VIAVI offers the ONLY fully-portable DTS and DTSS solution that also contains a classic OTDR. Most temperature and strain sensing devices are rack-mounted only. Our fiber sensing solutions are modular in design, battery operated and compatible with the T-BERD/MTS-8000 Scalable Multi-test Platform, or the VIAVI ONMSi solution combined with an OTU-8000 unit. The OTU-8000 is a modular optical test head that contains the OTDR, Brillouin-OTDR, Raman-OTDR and a switch to monitor many fibers in an automated routine.
Fiber Optic Sensors
- What type of fiber optic sensing interrogators does VIAVI offer?
The VIAVI fiber sensing portfolio includes:
- DTS (Distributed Temperature Sensing) based on Raman OTDR technology
- DTSS (Distributed Temperature and Strain Sensing) based on Brillouin OTDR technology
- How can infrastructure be inspected periodically?
Using a portable, such as the VIAVI T-BERD/MTS-8000 platform with a DTS or DTSS module, a technician can go out into the field and conduct field measurements on fibers. Alternatively, using ONMSi and a rack-mounted OTU (Optical Test Unit) with a DTS or a DTSS monitors fibers using periodic traces that are set to alarm if there is a change from the beginning reference trace.
- What are the economic benefits of using distributed fiber optic sensors over traditional electro-mechanical sensors?
Fiber optic sensors are much less expensive and less labor intensive to install and utilize as a data point rich source. The fibers in the cable make up the distributed sensor and this material is inexpensive, lightweight and easy to attach or embed to an object under test.
Fibers are highly-reliable distributed sensors that do not require constant electrical current to produce data, and they are immune to electro-magnetic and radio-frequency interference. Historically, heavy, wired, electrified sensors that are labor intensive to install have been the main data source for obtaining strain or temperature data.
Electro-mechanical sensors can fall off, be intrusive and cost prohibitive and they require a power source. In locations where power is not readily available or, corrosion, vibration or EMI is a problem, they are not practical. Electrical and radio noise ingress or egress distorts their measurement data. A bridge that needs safety monitoring is a prime candidate for cost-effective fiber optic sensor monitoring, in which the fibers can be embedded or retro-actively attached to the bridge to detect strain and risk of failure before the bridge actually fails. As long as the fiber is not bent excessively, the fiber can be installed in a sine wave shape to allow for more data points across a surface. An OTDR can detect micro and macro bends and can be used to optimize the fiber strain and bends at the installation of the fiber sensor if a slightly strained fiber is required in the application.
- What advantages and data types can be obtained from fiber optic sensors?
Fiber optic sensors can provide multiple types of data through optical time domain reflectometry (OTDR) including data on the acoustics, strain, temperature and light transmission properties that indicate movement, or bends and breaks in the fiber. This data can be provided across the entire length of the fiber(s) instead of being limited to discrete and intermittently placed sensor sites. For example, using an OTDR to measure these items will reveal where the temperature changes by gradient across a long fiber span. One can also see where strain in the form of fiber elongation begins and ends. In telecommunications, strain needs to be avoided and thus measuring this protects the network and allows proactive cable strain mitigation and repair. If one wants to monitor a bridge, the strain on the fiber sensor can indicate movement of the bridge such as sagging, sinking or stress caused by separation of the bridge plates.
Consider measuring temperature throughout a building that requires a very specific temperature range, such as a data center, nuclear plant, or blood bank storage facility. Traditional electrified thermostatic sensors are placed in several locations and take periodic discrete point readings. Electronic temperature sensors are expensive and requires constant electrification. What happens when the location is missing a sensor or the sensor fails due to power loss, temperature extremes, or EMI interference? The temperature is not optimally regulated creating a hot or a cold spot. A fiber optic sensor net in the form of one or more fiber cables can be run throughout the building to obtain readings across continuous locations. The fiber net can provide more data points for better coverage at a lower cost with higher reliability. A pulse of light emitted by a laser OTDR is all that is required to interrogate the fiber sensor and the device can be powered by a battery in case of a power outage for more than a day.
What are some game-changing applications of fiber optic sensors?
- Data and Telecommunications Fiber Cable Monitoring:
Communications cables are placed all over the world in rugged, inhospitable subterranean, submarine and aerial environments where ice, wind, earth movement/erosion, waves, vandalism, and human error constantly strain or break the cables, causing both service outages and service degradation. Cables are sometimes strained accidentally during installation. Once excessively strained, the cable is at risk of breaking and the lifespan of the cable is dramatically reduced from 35-40 years to potentially just months.
Long-haul and submarine cables are mission critical but are difficult to service in inclement weather or remote, dangerous terrain. Distributed strain sensing with a fiber optic sensor will allow a network cable owner to test the fiber at installation, and then monitor a dark fiber for excessive strain risk and changes in strain while in service to mitigate breakage. Mauritania recently experienced a break in the submarine cable that disconnected the entire network from the internet for two days. This was caused when a trawler lifted the African Coast to Europe cable off the sea floor and broke it. Had this cable been monitored for strain, an alarm would have triggered as the cable was being pulled before it broke. If it did end up breaking, a classic Rayleigh OTDR could have located the break within one meter, thus reducing the outage time.
Consider an aerial cable bearing an excessive ice load. The network operator can monitor the cables and locate network segments where staff should perform ice removal to prevent excessive strain. After a strain event has occurred, the cable can be tested against MAT tolerance measurements to be prioritized for replacement. Both portable DTSS fiber optic sensor OTDRs and rack-mounted fiber interrogation OTDRs are available.
- Communication Cable Repair and Insurance Coverage Chargeback:
The most common cause of cable breakage is due to construction digging, aka backhoe attenuation. Often when the break is located, the cable is spliced or connectorized at the break location. However, this may only resolve the problem temporarily because the strain has damaged many meters of cable on both sides of the break when the backhoe pulled the cable out of the ground.
The cable may break again as it is re-installed or become so degraded that it is too damaged to provide adequate service. Repeat repairs are expensive and cause additional service outages. By taking distributed strain measurements with a fiber optic sensor OTDR in both directions up and down the cable when the break occurs, the technician can provide scientific evidence to demonstrate precisely which section(s) of cable should be replaced. This evidence can be used to charge the responsible party for the cost of the damage. It prevents further repeat repair dispatches and service disruption to customers as well as unnecessary repairs on good cable sections that have not experienced strain damage.
- Pipeline or Dam Leak Detection:
Pipelines carry all types of expensive and potentially caustic materials in the oil, chemical, food, waste and water industries. A spill, leak that causes contamination into the pipeline, or theft can cause catastrophic problems. Pipeline monitoring is accomplished by measuring fibers for temperature and strain along the pipeline. Likewise, a dam or dike can be monitored similarly. A leak is suspected if there is a dramatic change in temperature, or the strain or light reflectance properties of the fiber. Temperature can be indicative of a leak or tap, strain is indicative of risk of breakage due to unexpected movement, and the problem can be located within a meter by using classic light reflectance Rayleigh scattering OTDR analysis. A combination optical interrogator, for strain, temperature and light reflectance can be used in a rack-mounted OTDR monitoring solution to continually monitor the fiber sensors attached to the pipeline. Fiber optic sensors provide accurate detection allowing shutdown, inspection, and repairs to be done quickly.
- Powerline Hot Spot Detection:
Electrical hot spots on power transmission plants cause life-threatening fire risk and infrastructure damage. A recent example may have happened in California, USA when an electrical hot spot or downed electric cable may have ignited a forest fire. Lives and property were lost and now the utility is facing lawsuits and bankruptcy.
Remote fiber sensing using distributed temperature sensing (DTS) is the only economical way to monitor such problems and is much less expensive than the cost of such a catastrophic event. A fiber is placed along the transmission line to remotely monitor the line. An alarm is triggered when the fiber optic sensor system detects a rise in temperature, a strain or bend that can indicate a line fall. By pairing it with Rayleigh OTDR analysis, a precise location can be determined when there is either a gradual or abrupt shift in the fiber position by comparing a reference trace to a constant, periodic trace. The alarm can trigger an emergency power shutdown and investigation of the transmission lines. Because the fiber analysis using a fiber optic sensor is immune to EMI, it is the ideal source of data in this high EMI environment.
Predicting Fiber Breaks and Weak Points
Field Trial of Strain B-OTDR Using Brillouin-Based Fiber Strain Measurements over Long-Distance Aerial Cables
Distributed Fiber Optic solution for measuring Temperature and Strain using single ended Brillouin OTDR