Electro-optical MASINT: Difference between revisions

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In other words, MASINT may give warning before characteristics visible to IMINT are clear, or it may help validate or understand the pictures taken by IMINT.
In other words, MASINT may give warning before characteristics visible to IMINT are clear, or it may help validate or understand the pictures taken by IMINT.


MASINT techniques are not limited to the United States, but the U.S. distinguishes MASINT sensors from others more than do other nations. According to the [[United States Department of Defense]], MASINT is technically derived intelligence (excluding traditional imagery [[IMINT]] and signals intelligence [[SIGINT]]) that – when collected, processed, and analyzed by dedicated MASINT systems – results in intelligence that detects, tracks, identifies, or describes the signatures (distinctive characteristics) of fixed or dynamic target sources.  MASINT was recognized as a formal intelligence discipline in 1986. <ref name =IOSS-2>{{cite web
MASINT techniques are not limited to the United States, but the U.S. distinguishes MASINT sensors from others more than do other nations. According to the [[United States Department of Defense]], MASINT is technically derived intelligence (excluding traditional imagery [[IMINT]] and signals intelligence [[SIGINT]]) that – when collected, processed, and analyzed by dedicated MASINT systems – results in intelligence that detects, tracks, identifies, or describes the signatures (distinctive characteristics) of fixed or dynamic target sources.  MASINT was recognized as a formal intelligence discipline in 1986.<ref name =IOSS-2>{{cite web
   | last = Interagency OPSEC Support Staff (IOSS)
   | last = Interagency OPSEC Support Staff (IOSS)
   | title = Operations Security Intelligence Threat Handbook: Section 2, Intelligence Collection Activities and Disciplines  
   | title = Operations Security Intelligence Threat Handbook: Section 2, Intelligence Collection Activities and Disciplines  
   | date = May 1996
   | date = May 1996
   | url = http://www.fas.org/irp/nsa/ioss/threat96/part03.htm
   | url = http://www.fas.org/irp/nsa/ioss/threat96/part03.htm
  }}</ref>. Another way to describe MASINT is "a "non-literal" discipline. It feeds on a target's unintended emissive byproducts, the "trails" of thermal energy, chemical or radio frequency emission that an object leaves in its wake. These trails form distinct signatures, which can be exploited as reliable discriminators to characterize specific events or disclose hidden targets"<ref name=Lum>{{cite journal
  }}</ref> Another way to describe MASINT is "a "non-literal" discipline. It feeds on a target's unintended emissive byproducts, the "trails" of thermal energy, chemical or radio frequency emission that an object leaves in its wake. These trails form distinct signatures, which can be exploited as reliable discriminators to characterize specific events or disclose hidden targets"<ref name=Lum>{{cite journal
   | last = Lum
   | last = Lum
   | first = Zachary
   | first = Zachary
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   | publisher = Air Force Institute of Technology  | url = http://www.afit.edu/cmsr/}}</ref>
   | publisher = Air Force Institute of Technology  | url = http://www.afit.edu/cmsr/}}</ref>


MASINT collection technologies in this area use radar, lasers, staring arrays in the infrared and visual, to point sensors at the information of interest. As opposed to IMINT, MASINT electro-optical sensors do not create pictures. Instead, they would indicate the coordinates, intensity, and spectral characteristics of a light source, such as a [[rocket]] engine, or a missile [[reentry vehicle]]. Electro-optical MASINT involves obtaining information from emitted or reflected energy, across the wavelengths of [[infrared]], [[visible]], and [[ultraviolet]] [[light]]. Electro-optical techniques  include measurement of the radiant intensities, dynamic motion, and the materials composition of a target. These measurements put the target in spectral and spatial contexts. Sensors used in electro-optical MASINT include radiometers, spectrometers, non-literal imaging systems, lasers, or laser radar (LIDAR)<ref name=FM2-0Ch9>{{cite web
MASINT collection technologies in this area use radar, lasers, staring arrays in the infrared and visual, to point sensors at the information of interest. As opposed to IMINT, MASINT electro-optical sensors do not create pictures. Instead, they would indicate the coordinates, intensity, and spectral characteristics of a light source, such as a [[rocket]] engine, or a missile [[reentry vehicle]]. Electro-optical MASINT involves obtaining information from emitted or reflected energy, across the wavelengths of [[infrared]], [[visible]], and [[ultraviolet]] [[light]]. Electro-optical techniques  include measurement of the radiant intensities, dynamic motion, and the materials composition of a target. These measurements put the target in spectral and spatial contexts. Sensors used in electro-optical MASINT include radiometers, spectrometers, non-literal imaging systems, lasers, or laser radar (LIDAR).<ref name=FM2-0Ch9>{{cite web
   | last = US Army
   | last = US Army
   | title = Chapter 9: Measurement and Signals Intelligence
   | title = Chapter 9: Measurement and Signals Intelligence
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   | publisher = Department of the Army
   | publisher = Department of the Army
   | date = May 2004
   | date = May 2004
   | url =  https://atiam.train.army.mil/soldierPortal/atia/adlsc/view/public/10536-1/FM/2-0/chap9.htm3}}</ref>.
   | url =  https://atiam.train.army.mil/soldierPortal/atia/adlsc/view/public/10536-1/FM/2-0/chap9.htm3}}</ref>


Observation of foreign missile tests, for example, make extensive use of MASINT along with other disciplines. For example, electro-optical and radar tracking establish trajectory, speed, and other flight characteristics that can be used to validate the [[TELINT]] telemetry intelligence being received by SIGINT sensors. Electro-optical sensors, which guide radars, operate on  aircraft, ground stations, and ships.  
Observation of foreign missile tests, for example, make extensive use of MASINT along with other disciplines. For example, electro-optical and radar tracking establish trajectory, speed, and other flight characteristics that can be used to validate the [[TELINT]] telemetry intelligence being received by SIGINT sensors. Electro-optical sensors, which guide radars, operate on  aircraft, ground stations, and ships.  
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==Airborne Electro-Optical Missile Tracking MASINT==
==Airborne Electro-Optical Missile Tracking MASINT==


U.S. [[RC-135]]S COBRA BALL aircraft have MASINT sensors that are "...two linked electro-optical sensors -- the Real Time Optics System (RTOS) and the Large Aperture Tracker System (LATS). RTOS consists of an array of staring sensors encompassing a wide field of regard for target acquisition. LATS serves as an adjunct tracker. Due to its large aperture, it has significantly greater sensitivity and resolving power than the RTOS, but is otherwise similar <ref name=COBRABALL>{{Citation
U.S. [[RC-135]]S COBRA BALL aircraft have MASINT sensors that are "...two linked electro-optical sensors -- the Real Time Optics System (RTOS) and the Large Aperture Tracker System (LATS). RTOS consists of an array of staring sensors encompassing a wide field of regard for target acquisition. LATS serves as an adjunct tracker. Due to its large aperture, it has significantly greater sensitivity and resolving power than the RTOS, but is otherwise similar.<ref name=COBRABALL>{{Citation
   | last = Pike
   | last = Pike
   | first = John
   | first = John
   | title = COBRA BALL
   | title = COBRA BALL
   | url = http://www.globalsecurity.org/intell/systems/cobra_ball.htm}}</ref>.
   | url = http://www.globalsecurity.org/intell/systems/cobra_ball.htm}}</ref>


<!--[[Image:RC-135 Cobra Ball aircraft parked at Offutt.jpg|thumb|Two Cobra Ball aircraft on the flightline at [[Offutt Air Force Base]], Nebraska.]]-->  
<!--[[Image:RC-135 Cobra Ball aircraft parked at Offutt.jpg|thumb|Two Cobra Ball aircraft on the flightline at [[Offutt Air Force Base]], Nebraska.]]-->  
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Both electro-optical and radar sensors have been coupled with acoustic sensors in modern counter-artillery systems. Electro-optical sensors are directional and precise, so need to be cued by acoustic or other omnidirectional sensors. The original [[Canada|Canadian]] sensors, in the [[First World War]], used electro-optical flash as well as geophysical sound sensors.
Both electro-optical and radar sensors have been coupled with acoustic sensors in modern counter-artillery systems. Electro-optical sensors are directional and precise, so need to be cued by acoustic or other omnidirectional sensors. The original [[Canada|Canadian]] sensors, in the [[First World War]], used electro-optical flash as well as geophysical sound sensors.
===Purple Hawk===
===Purple Hawk===
Complementing [[Radar MASINT#Counterartillery Radar |counter-mortar radar]] is the [[Israel|Israeli]] Purple Hawk mast-mounted electro-optical sensor, which detects mortars and provides perimeter security. The device, remotely operated via fiber optics or microwave, is intended to have a laser designator<ref>{{Citation
Complementing [[Radar MASINT#Counterartillery Radar |counter-mortar radar]] is the [[Israel|Israeli]] Purple Hawk mast-mounted electro-optical sensor, which detects mortars and provides perimeter security. The device, remotely operated via fiber optics or microwave, is intended to have a laser designator.<ref>{{Citation
   | author = Daniel W. Caldwell
   | author = Daniel W. Caldwell
   | title = Radar planning, preparation and employment of 3-tiered coverage: LCMR, Q-36 and Q-37
   | title = Radar planning, preparation and employment of 3-tiered coverage: LCMR, Q-36 and Q-37
   | url = http://www.thefreelibrary.com/Radar+planning,+preparation+and+employment+of+3-tiered+coverage:...-a0123856463}}</ref>.
   | url = http://www.thefreelibrary.com/Radar+planning,+preparation+and+employment+of+3-tiered+coverage:...-a0123856463}}</ref>


===Rocket Launch Spotter===
===Rocket Launch Spotter===
A newer U.S. system couples an electro-optical and an acoustic system to produce the Rocket Artillery Launch Spotter (RLS)<ref>{{cite web
A newer U.S. system couples an electro-optical and an acoustic system to produce the Rocket Artillery Launch Spotter (RLS).<ref>{{cite web
  | url = http://www.nrl.navy.mil/Review06/images/06Optical(Mabe).pdf
  | url = http://www.nrl.navy.mil/Review06/images/06Optical(Mabe).pdf
  | title = Rocket Artillery Launch Spotter (RLS)
  | title = Rocket Artillery Launch Spotter (RLS)
  | author = Mabe, R.M. ''et al.''
  | author = Mabe, R.M. ''et al.''
}}</ref>. RLS combines components from two existing systems, the Tactical Aircraft Directed Infra-Red Countermeasures (TADIRCM) and the UTAMS . The two-color infrared sensors were originally designed to detect surface-to-air missiles for TADIRCM. Other TADIRCM components also have been adapted to RLS, including the computer processors, inertial navigation units (INU), and detection and tracking algorithms.
}}</ref> RLS combines components from two existing systems, the Tactical Aircraft Directed Infra-Red Countermeasures (TADIRCM) and the UTAMS . The two-color infrared sensors were originally designed to detect surface-to-air missiles for TADIRCM. Other TADIRCM components also have been adapted to RLS, including the computer processors, inertial navigation units (INU), and detection and tracking algorithms.


It is an excellent example of [[MASINT#Cueing |automatic cueing]] of one sensor by another. Depending on the application, the [[sensitive]] but less [[selective]] sensor is either acoustic or nonimaging electro-optical. The selective sensor is forward-looking infrared (FLIR).
It is an excellent example of [[MASINT#Cueing |automatic cueing]] of one sensor by another. Depending on the application, the [[sensitive]] but less [[selective]] sensor is either acoustic or nonimaging electro-optical. The selective sensor is forward-looking infrared (FLIR).
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There are several distinctive characteristics, in the range of visible light, from nuclear explosions. One of these is a characteristic "dual flash" measured by a [[bhangmeter]]. This went into routine use on the [[Vela (satellite) |advanced Vela]] nuclear detection satellites, first launched in 1967. The earlier Velas only detected X-rays, gamma rays, and neutrons.
There are several distinctive characteristics, in the range of visible light, from nuclear explosions. One of these is a characteristic "dual flash" measured by a [[bhangmeter]]. This went into routine use on the [[Vela (satellite) |advanced Vela]] nuclear detection satellites, first launched in 1967. The earlier Velas only detected X-rays, gamma rays, and neutrons.


The bhangmeter technique was used earlier, in 1961, aboard a modified US KC-135B aircraft monitoring the preannounced Soviet test of [[Tsar Bomba]], the largest nuclear explosion ever detonated<ref>{{cite web
The bhangmeter technique was used earlier, in 1961, aboard a modified US KC-135B aircraft monitoring the preannounced Soviet test of [[Tsar Bomba]], the largest nuclear explosion ever detonated.<ref>{{cite web
| url = http://nuclearweaponarchive.org/Russia/TsarBomba.html
| url = http://nuclearweaponarchive.org/Russia/TsarBomba.html
| title = Big Ivan, The Tsar Bomba (“King of Bombs”): The World's Largest Nuclear Weapon
| title = Big Ivan, The Tsar Bomba (“King of Bombs”): The World's Largest Nuclear Weapon
| last = Sublette
| last = Sublette
| first = Carey  
| first = Carey  
}}</ref>. The US test monitoring, which carried both broadband electromagnetic and optical sensors including a bhangmeter, was named SPEEDLIGHT.
}}</ref>  The US test monitoring, which carried both broadband electromagnetic and optical sensors including a bhangmeter, was named SPEEDLIGHT.


As part of Operation BURNING LIGHT, one MASINT system photographed the nuclear clouds of French atmospheric nuclear tests to measure their density and opacity  
As part of Operation BURNING LIGHT, one MASINT system photographed the nuclear clouds of French atmospheric nuclear tests to measure their density and opacity.<ref name=SAC1971>{{Citation
<ref name=SAC1971>{{Citation
   | last = History Division, Strategic Air Command
   | last = History Division, Strategic Air Command
   | title = SAC Reconnaissance History, January 1968-June 1971
   | title = SAC Reconnaissance History, January 1968-June 1971
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   | last = Office of the Historian, Strategic Air Command
   | last = Office of the Historian, Strategic Air Command
   | title = History of SAC Reconnaissance Operations, FY 1974
   | title = History of SAC Reconnaissance Operations, FY 1974
   | url = http://www.gwu.edu/~nsarchiv/NSAEBB/NSAEBB184/FR29.pdf}}</ref>. This operation is borderline with [[Nuclear MASINT]].
   | url = http://www.gwu.edu/~nsarchiv/NSAEBB/NSAEBB184/FR29.pdf}}</ref>  This operation is borderline with [[Nuclear MASINT]].


Bhangmeters on Advanced Vela satellites detected the what is variously called the [[Vela Incident]] or South Atlantic Incident, on 22 September 1979. Different reports have claimed that it was, or was not, a nuclear test, and, if it was, probably involved [[South Africa]] and possibly [[Israel]]. [[France]] and [[Taiwan]] have also been suggested. Only one bhangmeter detected the characteristic double-flash, although US Navy [[hydrophone]]s suggest a low-yield blast. Other sensors were negative or equivocal, and no definitive explanation has yet been made public.
Bhangmeters on Advanced Vela satellites detected the what is variously called the [[Vela Incident]] or South Atlantic Incident, on 22 September 1979. Different reports have claimed that it was, or was not, a nuclear test, and, if it was, probably involved [[South Africa]] and possibly [[Israel]]. [[France]] and [[Taiwan]] have also been suggested. Only one bhangmeter detected the characteristic double-flash, although US Navy [[hydrophone]]s suggest a low-yield blast. Other sensors were negative or equivocal, and no definitive explanation has yet been made public.
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===Hyperspectral MASINT===
===Hyperspectral MASINT===


Hyperspectral MASINT involves the synthesis of images as seen by visible and near infrared light. US MASINT in this area is coordinated by the  Hyperspectral MASINT Support to Military Operations (HYMSMO) project.  This MASINT technology differs from IMINT in that it attempts to understand the physical characteristics of what is seen, not just what it looks like. <ref name=Gatz>{{cite conference
Hyperspectral MASINT involves the synthesis of images as seen by visible and near infrared light. US MASINT in this area is coordinated by the  Hyperspectral MASINT Support to Military Operations (HYMSMO) project.  This MASINT technology differs from IMINT in that it attempts to understand the physical characteristics of what is seen, not just what it looks like.<ref name=Gatz>{{cite conference
   | first = Nahum
   | first = Nahum
   | last = Gatz
   | last = Gatz
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   | location = Wright-Patterson Air Force Base, Dayton, Ohio
   | location = Wright-Patterson Air Force Base, Dayton, Ohio
   | url = http://www.afit.edu/cmsr/WPMDC/lectures.cfm
   | url = http://www.afit.edu/cmsr/WPMDC/lectures.cfm
}}</ref>.
}}</ref>


Hyperspectral imaging typically needs multiple [[Measurement and Signature Intelligence#Basic interaction of energy sources with targets |imaging modalities]]d, such as whiskbroom, pushbroom, tomographic, intelligent filters, and time series.  
Hyperspectral imaging typically needs multiple [[Measurement and Signature Intelligence#Basic interaction of energy sources with targets |imaging modalities]]d, such as whiskbroom, pushbroom, tomographic, intelligent filters, and time series.  
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====Design Issues====
====Design Issues====


Some of the major issues in visible and infrared hyperspectral processing include atmospheric correction, for the visible and short wave infrared<ref>{{cite conference
Some of the major issues in visible and infrared hyperspectral processing include atmospheric correction, for the visible and short wave infrared.<ref>{{cite conference
   | first = Alexander
   | first = Alexander
   | last = Goetz
   | last = Goetz
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   | location = Wright-Patterson Air Force Base, Dayton, Ohio
   | location = Wright-Patterson Air Force Base, Dayton, Ohio
   | url = http://www.afit.edu/cmsr/WPMDC/lectures.cfm
   | url = http://www.afit.edu/cmsr/WPMDC/lectures.cfm
  }}</ref>. (0.4 - 2.5 micrometer) dictate sensor radiances need to be converted to surface reflectances. This dictates a need for measuring, and connecting for:
  }}</ref> (0.4 - 2.5 micrometer) dictate sensor radiances need to be converted to surface reflectances. This dictates a need for measuring, and connecting for:
:*atmospheric absorption and scattering  
:*atmospheric absorption and scattering  
:*aerosol optical depth,  
:*aerosol optical depth,  
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:*blurring due to the adjacency effect and retrieval of reflectance in shadows.  
:*blurring due to the adjacency effect and retrieval of reflectance in shadows.  


Hyperspectral, as opposed to multispectral, processing gives the potential of improved spectral signature measurement from airborne and spaceborne sensor platforms. Sensors on these platforms, however, must compensate for atmospheric effects. Such compensation is easiest with high contrast targets sensed through well-behaved atmosphere with even, reliable illumination, the real world will not always be so cooperative.  For more complicated situations, one can not simply compensate for the atmospheric and illumination conditions by taking them out. The Invariant Algorithm for target detection was designed to find many possible combinations of these conditions for the image
Hyperspectral, as opposed to multispectral, processing gives the potential of improved spectral signature measurement from airborne and spaceborne sensor platforms. Sensors on these platforms, however, must compensate for atmospheric effects. Such compensation is easiest with high contrast targets sensed through well-behaved atmosphere with even, reliable illumination, the real world will not always be so cooperative.  For more complicated situations, one can not simply compensate for the atmospheric and illumination conditions by taking them out. The Invariant Algorithm for target detection was designed to find many possible combinations of these conditions for the image.<ref>{{cite web
<ref>{{cite web
  | url = http://www.cis.rit.edu/education/ugrad/SeniorResearch/Gold-2005-bs.pdf
  | url = http://www.cis.rit.edu/education/ugrad/SeniorResearch/Gold-2005-bs.pdf
  | title = Performance Analysis of the Invariant Algorithm for Target Detection in Hyperspectral Imagery
  | title = Performance Analysis of the Invariant Algorithm for Target Detection in Hyperspectral Imagery
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Multiple organizations, with several reference sensors, are collecting libraries of hyperspectral signatures, starting with undisturbed areas such as deserts, forests, cities, etc.  
Multiple organizations, with several reference sensors, are collecting libraries of hyperspectral signatures, starting with undisturbed areas such as deserts, forests, cities, etc.  


:*'''AHI''', the Airborne Hyperspectral Imager <ref>{{cite web
:*'''AHI''', the Airborne Hyperspectral Imager,<ref>{{cite web
  | url = http://www.higp.hawaii.edu/ahi/paper.html
  | url = http://www.higp.hawaii.edu/ahi/paper.html
  | title = An Airborne Hyperspectral Imager for Hyperspectral Mine Detection
  | title = An Airborne Hyperspectral Imager for Hyperspectral Mine Detection
  | author = Lucey, P.G. ''et al.''
  | author = Lucey, P.G. ''et al.''
}}</ref>, a hyperspectral sensor operating in the long-wave infrared spectrum for DARPA’s Hyperspectral Mine Detection (HMD) program. AHI is a helicopter-borne LWIR hyperspectral imager with real time on-board radiometric calibration and mine detection.
}}</ref> a hyperspectral sensor operating in the long-wave infrared spectrum for DARPA’s Hyperspectral Mine Detection (HMD) program. AHI is a helicopter-borne LWIR hyperspectral imager with real time on-board radiometric calibration and mine detection.
:*'''COMPASS''', the Compact Airborne Spectral Sensor, a day-only sensor for 384 bands between from 400 to 2350 nm, being developed by the Army Night Vision and Electronic Sensors Directorate (NVESD)<ref name=OSD-UASR-2005 />.
:*'''COMPASS''', the Compact Airborne Spectral Sensor, a day-only sensor for 384 bands between from 400 to 2350 nm, being developed by the Army Night Vision and Electronic Sensors Directorate (NVESD)<ref name=OSD-UASR-2005 />.
:*'''HyLite''', Army day/night Hyperspectral Longwave Imager for the Tactical Environment <ref name=OSD-UASR-2005>OSD-UASR-2005 />
:*'''HyLite''', Army day/night Hyperspectral Longwave Imager for the Tactical Environment <ref name=OSD-UASR-2005>OSD-UASR-2005 />
:*'''HYDICE''', the HYperspectral Digital Imagery Collection Experiment <ref>{{cite web
:*'''HYDICE''', the HYperspectral Digital Imagery Collection Experiment<ref>{{cite web
  | url = http://hdl.handle.net/1850/3210
  | url = http://hdl.handle.net/1850/3210
  | title = Analysis of HYDICE noise characteristics and their impact on subpixel object detection
  | title = Analysis of HYDICE noise characteristics and their impact on subpixel object detection
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  | pages = 112-123
  | pages = 112-123
}}</ref> built by Hughes Danbury Optical Systems and flight tested on a Convair 580.
}}</ref> built by Hughes Danbury Optical Systems and flight tested on a Convair 580.
:*'''SPIRITT''', the Air Force's Spectral Infrared Remote Imaging Transition Testbed <ref>{{cite web
:*'''SPIRITT''', the Air Force's Spectral Infrared Remote Imaging Transition Testbed,<ref>{{cite web
  | url = http://www.fbodaily.com/cbd/archive/2000/12(December)/26-Dec-2000/asol005.htm
  | url = http://www.fbodaily.com/cbd/archive/2000/12(December)/26-Dec-2000/asol005.htm
  | date = December 21, 2000
  | date = December 21, 2000
  | title = Spectral Infrared Remote Imaging Transition Testbed  
  | title = Spectral Infrared Remote Imaging Transition Testbed  
  | journal = Commerce Business Daily
  | journal = Commerce Business Daily
}}</ref>, a day/night, long range reconnaissance imaging testbed composed of a hyperspectral sensor system with integrated high resolution imaging
}}</ref> a day/night, long range reconnaissance imaging testbed composed of a hyperspectral sensor system with integrated high resolution imaging


====Signature Libraries====
====Signature Libraries====
Under the HYMSMO program, there have been a number of studies to build hyperspectral imaging signatures in various kinds of terrain<ref>{{cite paper
Under the HYMSMO program, there have been a number of studies to build hyperspectral imaging signatures in various kinds of terrain.<ref>{{cite paper
   | author = Bergman, Steven M.
   | author = Bergman, Steven M.
   | title = The Utility of Hyperspectral Data in Detecting and Discriminating Actual and Decoy Target Vehicles
   | title = The Utility of Hyperspectral Data in Detecting and Discriminating Actual and Decoy Target Vehicles
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   | date = December 1996
   | date = December 1996
   | url =  http://handle.dtic.mil/100.2/ADA327453
   | url =  http://handle.dtic.mil/100.2/ADA327453
}}</ref>. Signatures of undisturbed forest, desert, island and urban ares are being recorded with sensors including COMPASS, HYDICE and SPIRITT.  Many of these areas are also being analyzed with complementary sensors including  [[Radar MASINT#SAR Interferometry |synthetic aperture radar (SAR)]].
}}</ref> Signatures of undisturbed forest, desert, island and urban ares are being recorded with sensors including COMPASS, HYDICE and SPIRITT.  Many of these areas are also being analyzed with complementary sensors including  [[Radar MASINT#SAR Interferometry |synthetic aperture radar (SAR)]].


{| class="wikitable"
{| class="wikitable"
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|}
|}


A representative test range, with and without buried metal, is the [[Radar MASINT#Steel Crater Test Area |Steel Crater Test Area]] at the Yuma Proving Grounds<ref>{{cite web
A representative test range, with and without buried metal, is the [[Radar MASINT#Steel Crater Test Area |Steel Crater Test Area]] at the Yuma Proving Grounds.<ref>{{cite web
  | url = https://www.denix.osd.mil/denix/Public/News/OSD/UXO/Conferences/Forum/Deluca.pdf
  | url = https://www.denix.osd.mil/denix/Public/News/OSD/UXO/Conferences/Forum/Deluca.pdf
  | title = Unexploded Ordnance Detection Experiments Using Ultra-Wideband Synthetic Aperture Radar
  | title = Unexploded Ordnance Detection Experiments Using Ultra-Wideband Synthetic Aperture Radar
  | author = Clyde C. DeLuca
  | author = Clyde C. DeLuca
  | coauthors = Vincent Marinelli , Marc Ressler, and Tuan Ton
  | coauthors = Vincent Marinelli , Marc Ressler, and Tuan Ton
}}</ref>. This was developed for radar measurements, but is comparable to other signature development areas for other sensors and may be used for hyperspectral sensing of buried objects.
}}</ref> This was developed for radar measurements, but is comparable to other signature development areas for other sensors and may be used for hyperspectral sensing of buried objects.


====Applications====
====Applications====


In applications of intelligence interest, the Johns Hopkins University Applied Physics Laboratory (JHU/APL) has demonstrated that hyperspectral sensing allows discrimination of refined signatures, based on a large number of narrow frequency bands across a wide spectrum<ref name=Kolodner>{{cite web  
In applications of intelligence interest, the Johns Hopkins University Applied Physics Laboratory (JHU/APL) has demonstrated that hyperspectral sensing allows discrimination of refined signatures, based on a large number of narrow frequency bands across a wide spectrum.<ref name=Kolodner>{{cite web  
  | url = http://www.jhuapl.edu/nss/documents/fact_sheets/07-00963-1HEPv2.pdf  
  | url = http://www.jhuapl.edu/nss/documents/fact_sheets/07-00963-1HEPv2.pdf  
  | title = Hyperspectral Exploitation Program
  | title = Hyperspectral Exploitation Program
  | author = Kolodner, Marc A.  
  | author = Kolodner, Marc A.  
  | accessdate = 2007-12-01
  | accessdate = 2007-12-01
}}</ref>. These techniques can identify include military vehicle paints, characteristic of particular countries' signatures. They can differentiate camouflage from real vegetation. By detecting disturbances in earth, they can detect a wide variety of both excavation and buried materials. Roads and surfaces that have been lightly or heavily trafficked will produce different measurements than the reference signatures.
}}</ref> These techniques can identify include military vehicle paints, characteristic of particular countries' signatures. They can differentiate camouflage from real vegetation. By detecting disturbances in earth, they can detect a wide variety of both excavation and buried materials. Roads and surfaces that have been lightly or heavily trafficked will produce different measurements than the reference signatures.
   
   
It can detect specific types of foliage supporting drug-crop identification; disturbed soil supporting the identification of mass graves, minefields, caches, underground facilities or cut foliage; and variances in soil, foliage, and hydrologic features often supporting NBC contaminant detection. This was done previously with false-color infrared photographic film, but electronics are faster and more flexible. <ref name=Gatz />
It can detect specific types of foliage supporting drug-crop identification; disturbed soil supporting the identification of mass graves, minefields, caches, underground facilities or cut foliage; and variances in soil, foliage, and hydrologic features often supporting NBC contaminant detection. This was done previously with false-color infrared photographic film, but electronics are faster and more flexible. <ref name=Gatz />
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=====Mass Graves=====
=====Mass Graves=====


Peace operations and war crimes investigation may require the detection of often-clandestine mass graves. Clandestinity makes it difficult to get witness testimony, or use technologies that require direct access to the suspected grave site (e.g., ground penetrating radar). Hyperspectral imaging from aircraft or satellites can provide remotely sensed reflectance spectra to help detect such graves. Imaging of an experimental mass grave and a real-world mass grave show that hyperspectral remote imaging is a powerful method for finding mass graves in real time, or, in some cases, retrospectively<ref name=Kalacska>{{cite journal  
Peace operations and war crimes investigation may require the detection of often-clandestine mass graves. Clandestinity makes it difficult to get witness testimony, or use technologies that require direct access to the suspected grave site (e.g., ground penetrating radar). Hyperspectral imaging from aircraft or satellites can provide remotely sensed reflectance spectra to help detect such graves. Imaging of an experimental mass grave and a real-world mass grave show that hyperspectral remote imaging is a powerful method for finding mass graves in real time, or, in some cases, retrospectively.<ref name=Kalacska>{{cite journal  
  | url = http://ww2.csfs.ca/CSFS_Journal.aspx?ID=46&year=2006
  | url = http://ww2.csfs.ca/CSFS_Journal.aspx?ID=46&year=2006
  | title = Remote Sensing as a Tool for the Detection of Clandestine Mass Graves
  | title = Remote Sensing as a Tool for the Detection of Clandestine Mass Graves
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  | issue = 1
  | issue = 1
  | date = March 2006
  | date = March 2006
}}</ref>.
}}</ref>


=====Ground Order of Battle Target Detection=====  
=====Ground Order of Battle Target Detection=====  
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=====Biomass Estimation=====
=====Biomass Estimation=====
Knowing the fractions of vegetation and soil is of helps estimate the biomass. Biomass is not extremely important for military operations, but gives information for national-level economic and environmental intelligence. Detailed hyperspectral imagery  such as the leaf chemical content (nitrogen, proteins, lignin and water) can be relevant to counterdrug surveillance<ref name=Borel>{{citation
Knowing the fractions of vegetation and soil is of helps estimate the biomass. Biomass is not extremely important for military operations, but gives information for national-level economic and environmental intelligence. Detailed hyperspectral imagery  such as the leaf chemical content (nitrogen, proteins, lignin and water) can be relevant to counterdrug surveillance.<ref name=Borel>{{citation
   | first = Christoph C.
   | first = Christoph C.
   | last = Borel
   | last = Borel
Line 339: Line 337:
   | date = July 17, 2007
   | date = July 17, 2007
   | location = Wright-Patterson Air Force Base, Dayton, Ohio
   | location = Wright-Patterson Air Force Base, Dayton, Ohio
   | url = http://www.afit.edu/cmsr/WPMDC/lectures.cfm  }}</ref>.
   | url = http://www.afit.edu/cmsr/WPMDC/lectures.cfm  }}</ref>


==Space-based Staring Infrared Sensors==
==Space-based Staring Infrared Sensors==


The US, in 1970, launched the first of a series of space-based [[staring array]] sensors that detected and located infrared heat signatures, typically from rocket motors but also from other intense heat sources. Such signatures, which are associated with measurement of energy and location, are not pictures in the IMINT sense. Currently called the Satellite Early Warning System (SEWS), the program is the descendant of several generations of [[Defense Support Program]] (DSP) spacecraft. The fUSSR/[[Russia|Russian]] Prognoz spacecraft has been described, by US sources, as having similar capabilities to DSP <ref name=IOSS3>{{citation
The US, in 1970, launched the first of a series of space-based [[staring array]] sensors that detected and located infrared heat signatures, typically from rocket motors but also from other intense heat sources. Such signatures, which are associated with measurement of energy and location, are not pictures in the IMINT sense. Currently called the Satellite Early Warning System (SEWS), the program is the descendant of several generations of [[Defense Support Program]] (DSP) spacecraft. The fUSSR/[[Russia|Russian]] Prognoz spacecraft has been described, by US sources, as having similar capabilities to DSP.<ref name=IOSS3>{{citation
  | url = http://www.fas.org/irp/nsa/ioss/threat96/part03.htm
  | url = http://www.fas.org/irp/nsa/ioss/threat96/part03.htm
  | title = Operations Security Intelligence Threat Handbook, Section 3, Adversary Foreign Intelligence Operations
  | title = Operations Security Intelligence Threat Handbook, Section 3, Adversary Foreign Intelligence Operations
  | author = Interagency OPSEC Support Staff
  | author = Interagency OPSEC Support Staff
  | date = May 1996
  | date = May 1996
}}</ref>.
}}</ref>


<!--[[Image:STS-44 DSP deployment.jpg|thumb|220px|DSP satellite deployment during [[STS-44]]]]-->
<!--[[Image:STS-44 DSP deployment.jpg|thumb|220px|DSP satellite deployment during [[STS-44]]]]-->

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Electro-optical MASINT is a subdiscipline of Measurement and signature Intelligence (MASINT), and refers to intelligence gathering activities which bring together disparate elements that do not fit within the definitions of Signals Intelligence (SIGINT), Imagery Intelligence (IMINT), or Human Intelligence (HUMINT).

Electro-optical MASINT has similarities to IMINT, but is distinct from it. IMINT's primary goal is to create a picture, composed of visual elements understandable to a trained user. Electro-optical MASINT helps validate that picture, so that, for example, the analyst can tell if an area of green is vegetation or camouflage paint. Electro-optical MASINT also generates information on phenomena that emit, absorb, or reflect electromagnetic energy in the infrared, visible light, or ultraviolet spectra, phenomena where a "picture" is less important than the amount or type of energy reported. For example, a class of satellites, originally intended to give early warning of rocket launches based on the heat of their exhaust, reports energy wavelengths and strength as a function of location(s). There would be no value, in this specific context, to seeing a photograph of the flames coming out of the rocket.

Subsequently, when the geometry between the rocket exhaust and the sensor permits a clear view of the exhaust, IMINT would give a visual or infrared picture of its shape, while electro-optical MASINT would give, either as a list of coordinates with characteristics, or a "false-color" image, the temperature distribution, and spectroscopic information on its composition.

In other words, MASINT may give warning before characteristics visible to IMINT are clear, or it may help validate or understand the pictures taken by IMINT.

MASINT techniques are not limited to the United States, but the U.S. distinguishes MASINT sensors from others more than do other nations. According to the United States Department of Defense, MASINT is technically derived intelligence (excluding traditional imagery IMINT and signals intelligence SIGINT) that – when collected, processed, and analyzed by dedicated MASINT systems – results in intelligence that detects, tracks, identifies, or describes the signatures (distinctive characteristics) of fixed or dynamic target sources. MASINT was recognized as a formal intelligence discipline in 1986.[1] Another way to describe MASINT is "a "non-literal" discipline. It feeds on a target's unintended emissive byproducts, the "trails" of thermal energy, chemical or radio frequency emission that an object leaves in its wake. These trails form distinct signatures, which can be exploited as reliable discriminators to characterize specific events or disclose hidden targets"[2]

As with many branches of MASINT, specific techniques may overlap with the six major conceptual disciplines of MASINT defined by the Center for MASINT Studies and Research, which divides MASINT into Electro-optical, Nuclear, Geophysical, Radar, Materials, and Radiofrequency disciplines.[3]

MASINT collection technologies in this area use radar, lasers, staring arrays in the infrared and visual, to point sensors at the information of interest. As opposed to IMINT, MASINT electro-optical sensors do not create pictures. Instead, they would indicate the coordinates, intensity, and spectral characteristics of a light source, such as a rocket engine, or a missile reentry vehicle. Electro-optical MASINT involves obtaining information from emitted or reflected energy, across the wavelengths of infrared, visible, and ultraviolet light. Electro-optical techniques include measurement of the radiant intensities, dynamic motion, and the materials composition of a target. These measurements put the target in spectral and spatial contexts. Sensors used in electro-optical MASINT include radiometers, spectrometers, non-literal imaging systems, lasers, or laser radar (LIDAR).[4]

Observation of foreign missile tests, for example, make extensive use of MASINT along with other disciplines. For example, electro-optical and radar tracking establish trajectory, speed, and other flight characteristics that can be used to validate the TELINT telemetry intelligence being received by SIGINT sensors. Electro-optical sensors, which guide radars, operate on aircraft, ground stations, and ships.

Airborne Electro-Optical Missile Tracking MASINT

U.S. RC-135S COBRA BALL aircraft have MASINT sensors that are "...two linked electro-optical sensors -- the Real Time Optics System (RTOS) and the Large Aperture Tracker System (LATS). RTOS consists of an array of staring sensors encompassing a wide field of regard for target acquisition. LATS serves as an adjunct tracker. Due to its large aperture, it has significantly greater sensitivity and resolving power than the RTOS, but is otherwise similar.[5]

There is a broader program to standardize the architecture of the various RC-135 aircraft, so that there will be greater commonality of parts, and some ability to switch missions: a COBRA BALL will be able to carry out some SIGINT missions of the RIVET JOINT RC-135.

COBRA BALL cues the COBRA DANE ground radar and the COBRA JUDY ship-based radar. See Radar MASINT

Tactical Counterartillery Sensors

Both electro-optical and radar sensors have been coupled with acoustic sensors in modern counter-artillery systems. Electro-optical sensors are directional and precise, so need to be cued by acoustic or other omnidirectional sensors. The original Canadian sensors, in the First World War, used electro-optical flash as well as geophysical sound sensors.

Purple Hawk

Complementing counter-mortar radar is the Israeli Purple Hawk mast-mounted electro-optical sensor, which detects mortars and provides perimeter security. The device, remotely operated via fiber optics or microwave, is intended to have a laser designator.[6]

Rocket Launch Spotter

A newer U.S. system couples an electro-optical and an acoustic system to produce the Rocket Artillery Launch Spotter (RLS).[7] RLS combines components from two existing systems, the Tactical Aircraft Directed Infra-Red Countermeasures (TADIRCM) and the UTAMS . The two-color infrared sensors were originally designed to detect surface-to-air missiles for TADIRCM. Other TADIRCM components also have been adapted to RLS, including the computer processors, inertial navigation units (INU), and detection and tracking algorithms.

It is an excellent example of automatic cueing of one sensor by another. Depending on the application, the sensitive but less selective sensor is either acoustic or nonimaging electro-optical. The selective sensor is forward-looking infrared (FLIR).


RLS uses two TADIRCM sensors, an INU, and a smaller field-of-view single-color (FLIR) camera on each tower. The INU, which contains a GPS receiver, allows the electro-optical sensors to align to the azimuth and elevation of any detected threat signature.

The basic system mode is for rocket detection, since a rocket launch gives a bright flare. In basic operation, RLS has electro-optical systems on three towers, separated by 2 to 3 kilometers, to give omnidirectional coverage. The tower equipment connects to the control stations using a wireless network.

When a sensor measures a potential threat, the control station determines if it correlates with another measurement to give a threat signature. When a threat is recognized, RLS triangulates the optical signal and presents the Point of Origin (POO) on a map display. The nearest tower FLIR camera then is cued to the threat signature, giving the operator real-time video within 2 seconds of detection. When not in RLS mode, the FLIR cameras are available to the operator as surveillance cameras.

Mortar launches do not produce as strong an electro-optical signature as does a rocket, so RLS relies on acoustic signature cueing from an Unattended Transient Acoustic Measurement and Signal Intelligence System (UTAMS). There is an UTAMS array at the top of each of the three RLS towers. The tower heads can be rotated remotely.

Each array consists of four microphones and processing equipment. Analyzing the time delays between an acoustic wavefront’s interaction with each microphone in the array UTAMS provides an azimuth of origin. The azimuth from each tower is reported to the UTAMS processor at the control station, and a POO is triangulated and displayed. The UTAMS subsystem can also detect and locate the point of impact (POI), but, due to the difference between the speeds of sound and light, it may take UTAMS as long as 30 seconds to determine the POO for a rocket launch 13 km away. This means UTAMS may detect a rocket POI prior to the POO, providing very little if any warning time. but the electro-optical component of RLS will detect the rocket POO earlier.

Infrared MASINT

While infrared IMINT and MASINT operate in the same wavelengths, MASINT does not “take pictures” in the conventional sense, but it can validate IMINT pictures. Where an IR IMINT sensor would take a picture that fills a frame, the IR MASINT sensor gives a list, by coordinate, of IR wavelengths and energy. A classic example of validation would be analyzing the detailed optical spectrum of a green area in a photograph: is the green from natural plant life, or is it camouflage paint?

The Army's AN/GSQ-187 Improved Remote Battlefield Sensor System (I-REMBASS) contains a Passive Infrared Sensor, DT-565/GSQ, which "detects tracked or wheeled vehicles and personnel. It also provides information on which to base a count of objects passing through its detection zone and reports their direction of travel relative to its location. The monitor uses two different [magnetic and passive infrared] sensors and their identification codes to determine direction of travel.

Shallow-water operations [8] require generalizing IR imaging to include a non-developmental Thermal Imaging Sensor System (TISS) to surface ships with a day/night, high-resolution, infrared (IR) and visual imaging, and laser range-finder capability to augment existing optical and radar sensors, especially against small boats and floating mines. Similar systems are now available in Army helicopters and armored fighting vehicles.

Optical Measurement of Nuclear Explosions

There are several distinctive characteristics, in the range of visible light, from nuclear explosions. One of these is a characteristic "dual flash" measured by a bhangmeter. This went into routine use on the advanced Vela nuclear detection satellites, first launched in 1967. The earlier Velas only detected X-rays, gamma rays, and neutrons.

The bhangmeter technique was used earlier, in 1961, aboard a modified US KC-135B aircraft monitoring the preannounced Soviet test of Tsar Bomba, the largest nuclear explosion ever detonated.[9] The US test monitoring, which carried both broadband electromagnetic and optical sensors including a bhangmeter, was named SPEEDLIGHT.

As part of Operation BURNING LIGHT, one MASINT system photographed the nuclear clouds of French atmospheric nuclear tests to measure their density and opacity.[10] [11] This operation is borderline with Nuclear MASINT.

Bhangmeters on Advanced Vela satellites detected the what is variously called the Vela Incident or South Atlantic Incident, on 22 September 1979. Different reports have claimed that it was, or was not, a nuclear test, and, if it was, probably involved South Africa and possibly Israel. France and Taiwan have also been suggested. Only one bhangmeter detected the characteristic double-flash, although US Navy hydrophones suggest a low-yield blast. Other sensors were negative or equivocal, and no definitive explanation has yet been made public.

LASER MASINT

This discipline includes both measuring the performance of lasers of interest, and using lasers as part of MASINT sensors. With respect to foreign lasers, focus of the collection is on laser detection, laser threat warning, and precise measurement of the frequencies, power levels, wave propagation, determination of power source, and other technical and operating characteristics associated with laser systems strategic and tactical weapons, range finders, and illuminators. [4]

In addition to passive measurements of other lasers, the MASINT system can use active lasers (LIDAR) for distance measurements, but also for destructive remote sensing that provides energized material for spectroscopy. Close-in lasers could do chemical (i.e., materials MASINT) analysis of samples vaporized by lasers.

Laser systems are largely at a proof of concept level.[12] One promising area is a synthetic imaging system that would be able to create images through forest canopy, but the current capability is much less than existing SAR or EO systems.

A more promising approach would image through obscurations such as dust, cloud, and haze, particularly in urban environments. The laser illuminator would send a pulse, and the receiver would capture only the first photons to return, minimizing scattering and blooming.

Use of LIDAR for precision elevation and mapping is much closer, and again chiefly in urban situations.

Spectroscopic MASINT

Spectroscopy can be applied either to targets that are already excited, such as an engine exhaust, or stimulated with a laser or other energy source. It is not an imaging technique, although it can be used to extract greater information from images.

Where an IMINT sensor would take a picture that fills a frame, the Spectroscopic MASINT sensor gives a list, by coordinate, of wavelengths and energy. Multispectral IMINT is likely to discriminate more wavelengths, especially if it extends into the IR or UV, than a human being, even with an excellent color sense, could discriminate.

The results plot energy versus frequency. A spectral plot represents radiant intensity versus wavelength at an instant in time. The number of spectral bands in a sensor system determines the amount of detail that can be obtained about the source of the object being viewed. Sensor systems range from

  • multispectral (2 to 100 bands) to
  • hyperspectral (100 to 1,000 bands) to
  • ultraspectral (1,000+ bands).

More bands provide more discrete information, or greater resolution. The characteristic emission and absorption spectra serve to fingerprint or define the makeup of the feature that was observed. A radiometric plot represents the radiant intensity versus time; there can be plots at multiple bands or wavelengths. For each point along a time-intensity radiometric plot, a spectral plot can be generated based on the number of spectral bands in the collector, such as the radiant intensity plot of a missile exhaust plume as the missile is in flight. The intensity or brightness of the object is a function of several conditions including its temperature, surface properties or material, and how fast it is moving. [4] Remember that additional, non-electro-optical sensors, such as ionizing radiation detectors, can correlate with these bands.

Advancing optical spectroscopy was identified as a high priority by a National Science Foundation workshop[13] in supporting counterterrorism and general intelligence community needs. These needs were seen as most critical in the WMD context. The highest priority was increasing the sensitivity of spectroscopic scanners, since, if an attack has not actually taken place, the threat needs to be analyzed remotely. In the real world of attempting early warning, expecting to get a signature of something, which is clearly a weapon, is unrealistic. Consider that the worst chemical poisoning in history was an industrial accident, the Bhopal disaster. The participants suggested that the "intelligence community must exploit signatures of feedstock materials, precursors, by-products of testing or production, and other inadvertent or unavoidable signatures." False positives are inevitable, and other techniques need to screen them out.

Second to detectability, as a priority was rejecting noise and background. It is especially difficult for biowarfare agents, which are the greatest WMD challenge to detect by remote sensing rather than laboratory analysis of a sample. Methods may need to depend on signal enhancement, by clandestine dispersion of reagents in the area of interest, which variously could emit or absorb particular spectra. Fluorescent reactions are well known in the laboratory; could they be done remotely and secretly? Other approaches could pump the sample with an appropriately tuned laser, perhaps at several wavelengths. The participants stressed that the need to miniaturize sensors, which might enter the area in question using unmanned sensors, including miniaturized aerial, surface, and even subsurface vehicles.

Electro-optical spectroscopy is one means of chemical detection, especially using nondispersive infrared spectroscopy is one MASINT technology that lends itself to early warning of deliberate or actual releases. In general, however, chemical sensors tend to use a combination of gas chromatography and mass spectrometry, which are more associated with materials MASINT. See Chemical Warfare and Improvised Chemical Devices.

Laser excitation with multispectral return analysis is a promising chemical and possibly biological analysis method.[12]

Multispectral MASINT

SYERS 2, on the high-altitude U-2 reconnaissance aircraft, is the only operational airborne military multi-spectral sensor, providing 7 bands of visual and infrared imagery at high resolution.[12]

Hyperspectral MASINT

Hyperspectral MASINT involves the synthesis of images as seen by visible and near infrared light. US MASINT in this area is coordinated by the Hyperspectral MASINT Support to Military Operations (HYMSMO) project. This MASINT technology differs from IMINT in that it attempts to understand the physical characteristics of what is seen, not just what it looks like.[14]

Hyperspectral imaging typically needs multiple imaging modalitiesd, such as whiskbroom, pushbroom, tomographic, intelligent filters, and time series.

Design Issues

Some of the major issues in visible and infrared hyperspectral processing include atmospheric correction, for the visible and short wave infrared.[15] (0.4 - 2.5 micrometer) dictate sensor radiances need to be converted to surface reflectances. This dictates a need for measuring, and connecting for:

  • atmospheric absorption and scattering
  • aerosol optical depth,
  • water vapor,
  • correction for the effect of bi-directional reflectance distribution function,
  • blurring due to the adjacency effect and retrieval of reflectance in shadows.

Hyperspectral, as opposed to multispectral, processing gives the potential of improved spectral signature measurement from airborne and spaceborne sensor platforms. Sensors on these platforms, however, must compensate for atmospheric effects. Such compensation is easiest with high contrast targets sensed through well-behaved atmosphere with even, reliable illumination, the real world will not always be so cooperative. For more complicated situations, one can not simply compensate for the atmospheric and illumination conditions by taking them out. The Invariant Algorithm for target detection was designed to find many possible combinations of these conditions for the image.[16]

Sensors

Multiple organizations, with several reference sensors, are collecting libraries of hyperspectral signatures, starting with undisturbed areas such as deserts, forests, cities, etc.

  • AHI, the Airborne Hyperspectral Imager,[17] a hyperspectral sensor operating in the long-wave infrared spectrum for DARPA’s Hyperspectral Mine Detection (HMD) program. AHI is a helicopter-borne LWIR hyperspectral imager with real time on-board radiometric calibration and mine detection.
  • COMPASS, the Compact Airborne Spectral Sensor, a day-only sensor for 384 bands between from 400 to 2350 nm, being developed by the Army Night Vision and Electronic Sensors Directorate (NVESD)[12].
  • HyLite, Army day/night Hyperspectral Longwave Imager for the Tactical Environment Cite error: Closing </ref> missing for <ref> tag built by Hughes Danbury Optical Systems and flight tested on a Convair 580.
  • SPIRITT, the Air Force's Spectral Infrared Remote Imaging Transition Testbed,[18] a day/night, long range reconnaissance imaging testbed composed of a hyperspectral sensor system with integrated high resolution imaging

Signature Libraries

Under the HYMSMO program, there have been a number of studies to build hyperspectral imaging signatures in various kinds of terrain.[19] Signatures of undisturbed forest, desert, island and urban ares are being recorded with sensors including COMPASS, HYDICE and SPIRITT. Many of these areas are also being analyzed with complementary sensors including synthetic aperture radar (SAR).

Hyperspectral Signature Library Development
Operation/Environment Date Location
Desert Radiance I[20] October 1994 White Sands Missile Range, New Mexico
Desert Radiance II June 1995 Yuma Proving Grounds, Arizona
Forest Radiance I[21] (also had urban and waterfront components) August 1995 Aberdeen Proving Grounds, Maryland
Island Radiance I[22] (also had lake, ocean and shallow water components) October 1995 Lake Tahoe, California/Nevada; Kaneohe Bay, Hawaii

A representative test range, with and without buried metal, is the Steel Crater Test Area at the Yuma Proving Grounds.[23] This was developed for radar measurements, but is comparable to other signature development areas for other sensors and may be used for hyperspectral sensing of buried objects.

Applications

In applications of intelligence interest, the Johns Hopkins University Applied Physics Laboratory (JHU/APL) has demonstrated that hyperspectral sensing allows discrimination of refined signatures, based on a large number of narrow frequency bands across a wide spectrum.[24] These techniques can identify include military vehicle paints, characteristic of particular countries' signatures. They can differentiate camouflage from real vegetation. By detecting disturbances in earth, they can detect a wide variety of both excavation and buried materials. Roads and surfaces that have been lightly or heavily trafficked will produce different measurements than the reference signatures.

It can detect specific types of foliage supporting drug-crop identification; disturbed soil supporting the identification of mass graves, minefields, caches, underground facilities or cut foliage; and variances in soil, foliage, and hydrologic features often supporting NBC contaminant detection. This was done previously with false-color infrared photographic film, but electronics are faster and more flexible. [14]

Minefield detection

JHU/APL target-detection algorithms have been applied to the Army Wide Area Airborne Minefield Detection (WAAMD) program’s desert and forest. By using the COMPASS and AHI hyperspectral sensors, robust detection of both surface and buried minefields is achieved with very low false alarm rates.

Underground Construction

Hyperspectral imaging can detect disturbed earth and foliage. In in concert with other methods such as coherent change detection radar, which can precisely measure changes in the height of the ground surface. Together, these can detect underground construction.

While still at a research level, Gravitimetric MASINT can, with these other MASINT sensors, give precise location information for deeply buried command centers, WMD facilities, and other critical target. It remains a truism that once a target can be located, it can be killed. "Bunker-buster" nuclear weapons are not needed when multiple precision guided bombs can successively deepen a hole until the no-longer-protected structure is reached.

Urban Spectral Target Detection

Using data collected over US cities by the Army COMPASS and Air Force SPIRITT sensors, JHU/APL target detection algorithms are being applied to urban hyperspectral signatures. The ability to robustly detect unique spectral targets in urban areas denied for ground inspection, with limited ancillary information will assist in the development and deployment of future operational hyperspectral systems overseas.[24]

Mass Graves

Peace operations and war crimes investigation may require the detection of often-clandestine mass graves. Clandestinity makes it difficult to get witness testimony, or use technologies that require direct access to the suspected grave site (e.g., ground penetrating radar). Hyperspectral imaging from aircraft or satellites can provide remotely sensed reflectance spectra to help detect such graves. Imaging of an experimental mass grave and a real-world mass grave show that hyperspectral remote imaging is a powerful method for finding mass graves in real time, or, in some cases, retrospectively.[25]

Ground Order of Battle Target Detection

JHU/APL target detection algorithms have been applied to the HYMSMO desert and forest libraries, and can reveal camouflage, concealment and deception protecting ground miitary equipment. Other algorithms have been demonstrated, using HYDICE data, that they can identify lines of communication based on the disturbance of roads and other ground surfaces.[24]

Biomass Estimation

Knowing the fractions of vegetation and soil is of helps estimate the biomass. Biomass is not extremely important for military operations, but gives information for national-level economic and environmental intelligence. Detailed hyperspectral imagery such as the leaf chemical content (nitrogen, proteins, lignin and water) can be relevant to counterdrug surveillance.[26]

Space-based Staring Infrared Sensors

The US, in 1970, launched the first of a series of space-based staring array sensors that detected and located infrared heat signatures, typically from rocket motors but also from other intense heat sources. Such signatures, which are associated with measurement of energy and location, are not pictures in the IMINT sense. Currently called the Satellite Early Warning System (SEWS), the program is the descendant of several generations of Defense Support Program (DSP) spacecraft. The fUSSR/Russian Prognoz spacecraft has been described, by US sources, as having similar capabilities to DSP.[27]


Originally intended to detect the intense heat of an ICBM launch, this system proved useful at a theater level in 1990-1991. It detected the launch of Iraqi Scud missiles in time to give early warning to potential targets.

Shallow Water Operations

Several new technologies will be needed for shallow-water naval operations[8]. Since acoustic sensors (i.e., passive hydrophones and active sonar) perform less effectively in shallow waters than in the open seas, there is a strong pressure to develop additional sensors.

One family of techniques, which will require electro-optical sensors to detect, is bioluminescence: light generated by the movement of a vessel through plankton and other marine life. Another family, which may be solved with electro-optical methods, radar, or a combination, is detecting wakes of surface vessels, as well as effects on the water surface caused by underwater vessels and weapons.

References

  1. Interagency OPSEC Support Staff (IOSS) (May 1996). Operations Security Intelligence Threat Handbook: Section 2, Intelligence Collection Activities and Disciplines.
  2. Lum, Zachary (August 1998). "The measure of MASINT". Journal of Electronic Defense.
  3. Center for MASINT Studies and Research. Center for MASINT Studies and Research. Air Force Institute of Technology.
  4. 4.0 4.1 4.2 US Army (May 2004). Chapter 9: Measurement and Signals Intelligence. Field Manual 2-0, Intelligence. Department of the Army.
  5. Pike, John, COBRA BALL
  6. Daniel W. Caldwell, Radar planning, preparation and employment of 3-tiered coverage: LCMR, Q-36 and Q-37
  7. Mabe, R.M. et al.. Rocket Artillery Launch Spotter (RLS).
  8. 8.0 8.1 National Academy of Sciences Commission on Geosciences, Environment and Resources (April 29-May 2, 1991). Symposium on Naval Warfare and Coastal Oceanography. Retrieved on 2007-10-17.
  9. Sublette, Carey. Big Ivan, The Tsar Bomba (“King of Bombs”): The World's Largest Nuclear Weapon.
  10. History Division, Strategic Air Command, SAC Reconnaissance History, January 1968-June 1971
  11. Office of the Historian, Strategic Air Command, History of SAC Reconnaissance Operations, FY 1974
  12. 12.0 12.1 12.2 12.3 Office of the Secretary of Defense, Unmanned Aircraft Systems Roadmap 2005-2030
  13. (August 2003). Approaches to Combat Terrorism (ACT): Report of a Joint Workshop Exploring the Role of the Mathematical and Physical Sciences in Support of Basic Research Needs of the U.S. Intelligence Community. National Science Foundation.
  14. 14.0 14.1 Gatz, Nahum (February 23, 2006). Hyperspectral Technology OverviewNASIC Distinguished Lecture Series in Remote Sensing, Wright-Patterson Air Force Base, Dayton, Ohio: Center for MASINT Studies and Research.
  15. Goetz, Alexander (February 3, 2006). Hyperspectral Remote Sensing of the Earth: Science, Sensors and ApplicationsNASIC Distinguished Lecture Series in Remote Sensing, Wright-Patterson Air Force Base, Dayton, Ohio: Center for MASINT Studies and Research.
  16. Gold, Rachel (May 2005). Performance Analysis of the Invariant Algorithm for Target Detection in Hyperspectral Imagery.
  17. Lucey, P.G. et al.. An Airborne Hyperspectral Imager for Hyperspectral Mine Detection.
  18. Spectral Infrared Remote Imaging Transition Testbed (December 21, 2000).
  19. Bergman, Steven M. (December 1996). The Utility of Hyperspectral Data in Detecting and Discriminating Actual and Decoy Target Vehicles. US Naval Postgraduate School.
  20. Fay, Matthew E. (1997), An Analysis of Hyperspectral Data collected during Operation Desert Radiance, US Naval Postgraduate School
  21. Olsen, R.C. (1997). Target detection in a forest environment using spectral imagery. US Naval Postgraduate School.
  22. Stuffle, L. Douglas (December, 1996), Bathymetry by Hyperspectral Imagery, US Naval Postgraduate School
  23. Clyde C. DeLuca; Vincent Marinelli , Marc Ressler, and Tuan Ton. Unexploded Ordnance Detection Experiments Using Ultra-Wideband Synthetic Aperture Radar.
  24. 24.0 24.1 24.2 Kolodner, Marc A.. Hyperspectral Exploitation Program. Retrieved on 2007-12-01. Cite error: Invalid <ref> tag; name "Kolodner" defined multiple times with different content
  25. Kalacska, M. (March 2006). "Remote Sensing as a Tool for the Detection of Clandestine Mass Graves". Canadian Society of Forensic Science Journal 39 (1).
  26. Borel, Christoph C. (July 17, 2007), Challenging Image Analysis Problems in the Exploitation of Hyperspectral Remote Sensing Data for the Visible and Infrared Spectral Region, Wright-Patterson Air Force Base, Dayton, Ohio: Center for MASINT Studies and Research
  27. Interagency OPSEC Support Staff (May 1996), Operations Security Intelligence Threat Handbook, Section 3, Adversary Foreign Intelligence Operations