiber (HCF) Testing?

HCF uses photonic bandgap or anti-resonant structures to confine light within the hollow core. This allows light to travel closer to its theoretical speed when in a vacuum. This design significantly reduces latency and signal distortion, making it a promising solution for high-performance communication systems.

Currently there are two main types of hollow core fiber, double nested anti-resonant nodeless fiber (DNANF) and photonic bandgap guiding fiber (PBG), each with their own internal hollow core fiber structure and manufacturing process.

Source: University of Southampton

It is too early to know if there will be a dominant design, but the end goal is the same: to guide the light along the core, filled with air or a vacuum, in order to get as close as possible to speed-of-light transmission in free space.

Double nested anti-resonant nodeless fiber (DNANF)
Source: University of Southampton

Photonic bandgap guiding (PBG)
Source: Lightera

These air-guided structures significantly reduce the interaction between light and fiber material, resulting in several performance advantages.

Key Benefits of HCF

Hollow core fiber offers several significant advantages, including:

• Lower latency: HCF transmits light at nearly the speed of light in vacuum, resulting in latency of approximately 3.33 µs/km, compared to 4.9 µs/km for SMF
• Reduced chromatic dispersion (CD): HCF typically exhibits CD values <5 ps/nm/km, while SMF shows ~17 ps/nm/km
• Equivalent polarization mode dispersion (PMD): HCF can achieve PMD values below 0. 1 ps/√km, compared to 0.1 ps/√km for SMF
• Reduced nonlinear effects: Due to minimal light-material interaction, HCF exhibits negligible nonlinearities
• Lower attenuation at specific wavelengths: Recent advancements have achieved attenuation as low as 0.07 dB/km, outperforming typical SMF values of ~0.2 dB/km
• High damage threshold: The air core allows HCF to handle higher optical powers without thermal damage

Fast Pace of Development

The following figure shows the evolution of solid core fiber versus hollow core fiber in terms of attenuation levels (dB/km). It has progressed significantly in just the last 10 years and now offers lower attenuation per kilometer than standard single mode fiber.

HFC vs SMF Loss Reduction Over Years

Source: University of Southampton

Qualifying HCF Installations

Deploying hollow core fiber (HCF) introduces a unique set of challenges that differ significantly from conventional SMF installations. Proper qualification requires adapting both tools and procedures to account for the distinct physical and optical properties of HCF.

SMF-to-HCF Adapter Loss

Transitioning from SMF to HCF introduces coupling inefficiencies due to mismatched mode fields and core geometries. Adapter losses can range from 0.2–3 dB, depending on alignment precision and connector quality. These losses must be carefully measured when commissioning a link. The transition from glass-air also generates a high reflection of up to -15 dB when not properly done, this will be a challenge for an optical time domain reflectometer (OTDR), it will generate tailing on the trace and may mask some events close to this first connection. It is important to control this first adapter and ensure reflection as low as possible: better than -50dB.

Bending Radius and Bend Sensitivity

HCFs are 10× more sensitive to bending than SMFs due to their complex micro-structured design and air-core geometry. While SMFs can tolerate bend radius as low as 7.5 mm (especially bend-insensitive variants), HCFs often require minimum bend radius of several centimeters to avoid excessive attenuation or structural damage. This makes HCF less suitable for tight routing environments unless specifically engineered for bend tolerance. Installers must ensure proper routing and strain relief to maintain performance. The following figure shows the different bending radius of different fibers compared with hollow core fiber. 

Minimum bending radius HCF vs. ITU G.657

Minimum bending radius HCF vs. ITU G.657
Source: Broadband library

Rayleigh Backscattering (RBS)

HCF exhibits RBS levels approximately 14 to 20dB lower than SMF. This significantly affects OTDR trace visibility, making it harder to detect events and measure distances with standard OTDR settings.

Variable Backscattering Coefficient

Unlike SMF, where backscattering is relatively uniform, HCF may show non-uniform backscattering along the fiber length due to microstructural variations. This complicates OTDR trace interpretation and requires different test settings than for SMF (K factor).

OTDR trace showing the variation of RBS coefficient and the reflective splices

Standard uni-directional OTDR trace showing the variation of RBS coefficient and the reflective splices

Variable backscatter coefficient also means that bidirectional OTDR test and analysis is the only method suitable for characterizing fiber and splice losses. In addition, the standard bidirectional OTDR analysis algorithms and tools will not be able to manage and produce meaningful results again due to the variable backscatter coefficient.

HCF-to-HCF Splice Loss

Fusion splicing between HCF to HCF segments is more complex and can result in splice losses of 0.1–1.5 dB, depending on fiber alignment and cleanliness.  Compared to splices between SMF to SMF, HCF to HCF splices generate reflectance which exceed the backscattering level (as shown above) which create dead zones. In the field, splices could be 2 to 4 km apart; therefore it is important to have an OTDR with high dynamic range at short pulse to be able to measure each of them without merging of events.

Non-Standard OTDR Traces

HCF produces different OTDR signatures compared to SMF. The lower backscatter (-14 to -20dB) and unique modal behavior result in different traces, reflective splices and infiltration of ambient air components around the splice point. Standard OTDR settings may fail to detect key features, requiring different testing parameters such as pulse width and averaging time.

Trace from a coherent ODTR measuring 14dB difference of RBS from SMF to HCF

Trace from a coherent ODTR measuring 14dB difference of RBS from SMF to HCF

OTDR test wavelength

Currently most HCFs are optimized for operation in the S-band (starting around 1450nm) and above. Hence OTDR testing at 1310nm, as typically done with standard SMF, will not produce relevant or useful results so testing at 1550nm is required. As with SMF testing, using additional wavelengths allows for better fiber and splice loss characterization and bend detection. Therefore, at present HCF will require measurements at 1550nm and 1625nm for field acceptance testing.

Post-Processing Analysis (HCF Loss Profile)

Due to the unique trace characteristics (RBS varying along the fiber), standard OTDR post-processing analysis algorithms do not apply. Custom software or manual interpretation is often needed to assess splice quality, connector loss, and fiber integrity. It is necessary to match each measurement point from each direction, align the two traces and make a bidirectional analysis, (AB-BA)/2, to obtain the actual loss profile. Loss profile trace obtained by bidirectional analysis will then allow measurement of attenuation for each HCF section and the loss of each event on a link. 

OTDR traces acquired from testing HCF in both directions (A-B and B-A)

OTDR traces acquired from testing HCF in both directions (A-B and B-A)

Loss profile trace obtained by performing bidirectional analysis

Loss profile trace obtained by performing bidirectional analysis

To learn more about selecting the right HCF test equipment, OTDR setup, testing procedure, result processing and analysis, download this Hollow Core Fiber Testing application note

As HCF is relatively new and manufacturers are in the early stages of production and field trials it would be prudent to verify additional characteristics. In addition to bidirectional OTDR testing and bidirectional OTDR analysis, some attention should be paid to attenuation profile (AP), chromatic dispersion (CD), and polarization mode dispersion (PMD).

In order to confirm HFC is installed properly, it should be characterized completely (OTDR, AP, CD, PMD) to avoid any compromise in initial or future performance.

Attenuation Profile (AP)

Attenuation profile testing helps identify non-ideal transmission characteristics such as absorption regions (attenuation) caused by water vapor. During manufacturing the presence of gas could generate a degassing process creating absorption at certain wavelengths.

The AP of standard glass fibers is well known and is homogeneous from one manufacturer to another. Unlike HCF, where we are at the early stages of production and deployment, new HCF technologies and manufacturing processes are leading to different profiles.

As a result, post-installation testing of the attenuation profile becomes essential to validate the actual transmission capacity of the link, confirm manufacturer specifications, and ensure compatibility with system requirements. This is especially important in applications where wavelength-specific performance is critical

In field trials, a significant number of manufacturers and end customers have requested this information to assess link quality and verify performance claims before type approving or accepting a link.

Hollow core fiber attenuation profile measurement

Hollow core fiber attenuation profile measurement

Chromatic Dispersion (CD) and Polarization Mode Dispersion (PMD)

HCF are designed to transmit longer distance and higher speed therefore dispersion could have an impact on future upgrade of transmission rate, knowing the real base line is important.  Even though dispersion effects are much lower in HCF versus SMF there is a risk of inconsistency as new HCF manufacturing processes are established, validation of CD and PMD parameters ensures nothing unexpected has occurred after splicing all HCF sections together.

Therefore, in addition to bidirectional OTDR testing, CD and PMD are key for full HCF link characterization and certification. However, OTDR-based dispersion tests are limited by the same 14–20 dB drop in Rayleigh backscatter and dynamic range constraints, making them suitable only for short links.

A more accurate approach uses dedicated optical broadband light sources and dispersion measurement devices, such as the VIAVI OBS-500 optical broadband source and Optical Dispersion Measurement (ODM) module, bypasses these limitations and enables reliable long-distance testing

Techniques such as phase shift for CD and fixed analyzer for PMD offer precise results with greater dynamic range.

To learn more about the Fiber Characterization download our poster here.