Imagery analysis: Difference between revisions

{{Wikify|January 2007}} '''Imagery Analysis'''

The successful extraction of useful information from mostly bi-dimensional graphic

formats, including screen shots. In it's broadest sense it includes both color, and

black & white photographs, infra-red photographs and video, radar screens and

synthetic aperture radar formats, ultrasound, EKG, EEG, MRI, echo cardiograms, seismographs

and others. In short, any type of sensor-related data projected in 2 & 3D formats qualifies

as imagery.

Please keep in mind that since imagery analysis has it's start in military

intelligence, whose collection methods and analytical techniques for most of the last

century has been classified, it is close to impossible to independently verify many

details related to the development of imagery technology and analytical methods.

On the basis of my own training as an Army Imagery Analyst, my access to very old

imagery, pictures and anecdotes of collection and analysis of the time and open-source

information of the time makes it possible to paint a well-informed portrait of basic

techniques and technologies.

Keeping in mind that many of the pioneers are now dead, it's important to access

testimonials of retired analysts and technicians in order to obtain more exact

information, adding it as it becomes available.

'''Table of Contents:'''

I. The Origin of Imagery Analysis.

II. The Computer and how it affected Imagery Analysis.

III. The Development of Analytical Techniques.

IV. Actual Applications.

V. Future Applications.

[[I. The origin of Imagery Analysis.]]

Prior to the invention of early photography, military commanders depended on scouts

that would explore, and from high ground would survey or reconnoiter enemy activity,

depending on simple eyesight and human memory. Once photography became available, tactical

information became frozen in time, details could be preserved, enhancing the quality of

available information.

1. World war I saw the start of ground based and aerial photographic collection. For

the first time commanders were able to access timely and accurate intelligence. Such was

the value of this type of information that observers in tethered balloons and scout

planes were attacked, first with crude weapons and later escalating to machine guns and

the development of the fighter.

Frank Luke, an american pilot procured incendiary ammunition and used it to destroy

numerous enemy observation balloons, gaining the title of Balloon Buster.

The end of the war resulted in the scaling down of tactical and strategic

capabilities, resulting in almost dormant state in the development of photographic

analysis. The perceived threat from Germany and Japan revived the collection and analytical

capabilities of the major powers and helped military planners including one named

Eisenhower prepare for the next war.

2. In the 1930's experiments with film media and it's processing resulted in the

introduction of film that could now detect non-visible wavelengths in the Infra-red

spectrum.

One of the first applications was the use by those associated with rare art collections.

Previously invisible details made it possible to detect and deter forgeries.

Radar made its appearance during World War II, primarily in its early warning

capability. In the early days of the cold war, soviet troops would use a directional

radar beacon to lure surveillance aircraft toward their airspace in order to shoot them

down. By this time radar scopes became available in larger aircraft monitoring soviet-

controlled border areas. Having these scopes made early radar navigation possible, indeed,

in photos released by the Air Force, pictures were taken of the screens, documenting this

use.

The importance of tactical information is shown in the case of operation Market-Garden,

the aerial invasion of the Netherlands - sep 17, 1944. Photomissions revealed the presence

of two Panzer(armored) Divisions in the city of Arnhem, a bridgehead at the farthest reach

of those airborne troops assigned.

British Intelligence Major Brian Urquhart warned his commander of the threat, but an

overpowering optimism cause by the recent collapse of the western front overuled any

possibility of an objective threat assessment, resulting in a night-time river-crossing

in which out of 10,000 members of the british 1st Airborne Division that jumped into

Arnhem, only 2,600 survivors would reach reach the southern shore 9 days later.

In spite of the introduction of color film, photo interpreters to this day continue

to use Black & White because of the greater detail available. The early cold war era also

saw the introduction of strategic collection. In tactical collection, you count guns,

strategic collection includes butter. The categories of collection is of course,

classified.

3. The Post-Vietnam era saw the introduction of airborne infra-red sensors.

Differences in temperatures between objects and their surroundings made it possible to

detect targets on the ground. These early systems would record data which would be

accessed once the aerial platform would land. Later developments in transmission

technology would provide periodic data dumps and would further evolve into real-time

collection.

4. Synthetic Aperture Radar would soon be developed in the later part of the Cold War.

The concept of an optical camera aperture affecting the image acquisition process would be

emulated with radar waves, providing an undisclosed amount of detail. One clue would be

the NASA photo released in the late 1980's showing a previously hidden african dry riverbed.

5. This is also about the time when ultrasound would make it's appearance. For the

first time it was possible to view variations in tissue density which made it possible

to detect possible tissue and organ anomalies. Another application was that of detecting

material flaws in manufacturing.

[[II. The Computer and how it affected Imagery Analysis.]]

1. Experimentation with monochromatic imagery(Black & White) imagery revealed the

potential of exploiting the hundreds of shades of grey available in this medium. The next

step would be to digitally manipulate the grey scale to enhance the acquisition of usable

information. The first applications of this new technology would be by the intelligence

community and by medical researchers who would refine and further develop the technology,

resulting in the introduction of the CAT Scan.

2. Another technology introduced roughly at this time would be that of the echo-

cardiograph, which could show heart movements and the actual bloodflow through its

chambers.

One of the more recent developments has been that of Magnetic Resonance

Imaging(MRI), where tissue and bloodflow anomalies could be detected. Evidence of spinal

chord injuries and even complex neurochemical reactions in the brain could now be

detected and documented.

Scientists have also explored the possibilities of multi-spectral imaging such as

the 1970's LandSat, and yet more parts of the electromagnetic spectrum such as

astronomical gamma-ray imaging.

[[III. The Development of Analytical Techniques.]]

1. The first use of tactical imagery obtained during th first world war readily

revealed the straight man-made lines of roads, cites, airfields and trenches. Finding

concealed high-value targets like artillery, ammo dumps and other logistical sites was

quite another matter.

This was a process that was strictly by trial and error, with the resulting body

of knowledge transmitted to new recruits and officers. Terrain and the proximity to

supported units would dictate probable locations of logistical routes, ammo dumps,

supply depots and assembly areas. Being that the military by definition embraces

uniformity, patterns of emplacement and concealment, once discovered would result

in widespread targeting by artillery and air strikes.

The size, shape, and surroundings of items frequently gave away the location

of military assets, with shadows only making it that much easier to identify targets.

The development of analytical techniques is really a part of the evaluation of

the new technology itself. The first photograph to be taken was that of a french

neighborhood. It was crude, yet it clearly showed the outline of the houses.

Immediately it was apparent how the new technology, that is, the chemical film

plate was of immediate usefulness.

2. In the case of infra-red photography, the new details made available were

puzzling at first, and took some time to explain. In the pictures taken of works

of art, the strange images would eventually be interpreted as showing a feature being

painted over and finished. Simultaneous aerial coverage by photo and IR of a given

target would reveal how a warm vehicle would warm up the ground and once moved,

the warmed plot would stay warm for some time, giving the illusion of more vehicles.

Just as in the case of an experienced scientist, once you have a new observation,

you then have to explain it.

In the case of the application of radar, all you had at the beginning was a

variation of the cathode ray tube which would show only the distance to a single

target. Only with the introduction of the more familiar round screen format would

radar reach it's full potential.

So, you have the raw data but without the use of a readable 2 or 3D format,

you can't make that much use of this information. One thing to remember about radar

is that when it comes to illuminating aircraft, most of the energy is deflected.

Only the existence of corners, air intakes and flat surfaces that face the radar

makes it possible to detect these aircraft.

What is actually seen by traffic controllers is the return beep from the

aircraft's IFF. As in the case of 911, once the hijacked aircraft's IFF was turned

off, there wasn't much to see. You can also see this in the use of radar reflectors

that are routinely added to power lines in order to avoid crashes by low-flying

aircraft. The actual characteristics of synthetic aperture radar is of course,

classified, so one can only speculate on what is actually observable.

3. For the development of CATScans, computer aided design,CAD, had to come

first. Pictures were publicized in the 1960's showing design engineers using light

pen peripherals to draw proposed design features to be evaluated for fit and

aerodynamics before costly manufacturing jigs had to be built.

In the case of CATScans, if you don't have a 3D capability, the information

from Xrays is useless.

4. For the development of Ultrasound, the use of anatomical studies,

dissections and autopsies would have been necessary to provide insight and

confirmation of what was now visible. It would have taken some time to establish

average dimensions for organs and in the case of pre-natal scans body dimensions and

growth rates

5. The development Magnetic Resonance Imaging would have been a question of

comparing their data with that of CATScans and ultrasound. As far as how they

established the visiblity of neurochemical reactions, that would have been dependent

on current knowledge of neurological and physiological processes.

Now we have a situation where a new technology that is based on previous

understanding actually increases those fields of knowledge that made it possible.

6. The current emphasis of multi-spectral imaging is really a question of

maximizing the amount of data available for geological, agricultural and

environmental research. This means that you would only have to cover a given area

once, making global coverage a more economical proposition.

7. The latest imaging technolgies are driven by nuclear physics and astronomic

research. You can see this in the evaluation of particle acceleration, where

theoretical physics helps to make sense of the collected data. As in the case of

particle physics, multispectral orbital imaging is driven by theoretical research,

only to be confirmed by other sources.

[[IV. Current Applications.]]

1. Besides the traditional tactical and strategic use by civilian and military

intelligence, other entities have made extensive use of this discipline. Law

enforcement has made use of imagery in forensic crime scene documentation in order

to determine how crimes were commited to include how the assailant approached and

left the crime scene. Also, bullet trajectories can be detected in order to determine

the location of a sharpshooter.

The Border patrol has the use of imaging technology, determining transit routes

and the detection of illegal aliens trying to escape into the interior, beyond the

reach of the agents. Their only real problem is that there are way too many routes

to cover with the manning and technology only able to do so much.

2. Highway departments make use of stereo and terrain analysis techniques to

determine potential highway routes. As in the case of currently available programs,

imagery is included with other types of information to create detailed maps useful

for commerce, taxation, city planning and infrastructure.

3. The most important application has been for medical and research purposes.

Many advances in diagnostics and monitoring have contributed to the ever-increasing

body of knowledge and treatment options. The only problem is that with the increase

in diagnostic capability, the aspect of accountability and malpractice has made

necessary the costly regimen of multiple-discipline testing. This is not about to

change.

The positive side of developing new imaging technologies is that enhanced

observation and understanding will result in better diagnostics and treatments.

4. The introduction of LandSat in the mid '70s made possible new applications in

the fields of agriculture, geology, mining, and the environment. The actual resolution

would not be great, but sufficient for these types of applications. The raw data would

include the grey scale, and information from a variety of sensors. The designers would

find it necessary to assign colors for each type of return, creating a multicolored map.

5. Meteorological imagery since the '60s has made it possible to detect and

monitor severe weather well in advance of it's arrival, saving numerous lives.

[[V. Future applications.]]

One promising application would be in the field of Archeology. Terrain analysis

would show trade routes, lines of communication, cities, forts, farming, grazing, water

sources, supporting communities that surround cities and service trade routes, ancient

borders and more.

1. In the case of Ancient Egypt, IR would reveal water sources that would have

supported communities in the desert. Terrain Analysis reveals that in order to access

the Sinai copper mines, one had to access the shallow eastward valley north of present

day Cairo and reach the Red Sea just south of Port Said. From there it would have been

a question of sailing east toward the western coast of the Sinai and turn southward

toward Ras Abu Rudeis, a small coastal plain just east of the 2 copper mines.

The reason for this is that an overland route would have required the costly

logistical support of garrisons through territory held by hostile desert tribes.

2. In the case of the biblical exodus, terrain analysis excludes the traditional

sites as being too far and not being accessible to such a large group of people.

Advancing through mountainous terrain would have exposed them to ambushes.

The only confirmed location within Egypt or the Sinai is that of Baal Zephon.

Ancient papyrii describe this location as being close to Ramses, Tahpanhes and present

day Lake Menzaleh.

Being that Biblical Archeology is almost devoid of independent confirmation, one

has to use what little confirmed information is available. Following terrain, they

would have set out eastward along the mediterranean coast, reaching the Wadi of Egypt

(Al-Arish), and turning southward, following the wadi towards the interior. There are

numerous dams crossing the wadi, easily seen from above. Travel would have depended on

the use of scouts who would survey water sources, grazing areas and topography that would

permit travel for such a large group of people.

3. Imagery would benefit exploration in greater Palestine. Radar would readily

detect tells(mounds indicative of] multiple layers of ruins) in the plains. In mountainous

terrain, it would be a question of branching out from confirmed locations and establishing

a 10 mile radius, the idea being that cities depend on smaller, surrounding communities.

Terrain would dictate probable trade routes, water sources, grazing, farming and

supporting infrastructure.

4. Surveying jungles would require terrain analysis and radar to detect stone cities

and temple complexes.[[User:Radical man 7|Radical man 7]] 21:58, 5 January 2007 (UTC)

[[imaging technologies]]

[[photo analysis]]

[[radar]]

[[ultrasound]]

[[infra red]]

[[military intelligence]]

[[tactical intelligence]]

[[military history]]

[[archeology]]

[[User:Radical man 7|Radical man 7]] 23:50, 6 January 2007 (UTC)