Summit Fiber Optic Distributed Strain and Temperature Measurement Systems

1, 4 Channels; Dynamic Range 25 dB; Sampling Rate 10-5,000 Hz; Wavelength Range 1500-1620 nm; Wavelength Accuracy 1, 2 pm; Wavelength Stability 1, 3 pm; Optical Fiber Connectors LC/APC Luna’s HYPERION si155 is an industrial-grade, fan-less fiber optic sensing interrogator. Featuring both static and dynamic full spectrum analysis, Luna’s HYPERION si155 robust, turn-key interrogator provides long-term, reliable and accurate measurements of hundreds of Fiber-Bragg Gratings (FBGs) or extrinsic Fabry-Perot (FP) sensors on 4 parallel, 160 nm wide channels. The si155 interrogator features an all new, high-power, low-noise, ultra-wide swept wavelength laser with guaranteed absolute accuracy on every scan which is realized with Luna’s patented Fiber Fabry-Perot filter and wavelength reference technology. The HYPERION platform, on which the si155 is based, features new and groundbreaking capabilities including high-performance on-board DSP and real-time FPGA processing. This enables rapid full-spectrum data acquisition and flexible peak detect algorithms of Fiber Bragg Gratings (FBG), Long Period FBGs (LPG), Fabry-Perot (FP) and Mach-Zehnder (MZ) sensors with low-latency access to data for closed-loop feedback applications. HYPERION static full-spectrum optical interrogators measure the full optical spectrum of the optical sensor signals and can be equipped with a NIST absolute reference cell. The performance of the static interrogator module is characterized by high dynamic range and high absolute wavelength accuracy. The HYPERION platform is now compatible with the ENLIGHT sensing analysis software, which provides a single suite of tools for data acquisition, computation, and analysis of optical sensor networks. More information on the ENLIGHT software can be found in the downloadable datasheet. The HYPERION platform also includes a comprehensive fully supported application programing interface (API) and LabVIEW, Python, Matlab, and C++ examples. Whether an application requires static or dynamic real-time acquisition or periodic monitoring, Luna offers the right instrument for the job. Proven to be an essential element in reliable, long-term sensing measurement installations, Luna’s sensing instruments have been installed in hundreds of challenging applications all over the world, including large-span bridges in China, earthquake monitors in California, oil platforms in Brunei and marine vessels in the North Sea. Key Features: Full Spectrum at 1 kHz With 160 nm on 4 Parallel Channels Simultaneously, Eliminating the Need for Optical Switches Dynamic and Absolute Measurements of Fiber Bragg Gratings (FBGs), Long Period FBGs (LPGs), Fabry-Perot (FP) and Mach-Zehnder (MZ) Optical Sensors From Detailed Optical Spectrum Single and Continuous 25 dB Dynamic Range, Available to Each Sensor on Each Channel, Independent of Differential System Losses Modes: Enhanced Visibility (10 Hz), Standard (100 or 1,000 Hz), High Speed (5,000 Hz) Number of Channels: 1, 4 Wavelength Range: 1500 to 1620 nm Wavelength Accuracy / Stability: 1 pm/1 pm, 2 pm/3 pm Optical Fiber Connectors: LC/APC Data Verification Key Guarantees only Valid Output. Each Data Set is Calibrated and Verified Against any Potential Sources of System Error (Coming Soon) Proven Reliability and Longevity of the Luna Swept Wavelength Source, With Over 100 Million Hours Logged Since 2000 Dimensions: 206 x 274 x 79 mm Applications: Fiber Optic Sensing of – Oil & Gas; Medical Devices; Industrial Measurements; Energy; Structures; Security; Aerospace

4-16 Channels; Dynamic Range 25 dB; Sampling Rate 100-1,000 Hz; Wavelength Range 1460-1620 nm; Wavelength Accuracy 1, 2 pm; Wavelength Stability 1, 3 pm; Optical Fiber Connectors LC/APC Luna’s HYPERION si255 is an industrial-grade, fan-less fiber optic sensing interrogator. Featuring both static and dynamic full spectrum analysis, Luna’s HYPERION si255 robust, turn-key interrogator provides long-term, reliable and accurate measurements of nearly 1000 of Fiber-Bragg Gratings (FBGs) or extrinsic Fabry-Perot (FP) sensors on 16 parallel, 160 nm wide channels. The si255 interrogator features an all new, high-power, low-noise, ultra-wide swept wavelength laser with guaranteed absolute accuracy on every scan which is realized with Luna’s patented Fiber Fabry-Perot filter and wavelength reference technology. The all new HYPERION platform, on which the si255 is based, features new and groundbreaking capabilities including high-performance on-board DSP and real-time FPGA processing. This enables rapid full-spectrum data acquisition and flexible peak detect algorithms of Fiber Bragg Gratings (FBG), Long Period FBGs (LPG), Fabry-Perot (FP) and Mach-Zehnder (MZ) sensors with low-latency access to data for closed-loop feedback applications. HYPERION static full-spectrum optical interrogators measure the full optical spectrum of the optical sensor signals and can be equipped with a NIST absolute reference cell. The performance of the static interrogator module is characterized by high dynamic range and high absolute wavelength accuracy. The HYPERION platform is now compatible with the ENLIGHT sensing analysis software, which provides a single suite of tools for data acquisition, computation, and analysis of optical sensor networks. More information on the ENLIGHT software can be found in the downloadable datasheet. The HYPERION platform also includes a comprehensive fully supported application programing interface (API) and LabVIEW, Python, Matlab, and C++ examples. Whether an application requires static or dynamic real-time acquisition or periodic monitoring, Luna offers the right instrument for the job. Proven to be an essential element in reliable, long-term sensing measurement installations, Luna’s sensing instruments have been installed in hundreds of challenging applications all over the world, including large-span bridges in China, earthquake monitors in California, oil platforms in Brunei and marine vessels in the North Sea. Key Features: Full Spectrum at 1 kHz With 160 nm on up to 16 Parallel Channels Simultaneously, Eliminating the Need for Optical Switches Dynamic and Absolute Measurements of Fiber Bragg Gratings (FBGs), Long Period FBGs (LPGs), Fabry-Perot (FP) and Mach-Zehnder (MZ) Optical Sensors From Detailed Optical Spectrum Single and Continuous 25 dB Dynamic Range, Available to Each Sensor on Each Channel, Independent of Differential System Losses Modes: Enhanced Visibility (10 Hz), Standard (100 or 1,000 Hz), High Speed (5,000 Hz) Number of Parallel Channels: 4, 8, 16 Wavelength Range: 1500 to 1620 nm Wavelength Accuracy / Stability: 1 pm/1 pm, 2 pm/3 pm Optical Fiber Connectors: LC/APC Data Verification Key Guarantees only Valid Output. Each Data Set is Calibrated and Verified Against any Potential Sources of System Error (Coming Soon) Proven Reliability and Longevity of the Luna Swept Wavelength Source, With Over 100 Million Hours Logged Since 2000 Dimensions: 307 x 274 x 69 mm Applications: Fiber Optic Sensing of – Oil & Gas; Medical Devices; Industrial Measurements; Energy; Structures; Security; Aerospace

1-4 Channels; Dynamic Range 17-45 dB; Sampling Rate 10-5,000 Hz; Wavelength Range 60-160 nm; Wavelength Accuracy 1 pm; Wavelength Stability 1 pm; Optical Fiber Connectors LC/APC Luna’s HYPERION Single Board Interrogator is a high-performance optical sensing instrument that offers unmatched ease of integration for OEM systems. A full suite of software tools typically only available to high end instruments is among one of the many features of the HYPERION Single Board Interrogator. Derived from Luna’s HYPERION si155 platform, the HYPERION Single Board Interrogator leverages the unmatched gains which are realized with Luna’s patented fiber Fabry-Perot filter and wavelength reference technology. The HYPERION Single Board Interrogator features groundbreaking capabilities including high-performance DSP and real-time FPGA processing on-board, which enables rapid, flexible peak detect algorithms of Fiber Bragg Gratings (FBG), Long Period Gratings, Fabry-Perot (FP), Mach-Zehnder (MZ) sensors, and others with low-latency access to data for closed-loop feedback applications. HYPERION static full-spectrum optical interrogators measure the full optical spectrum of the optical sensor signals and can be equipped with a NIST absolute reference cell. The performance of the static interrogator module is characterized by high dynamic range and high absolute wavelength accuracy. The HYPERION Single Board Interrogator is compatible with the ENLIGHT sensing analysis software, which provides a single suite of tools for data acquisition, computation and analysis of optical sensor networks. More information on the ENLIGHT software can be found in the downloadable datasheet. This interrogator also includes a comprehensive application programing interface (API) and examples written in LabVIEW, Python, Matlab, C++ and C#. Whether an application requires static or dynamic real-time acquisition or periodic monitoring, Luna offers the right instrument for the job. Proven to be an essential element in reliable, long-term sensing measurement installations, Luna’s sensing instruments have been installed in hundreds of challenging applications all over the world, including large-span bridges in China, earthquake monitors in California, oil platforms in Brunei and marine vessels in the North Sea. Key Features: Truly Turn-key Solution Providing Quick Start-up and Data Collection With Minimal Software or Electronic Design Required for System Implementation With Added Benefit of Reduced Cost Dynamic Measurements of Fiber Bragg Gratings (FBGs), Long Period FBGs (LPGs), Fabry-Perot (FP) and Mach-Zehnder (MZ) Optical Sensors From Detailed Optical Spectrum Data Verification Key Guarantees only Valid Output. Each Data Set is Calibrated and Verified Against an Available Permanent NIST Traceable Reference Feature-rich ENLIGHT Software and API Support, Available at No Cost for Sensor Conditioning, Data Visualization and Data Saving Definitions Deep, Continuous Dynamic Range of 17 to 45 dB is Available to Each Sensor on Each Channel, Independent of Differential System Losses Modes: Enhanced Visibility (10 Hz), Standard (100 or 1,000 Hz), High Speed (5,000 Hz) Number of Parallel Channels: 1 to 4 Wavelength Range: 60 to 160 nm Wavelength Accuracy / Stability: 1 pm Optical Fiber Connectors: LC/APC Proven Reliability and Longevity of the Luna Swept Wavelength Source, With Over 100 Million Hours Logged Since 2000 Dimensions: 203 x 273 x 53.5 mm Applications: Fiber Optic Sensing of – Oil & Gas; Medical Devices; Industrial Measurements; Energy; Structures; Security; Aerospace

1 Channel; Dynamic Range >15 dB; Wavelength 780 nm; Spatial Resolution 10 cm; Measurement Range 250 m; Temperature Accuracy 1.5 °C; Optical Fiber Connectors E-2000 APC, Other Luciol Instruments’ LDT-100 high-resolution distributed optical temperature sensor measures the temperature profile across standard optical fibers. The measurement technique is based on Raman scattering. Due to the temperature dependence of the Raman scattering signal (Anti-Stokes), temperature variations along the sensing optical fiber are transformed in a variation of the backscattered signal. The LDT-100 uses photon-counting technology to achieve a high detection efficiency and very high spatial resolution. An internal temperature calibration reference makes the system ready for testing and minimizes time consuming user re-calibration. The LDT-100 also integrates OTDR testing capability which allows integrity and condition testing of the sensing optical fiber. The LDT-100 is a fully portable, simple and easy-to-use instrument, with user-friendly GUI software. A desktop version with USB interface is available as an option. If the standard models should not meet your needs, contact AMS Technologies with your requirements and together let us find the customized solution to your fiber optic measurement challenge Key Features: Fully Portable Format Measurement Range: 250 m Sampling Resolution: 2 cm (200 ps) Temperature Spatial Resolution: 10 cm Temperature Accuracy: 1.5 °C Operating Wavelength: 780 nm Optical Pulse Width: 1 ns Fiber Type: MMF 62.5/125 µm Optical Connector: E-2000 APC, Others on Request Integrated Calibration OTDR Testing Capability Dynamic Range OTDR: >15 dB Event Dead-zone OTDR: 10 cm Typical Attenuation Dead-zone OTDR (for ORL = 45 dB): 40 cm Typical Distance Accuracy OTDR: ± (10 mm + 5 x 10-5 x Fiber Length) Desktop Format Option Operating Temperature: 0 to +40 °C Weight: 3.1 kg Dimensions: 320 x 240 x 90 mm Applications: Distributed Temperature Monitoring With cm Spatial Resolution; High-resolution Temperature Profile Measurement; Temperature Surveillance; Other

1-8 Channels; Max. Sensor Length/Channel 10, 50 m; Measurement Points/m 384, 768, 1,538; Measurement Rate 10-250 Hz; Strain Measurement Range ±12,000 µɛ; Temperature Measurement Range -40 to 200 °C Luna’s ODiSI 6000 series of optical distributed sensor interrogators are innovative measurement systems specifically designed to address the test challenges of 21st century advanced materials and systems. The systems provide thousands of strain or temperature measurements per meter of a single high-definition fiber sensor. The high-definition data can fully map the contour of strain for a structure under test or the continuous thermal profile of a process in real time. Sensors are flexible, low-profile, require no electrical source, and can be bonded to sharply curved surfaces, embedded withing structures, or mounted directly to electrical surfaces. An ODiSI 6000 series system comes configured with 1, 2, 4 or 8 channels able to measure standard Rayleigh HD-FOS sensors. In standard mode, each channel supports an HD-FOS sensor up to 10 m in length. With the extended range option, up to four channels can support sensors up to 50 m in length each. The ODiSI 6000 series can be configured to measure strain or temperature with a gage pitch (spacing of adjacent gage centerpoints) of 0.65 mm, 1.3 mm or 2.6 mm. When configured for a gage pitch of 0.65 mm, the system acquires 1,538 strain or temperature measurement points along every meter of the HD-FOS sensor. The ODiSI 6000 system is able to measure HD-FOS data at rates up to 250 Hz. The per-channel measurement rate will depend on several factors, including number of channels, gage pitch and sensor length. See specifications in the downloadable data sheet for more information on real-time measurement rates. Key Features: Single- or Multi-channel Measurements of Strain-multiplex: Over 300,000 Measurement Locations Flexible, Lightweight and Easy to Install Sensors Reduce Time to First Measurement Passive, Corrosion Resistant, Dielectric, Flexible Sensors Go Where Other Sensors Can’t – in Bends, Around Corners, Embedded Inside Materials Long Sensor Life – No Drift or Recalibration Required, Cycle Counts >107 Large Strain Range and High Resolution Allow for Mapping of Complex Strain Fields and Large Strain Gradients Number of Parallel Channels: 1 to 8 Maximum Sensor Length Per Channel: 10, 50 m Measurement Points Per Meter of Sensor: 384, 768, 1,538 Measurement Rates: 10 to 250 Hz Strain Measurement Range: ±12,000 µɛ Strain Measurement Resolution: 1 µɛ Temperature Measurement Range: -40 to 200 °C Temperature Measurement Resolution: 0.1 °C Dimensions: 340 x 350 x 110 mm Applications: Characterize Strain on/in New Materials and Complex Structures; Profile Temperature In-situ to Maximize the Efficiency of Critical Processes; Measure Two – and Three – Dimensional Strain Fields to Validate FE Models; Evaluate Multi-material Joining; Embed Sensors Within Materials to Create “Smart Parts”

8 Channels; 16,384 Sensors; Total Sensing Length 104 m; Spatial Resolution 1.6 mm; Temperature Measurement Range -270 to +1,200 °C Sensuron’s RTS125+ series of fully ruggedized, compact fiber optic sensing system delivers reliable measurements in today’s most demanding environments. Distributed sensing capabilities make it possible to measure different parameters using a single system. This simplifies the collection and monitoring of diverse measurements. Its compact size, robust enclosure and increased efficiency make it an appealing choice for demanding installations with stringent limitations on physical space and power consumption. By combining data from multiple fibers, the technology can provide 3D visualization of shape and strain.RTS125+ can simultaneously measure strain, temperature, deflection, 3D shape positioning and more—making vast amounts of data available in real time. In today’s world, success is increasingly predicated on the ability of an organization to obtain and interpret large quantities of data. The RTS125+ allows engineers across industries to gather the data they want, not just the data they can get.The RTS125+ hardware sensing system is about the size of a loaf of bread. Weighing just 13 pounds, the system is ideal for use in numerous applications where weight and power consumption are key factors. The RTS125+ processes information at rates up to 100 times per second, representing a 20-fold improvement over existing technologies. The sensing system can derive key measurements in addition to strain and temperature, including 3D shape, deflection, pressure, strength, stiffness (bending and torsion), liquid level, and operational load. The RTS125+ offers unprecedented levels of data intensity – each 13 m hair-like optical fiber provides up to 2,000 data points with adjustable spatial resolution. Key Features: Ruggedized Eight Simultaneously Monitored Fibers with Over 2,000 Equally Spaced Sensors per Fiber Aggregate Sensing Length of 104 m Software Selectable Spatial Eesolution Down to 1.6 mm Real-time, High-resolution Distributed Strain and Temperature Measurements Up to 100 Hz Acquisition Rate Structural Deflection and 3D Shape Sensing Capability Immune to EMI/RFI and Radiation for Reliable Operation in Demanding Environments Applications: Aerospace – Monitoring Changes in Wing Load Distribution, Shape, Liquid Level and More; Automotive – Studying Automobile Frame Deformation to Improve Safety and Performance; Civil – Monitoring the Overall Health of Structures that Undergo Constant Stress, Such as Bridges, Dams and Buildings; Medical – Determining the Three-dimensional Shape and Orientation of Medical Instruments in (Minimally) Invasive Surgical Procedures

1 Channel; >2,000 Sensors; Total Sensing Length 13 m; Spatial Resolution 6.35 mm; Acquisition Time <10 s Sensuron’s Static Strain fiber optic distributed strain measurement system is a low-cost, one-channel fiber optic sensing instrument for quasi-continuous strain monitoring. With over 2,000 sensing points on a single fiber, users are able to achieve spatially continuous real-time strain monitoring. The system replaces single-point strain sensing solutions such as strain gauges, to monitor multiple areas simultaneously, identifying strain fluctuation points quickly and accurately. Customers who replace single-point sensing solutions with a true distributed sensing platform enjoy significantly reduced installation time as well as labor cost savings. Static Strain is a key tool for non-destructive testing applications. The system can be customized to meet your project’s unique performance requirements. Contact the AMS Technologies fiber measurement experts to discuss how your application can benefit from this technology. For fiber optic distributed strain and temperature measurement systems with 4 or 8 channels, please refer to Sensuron’s Summit and RTS125+ series. Key Features: Multi-Sensing Reduces Risk Low Cost One Monitored Optical Fiber With Over 2,000 Equally Spaced Sensors Sensing Length: up to 13 m Software selectable Spatial Resolution: down to 6.35 mm Real-time, High-resolution Distributed Strain Measurements Acquisition Time: <10 s Sensors Immune to EMI/RFI and Radiation for Reliable Operation in Demanding Environments Low-latency Networking Capability Adjustable Sensor Standoff Length Applications: Non-destructive Testing; Automotive; Aerospace; Energy; Civil Engineering and Mining