Block Engineering joins Leidos for active infrared spectroscopy chemical detection

Feb. 15, 2016
WRIGHT-PATTERSON AFB, Ohio, 15 Feb. 2016. Sensors experts at Block Engineering, Inc. in Marlborough, Mass., are developing a lightweight battery-operated chemical-detection system that detects explosives, chemical weapons, poisonous chemicals, and narcotics using active infrared spectroscopy.

WRIGHT-PATTERSON AFB, Ohio, 15 Feb. 2016. Sensors experts at Block Engineering, Inc. in Marlborough, Mass., are developing a lightweight battery-operated chemical-detection system that detects explosives, chemical weapons, poisonous chemicals, and narcotics using active infrared spectroscopy.

Officials of the U.S. Air Force Research Laboratory at Wright-Patterson Air Force Base, Ohio, announced a $9.4 million contract to Block Engineering on Wednesday Friday for the Standoff Illuminator for Measuring Absorbance and Reflectance Infrared Light Signatures (SILMARILS) project.

Block Engineering joins Leidos Inc. in Reston, Va., on the SILMARILS program. Leidos received a $17.9 million contract to develop the system on 2 Feb. 2016.

The Air Force Research Lab is awarding the contracts to Block Engineering and Leidos on behalf of the U.S. Intelligence Advanced Research Projects Agency (IARPA) in Washington. IARPA is the research arm of the Office of the Director of National Intelligence.

Related: Leidos eyes active infrared spectroscopy chemical detection for weapons, poisons, narcotics

The contract calls for Block Engineering experts to develop a portable system for real-time standoff detection and identification of trace chemical residues on surfaces using active infrared spectroscopy at a 30-meter range.

Block Engineering specializes in midwave infrared detection instruments, and offers Quantum Cascade Laser (QCL) spectrometers and midwave infrared laser sources with wide tunable range and fast chemical analysis.

Standoff chemical detection is a ubiquitous need across the intelligence community for applications ranging from forensic crime scene analysis to border and facility protection to stockpile and production monitoring, IARPA officials say.

Current systems, however, do not provide the sensitivity, specificity, and low false-alarm rates necessary to detect trace chemicals of interest in a cluttered, real-world environment.

Related: Bruker Daltonics' RAID-XP chemical agent/radiation detector installed in armored vehicles for Czech Army

Goals of the SILMARILS program include high chemical sensitivity and specificity across a broad range of target classes; effective operation amid gas phase and surface-adsorbed clutter, varying substrates, temperature, humidity, and indoor and outdoor background light; an eye-safe system with a visually unobservable illumination beam; portable size and power draw for limited-duration battery operation; and a rapid scan rate.

The key overarching objective of the SILMARILS program is not just to develop a spectrometer that can produce high-resolution infrared spectra in the laboratory, but also to develop a system that can identify target chemicals in the field with real-world clutter and background.

Block Engineering is joining Leidos in developing physical spectrometer hardware and detection and discrimination algorithms that detect nitro-based compounds such as TNT and RDX, acetone peroxide, and home-made explosives such as fertilizer bombs; chemical weapons such as sarin or tabun, as well as toxic chemicals that may be intentionally or unintentionally released such as hydrogen cyanide or ammonia gas; and illicit drugs such as cocaine, heroin, or methamphetamine, or legal but abused drugs such as Vicodin or hydrocodone.

IARPA officials also would like the instrument to detect compounds associated with the manufacture and deployment of biological agents and nuclear materials.

Related: Adaptive nuclear, biological, and chemical detection in demand

Block Engineering and Leidos experts will investigate coupling broadband coherent sources with interferometric spectroscopy in wavebands like long wave infrared (LWIR), mid-wave infrared (MWIR), and short-wave infrared (SWIR).

The job involves creating tailored algorithms and specific background and clutter filter approaches; understanding how surface and particle effects influence spectral signatures; designing an optical train from existing and purpose-developed component technology; and developing a prototype for field testing.

On this contract Block Engineering will do the work in Marlborough, Mass., and should be finished by October 2020. Additional contractors yet may be selected for the SILMARILS project.

For more information contact Block Engineering online at www.blockeng.com, Leidos at www.leidos.com, IARPA at www.iarpa.gov, or the Air Force Research Laboratory at www.wpafb.af.mil/AFRL.

About the Author

John Keller | Editor

John Keller is editor-in-chief of Military & Aerospace Electronics magazine, which provides extensive coverage and analysis of enabling electronic and optoelectronic technologies in military, space, and commercial aviation applications. A member of the Military & Aerospace Electronics staff since the magazine's founding in 1989, Mr. Keller took over as chief editor in 1995.

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