Applications

Applications and Technical Information

AIRS Imaging Applications

American Infrared Solutions supplies cameras and integrated dewar-cooler assemblies (IDCA’s) for integration into virtually all advanced infrared imaging and spectral sensing applications.  Our clients are pushing the boundaries of imaging science, and they leverage our expertise to accomplish their goals.  Some of the applications content on this page will link you to a few of the manufacturers who use our products and services.

Many of the advanced infrared and hyperspectral imaging applications require infrared modules with extremely high thermal sensitivity and specific spectral bandpass filters.  Unfortunately, most major infrared camera manufacturers can’t justify building custom or prototype systems to satisfy these emerging applications.

There are several different infrared sensor technologies available and a broad range of cryogenic cooling options, all of which are available from different manufacturers.  Sorting through the different sensor options, cooler, filter, and lens combinations can be a daunting task.   Thermal camera sensitivity specifications are usually presented with a defined scene temperature and low F number lens, and the actual performance of the system can vary.   If your application requires longer lenses, higher F numbers, or has colder scene temperatures than the advertised NETD specification, you may be disappointed in system performance. We can help you navigate these challenges, and since we are sensor and cooler agnostic, we can provide objective guidance.

If you have questions about which cooled sensor is best for your application, cooler and lens options to meet a SWAP specification,  or you need specific spectral response data on any of our systems, please give us a call.  For ITAR reasons we only display a limited amount of technical data on our products, but we are happy to share additional information to approved US persons.

Our IDCA’s and cameras support imaging applications across the full infrared spectrum to include:

Multispectral Imaging

Hyperspectral Imaging

SWIR Short Wave Infrared Imaging

E SWIR Extended SWIR Imaging

Mid-Wave Imaging

Long-Wave Imaging

Broadband infrared Imaging

Our sensor offerings include:

InSb

MCT

HOT MCT

SLS

SWIR APPLICATIONS

SWIR imaging is the fastest growing segment in the infrared spectrum.  A steady stream of new and meaningful applications for SWIR cameras in environmental, medical and defense are driving this growth.   AIRS supplies special camera modules to OEM’s who deliver solutions for these emerging markets.

Hyperspectral cameras for crop health

Hyperspectral cameras for mineral detection

Hyperspectral mapping

Gas and aerosol cloud analysis

Medical Imaging

Our extended SWIR systems with 0.9 to 2.5µm wavelength sensitivity provide the ability to see laser spots up to 2.5µm.  This is beyond the capabilities of InGaAs based SWIR cameras that drop off at 1.7µm. Extended SWIR provides improved visibility through fog, haze, and glass.

Telops manufactures multispectral camera systems for the full range of infrared applications, including imaging of combustion reactions, mineral imaging, and optical gas imaging.

https://www.telops.com/products/multispectral-cameras

Headwall Photonics manufactures and supports high-performance hyperspectral camera systems.  Their products include wavelength performance out to eSWIR at 2.5µm.

https://www.headwallphotonics.com/hyperspectral-sensors

Corning’s Advanced Optics Group offers a full range of hyperspectral and remote sensing solutions for science and defense.

https://www.corning.com/cala/en/products/advanced-optics/product-materials/aerospace-defense/spectral-sensing.html

Space, Defense and Security Applications we support:

Thermal weapon sights

Wide area surveillance

Drone based Search and Rescue systems

IBDSS Integrated base defense security systems

Unmanned Aerial Vehicle long range gimbal camera systems

Long Range Thermal Security Systems

Satellite infrared imaging systems

MTI Moving target indicator imaging modules

Target signature applications

Counter Drone Detection

Critical Infrastructure Protection systems

Maritime Situational Awareness systems

Port Security systems

Airport Perimeter Security Infrared systems

Airborne IED detection systems

Commander thermal sights

Laser pointer imaging (SeeSpot imaging)

Nightglow imaging

SWIR Camouflage detection

Chemical Imaging and sensing in FTIR systems

Scientific and Commercial Applications

FTIR Fourier Transfer Infrared sensing

Metrology

Chemical Imaging

Medical imaging applications

Optical Gas Imaging Systems (OGI)

Scientific research

Infrared Microscopy systems

High Speed infrared systems

Here’s a link to a well-crafted article by Dr. Austin Richards on spectral selection.

https://www.photonics.com/Articles/Infrared_Spectral_Selection_It_Begins_with_the/a25132

Useful Hyperspectral Imaging and Information Links:

Here’s a link to the USGS spectral library:

https://crustal.usgs.gov/speclab/QueryAll07a.php

https://www.usgs.gov/labs/spec-lab/capabilities/spectral-library

Here’s a link to an IEEE article on the Comparison of Mid Wave Infrared (MWIR) and Long Wave Infrared (LWIR) Imagery for Precision Agriculture Applications

https://ieeexplore.ieee.org/document/8742183

More on precision agriculture and remote sensing open articles are available through MDPI, a peer-reviewed open access journal about the science and application of remote sensing technology.

https://www.mdpi.com/journal/remotesensing

More information related to infrared imaging

WorldWideScience.org is a global science gateway comprised of national and international scientific databases and portals.

https://worldwidescience.org/topicpages/m/mid-wave+infrared+mwir.html

Cooled vs. Uncooled infrared cameras

Photon counting vs. resistive element sensors

For those who are new to evaluating infrared cameras, the key performance attributes differ somewhat from the visible spectrum.

For visible light cameras, we rarely give much thought to the sensitivity of the camera’s sensor, or to the pixel density.  Prior to digital imaging, film ISO (sensitivity) was a primary consideration and to a lesser extent film grain.  For performance infrared cameras, thermal sensitivity, or the NETD (noise equivalent temperature difference) and pixel density (fill factor) are two of the differentiators between uncooled microbolometer sensors and photon counting cooled sensors.

Thermal sensitivity is typically measured and presented in NETD.  A cryogenically cooled infrared camera can typically resolve a 25mk temperature difference, where a good quality uncooled microbolometer camera will usually resolve about a 40mk delta.  The visible difference in these systems appear as a much cleaner and sharper image in the cooled (photon counting) cameras as opposed to the microbolometer cameras.

Another benefit of the high sensitivity of cooled sensors is that this allows for powerful compact zoom optics.  Uncooled sensors suffer with high F number lenses and are rarely coupled with zoom lenses.  In the most demanding remote sensing applications the lens sizes will make an uncooled sensor impractical.

Uncooled microbolometer sensors are well suited to low cost thermography, industrial inspection, and short-range security applications since they can run for years without maintenance.  But they don’t offer the performance required for demanding remote sensing, scientific and hyperspectral applications.

Additionally, uncooled microbolometer sensors have very slow integration times.  This can be problematic for many airborne and scientific applications where smearing combined with noise can reduce the probability of target detection.  Most commercially available microbolometers offer a 10ms integration time, compared to high performance cooled sensors that can operate at integration speeds up to 50 µs.

Cryogenically cooled sensors operate at different temperatures depending on the sensor technology and application.   InSb sensors are typically cooled to 77K, but may be cooled to 70k to reduce dark current and to further reduce noise.   High Operating Temperature sensors including MCT or SLS might run at 120K or 130k.

Link to additional reading at semantic scholar.org

https://www.semanticscholar.org/paper/Digital-Pixel-Focal-Plane-Array-Technology-Schultz-Kelly/1a1f024cb14e9dec036248d638953175c697d4c1/figure/2

 

Invention of the microbolometer is credited the American astronomer Samuel Pierpont Langley in 1878.

https://en.wikipedia.org/wiki/Bolometer#:~:text=A%20bolometer%20is%20a%20device,American%20astronomer%20Samuel%20Pierpont%20Langley.

This video from Sunpower provides an excellent Stirling Cryogenic Micro-Cooler overview

Cryogenic linear and rotary micro-coolers have improved over the years in both performance and  size, and they are available from several manufacturers.  We can integrate, service and support most micro-coolers, including those from FLIR, Thales, AIM, Ricor,

Here’s a  Thales cooler overview.

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