Infrared
Infrared homing is a passive weapon guidance system which uses the
infrared (IR) light emission from a target to track and follow it.
Missiles which use infrared seeking are often referred to as
"heat-seekers", since infrared is radiated strongly by hot bodies.
Many objects such as people, vehicle engines and aircraft generate and
emit heat, and as such, are especially visible in the infrared
wavelengths of light compared to objects in the background.
Infrared
Infrared seekers are passive devices, which, unlike radar, provide no
indication that they are tracking a target. This makes them suitable
for sneak attacks during visual encounters, or over longer ranges when
used with a forward looking infrared system or similar cuing system.
This makes heat-seekers extremely deadly; 90% of all United States air
combat losses over the past 25 years have been due to infrared-homing
missiles.[1] They are, however, subject to a number of simple
countermeasures, most notably dropping flares behind the target to
provide false heat sources. This only works if the pilot is aware of
the missile and deploys the countermeasures, and modern seekers have
rendered these increasingly ineffective even in that case.
The first IR devices were experimented with in the pre-World War II
era. During the war, German engineers were working on heat seeking
missiles and proximity fuses, but did not have time to complete
development before the war ended. Truly practical designs did not
become possible until the introduction of conical scanning and
miniaturized vacuum tubes during the war. Anti-aircraft IR systems
began in earnest in the late 1940s, but both the electronics and
entire field of rocketry was so new that it required considerable
development before the first examples entered service in the
mid-1950s. These early examples had significant limitations and
achieved very low success rates in combat during the 1960s. A new
generation developed in the 1970s and 80s made great strides and
significantly improved their lethality. The latest examples from the
1990s and on have the ability to attack targets out of their field of
view (FOV), behind them, and even pick out vehicles on the ground.
The infrared sensor package on the tip or head of a heat-seeking
missile is known as the seeker head. The NATO brevity code for an
air-to-air infrared-guided missile launch is Fox Two.[2]
Contents
1 History
1.1 Early research
1.2 German seekers
1.3 Post-war designs
1.4 Later designs
1.5 MANPADs
2 Seeker types
3 Scanning patterns and modulation
3.1 Linear scan
3.2 Spin-scan
3.2.1 Hamburg system
3.2.2 Later concepts
3.2.3 Conical scan
3.2.4 Crossed array seekers
3.3 Rosette seekers
3.4 Imaging systems
4 Countermeasures
4.1 Flares
4.2 Jammers
5 Tracking
6 See also
7 References
7.1 Citations
7.2 Bibliography
8 External links
History[edit]
Early research[edit]
The Vampir nightscope used a photomultiplier as the sighting system
and provided illumination with an IR lamp mounted above the scope.
The ability of certain substances to give off electrons when struck by
infrared light had been discovered by the famous Bengali polymath
Jagadish Chandra Bose
Jagadish Chandra Bose in 1901, who saw the effect in galena, known
today as lead sulfide, PbS. There was little application at the time,
and he allowed his 1904 patent to lapse.[3] In 1917, Theodore Case, as
part of his work on what became the Movietone sound system, discovered
that a mix of thallium and sulfur was much more sensitive, but was
highly unstable electrically and proved to be little use as a
practical detector.[4] Nevertheless, it was used for some time by the
US Navy
US Navy as a secure communications system.[5]
In 1930 the introduction of the Ag-O-Cs photomultiplier provided the
first practical solution to the detection of IR, combining it with a
layer of galena as the photocathode. Amplifying the signal emitted by
the galena, the photomultiplier produced a useful output that could be
used for detection of hot objects at long ranges.[4] This sparked
developments in a number of nations, notably the UK and Germany where
it was seen as a potential solution to the problem of detecting night
bombers.
In the UK, research was plodding, with even the main research team at
Cavendish Labs
Cavendish Labs expressing their desire to work on other projects,
especially after it became clear that radar was going to be a better
solution. Nevertheless, Frederick Lindemann, Winston Churchill's
favorite on the Tizard Committee, remained committed to IR and became
increasing obstructionist to the work of the Committee who was
otherwise pressing for radar development. Eventually they dissolved
the Committee and reformed, leaving Lindemann off the roster,[6] and
filling his position with well known radio expert Edward Victor
Appleton.[7]
In Germany, radar research was not given nearly the same level of
support as in the UK, and competed with IR development throughout the
1930s. IR research was led primarily by Edgar Kutzscher at the
University of Berlin[8] working in concert with AEG.[4] By 1940 they
had successfully developed one solution; the Spanner Anlage (roughly
"Peeping Tom system") consisting of a detector photomultiplier placed
in front of the pilot, and a large searchlight fitted with a filter to
limit the output to the IR range. This provided enough light to see
the target at short range, and Spanner Anlage was fit to a small
number of
Messerschmitt Bf 110
Messerschmitt Bf 110 and
Dornier Do 17
Dornier Do 17 night fighters. These
proved largely useless in practice and the pilots complained that the
target often only became visible at 200 metres (660 ft), at which
point they would have seen it anyway.[9] Only 15 were built and were
removed as German airborne radar systems improved though 1942.[10]
AEG
AEG had been working with the same systems for use on tanks, and
deployed a number of models through the war, with limited production
of the FG 1250 beginning in 1943.[4] This work culminated in the
Zielgerät 1229
Zielgerät 1229 Vampir riflescope which was used with the StG 44
assault rifle for night use.[11]
German seekers[edit]
The Madrid seeker was being developed for the
Enzian
Enzian surface-to-air
missile.
The devices mentioned previously were all detectors, not seekers. They
produce either a signal indicating the general direction of the
target, or in the case of later devices, an image. Guidance was
entirely manual by an operator looking at the image. There were a
number of efforts in Germany during the war to produce a true
automatic seeker system, both for anti-aircraft use as well as against
ships. These devices were still in development when the war ended;
although some were ready for use, there had been no work on
integrating them with an missile airframe and considerable effort
remained before an actual weapon would be ready for use. Nevertheless,
a summer 1944 report to the
German Air Ministry
German Air Ministry stated that these
devices were far better developed than competing systems based on
radar or acoustic methods.[12]
Aware of the advantages of passive IR homing, the research program
started with a number of theoretical studies considering the emissions
from the targets. This led to the practical discovery that the vast
majority of the IR output from a piston engine aircraft was between 3
and 4.5 micrometers. The exhaust was also a strong emitter, but cooled
rapidly in the air so that it did not present a false tracking
target.[13] Studies were also made on atmospheric attenuation, which
demonstrated that air is generally more transparent to IR than visible
light, although the presence of water vapour and carbon dioxide
produced several sharp drops in transitivity.[14] Finally they also
considered the issue of background sources of IR, including
reflections off clouds and similar effects, concluding this was an
issue due to the way it changed very strongly across the sky.[15] This
research suggested that an IR seeker could home on a three-engine
bomber at 5 kilometres (3.1 mi) with an accuracy of about
1⁄10 degree,[16] making an IR seeker a very desirable device.
Kutzscher's team developed a system with the Eletroacustic Company of
Kiel known as Hamburg, which was being readied for installation in the
Blohm & Voss BV 143 glide bomb to produce an automated
fire-and-forget anti-shipping missile. A more advanced version allowed
the seeker to be directed off-axis by the bombardier in order to
lock-on to a target to the sides, without flying directly at it.
However, this presented the problem that when the bomb was first
released it was travelling too slowly for the aerodynamic surfaces to
easily control it, and the target sometimes slipped out from the view
of the seeker. A stabilized platform was being developed to address
this problem. The company also developed a working IR proximity fuse
by placing additional detectors pointing radially outward from the
missile centerline. which triggered when the signal strength began to
decrease, which it did when the missile passed the target. There was
work on using a single sensor for both tasks instead of two separate
ones.[17]
Other companies also picked up on the work by Eletroacustic and
designed their own scanning methods.
AEG
AEG and Kepka of Vienna used
systems with two movable plates that continually scanned horizontally
or vertically, and determined the location of the target by timing
when the image disappeared (AEG) or reappeared (Kepka). The Kepka
Madrid system had an instantaneous field of view (IFOV) of about 1.8
degrees and scanned a full 20 degree pattern. Combined with the
movement of the entire seeker within the missile, it could track at
angles as great as 100 degrees. Rheinmetall-Borsig and another team at
AEG
AEG produced different variations on the spinning-disk system.[18]
Post-war designs[edit]
The
AIM-4 Falcon
AIM-4 Falcon was the first IR guided missile to enter service. The
translucent dome allows the IR radiation to reach the sensor.
The
AIM-9 Sidewinder
_copy.jpg/600px-AIM_9L_Sidewinder_(modified)_copy.jpg)
AIM-9 Sidewinder closely followed Falcon into service. It was much
simpler than the Falcon and proved far more effective in combat.
Firestreak was the third IR missile to enter service. It was larger
and almost twice as heavy as its US counterparts, much of this due to
a larger warhead.
In the post-war era, as the German developments became better known, a
variety of research projects began to develop seekers based on the PbS
sensor. These were combined with techniques developed during the war
to improve accuracy of otherwise inherently inaccurate radar systems,
especially the conical scanning system. One such system was developed
by the
US Army Air Force
US Army Air Force (USAAF) known as the "Sun Tracker" was being
used as a possible guidance system for an intercontinental ballistic
missile. Testing this system led to the 1948 Lake Mead Boeing B-29
crash.[19]
USAAF project MX-798 was awarded to
Hughes Aircraft
Hughes Aircraft in 1946 for an
infrared tracking missile. The design used a simple reticle seeker and
an active system to control roll during flight. This was replaced the
next year by MX-904, calling for a supersonic version. At this stage
the concept was for a defensive weapon fired rearward out of a long
tube at the back end of bomber aircraft. In April 1949 the Firebird
missile project was cancelled and MX-904 was redirected to be a
forward-firing fighter weapon.[20] The first test firings began in
1949, when it was given the designation AAM-A-2 (Air-to-air Missile,
Air force, model 2) and the name Falcon. IR and semi-active radar
homing (SARH) versions both entered service in 1956, and became known
as the
AIM-4 Falcon
AIM-4 Falcon after 1962. The Falcon was a complex system
offering limited performance, especially due to its lack of a
proximity fuse, and managed a dismal 9% kill ratio in 54 firings
during
Operation Rolling Thunder
Operation Rolling Thunder during the Vietnam War.[21]
In the same year as MX-798, 1946,
William B. McLean
William B. McLean began studies of a
similar concept at the Naval Ordnance Test Station, today known as
Naval Air Weapons Station China Lake. He spent three years simply
considering various designs, which led to a considerably less
complicated design than the Falcon. When his team had a design they
believed would be workable, they began trying to fit it to the newly
introduced Zuni 5-inch rocket. They presented it in 1951 and it became
an official project the next year.
Wally Schirra
Wally Schirra recalls visiting the
lab and watching the seeker follow his cigarette.[22] The missile was
given the name Sidewinder after a local snake, the name was doubly
accurate as the Sidewinder is a pit viper and hunts by heat, and moves
in an undulating pattern not unlike the missile.[23] Sidewinder
entered service in 1957, and was widely used during Vietnam. It proved
to be a better weapon than Falcon, at least in relative terms. B
models managed a 14% kill ratio, while the much longer ranged D models
managed 19% Its performance and lower cost led the Air Force to adopt
it as well.[21][24]
The first heat-seeker built outside the US was the UK's de Havilland
Firestreak. Development began as OR.1056 Red Hawk, but this was
considered too advanced, and in 1951 an amended concept was released
as OR.1117 and given the code name Blue Jay. Designed as an
anti-bomber weapon, Blue Jay was larger, much heavier and flew faster
than its US counterparts, but had about the same range. It had a much
more advanced seeker, using PbTe and cooled to −180 °C
(−292.0 °F) by anhydrous ammonia to improve its performance.
One distinguishing feature was its faceted nose cone, which was
selected after it was found ice would build up on a more conventional
hemispherical dome. The first test firing took place in 1955 and it
entered service with the
Royal Air Force
Royal Air Force in August 1958.[25]
The French R.510 project began later than Firestreak and entered
experimental service in 1957, but was quickly replaced by a
radar-homing version, the R.511. Neither was very effective and had
short range on the order of 3 km, and were replaced by the first
effective design, the R.530, in 1962.[26]
The Soviets introduced their first, the Vympel K-13 in 1961, after
reverse engineering a Sidewinder that stuck in the wing of a Chinese
MiG-17
MiG-17 in 1958 during the Second Taiwan Strait Crisis. The K-13 was
widely exported, and faced its cousin over Vietnam throughout the war.
It proved even less reliable than the AIM-9B it was based on, with the
guidance system and fuse suffering continual failure.[21]
Later designs[edit]
SRAAM
SRAAM was designed to address most of the problems found with earlier
IR missiles in a very short-range weapon.
More than half a century after its introduction, upgraded versions of
the Sidewinder remain the primary IR missile in most western air
forces.
The R-73 was a leap forward for Soviet designs, and cause for
considerable worry among western air forces.
As Vietnam revealed the terrible performance of existing missile
designs, a number of efforts began to address them. In the US, minor
upgrades to the Sidewinder were carried out as soon as possible, but
more broadly pilots were taught proper engagement techniques so they
would not fire as soon as they heard the missile tone, and would
instead move to a position where the missile would be able to continue
tracking even after launch. This problem also led to efforts to make
new missiles that would hit their targets even if launched under these
less-than-ideal positions. In the UK this led to the
SRAAM
SRAAM project,
which was ultimately the victim of continually changing
requirements.[27] Two US programmes,
AIM-82 and AIM-95 Agile, met
similar fates.[28]
New seeker designs began to appear during the 1970s and led to a
series of more advanced missiles. A major upgrade to the Sidewinder
began, providing it with a seeker that was sensitive enough to track
from any angle, giving the missile all aspect capability for the first
time. This was combined with a new scanning pattern that helped reject
confusing sources (like the sun reflecting off clouds) and improve the
guidance towards the target. A small number of the resulting L models
were rushed to the UK just prior to their engagement in the Falklands
War, where they achieved an 82% kill ratio, and the misses were
generally due to the target aircraft flying out of range.[22] The
Argentine aircraft, equipped with Sidewinder B and R.550 Magic, could
only fire from the rear aspect, which the British pilots simply
avoided by always flying directly at them. The L was so effective that
aircraft hurried to add flare countermeasures, which led to another
minor upgrade to the M model to better reject flares. The L and M
models would go on to be the backbone of western air forces through
the end of the
Cold War
Cold War era.
An even larger step was taken by the Soviets with their R-73, which
replaced the K-13 and others with a dramatically improved design. This
missile introduced the ability to be fired at targets completely out
of view of the seeker; after firing the missile would orient itself in
the direction indicated by the launcher and then attempt to lock on.
When combined with a helmet mounted sight, the missile could be cued
and targeted without the launch aircraft first having to point itself
at the target. This proved to offer significant advantages in combat,
and led to great concern in among western forces.[29]
The solution to the R-73 problem was initially going to be the ASRAAM,
a pan-European design that combined the performance of the R-73 with
an imaging seeker. In a wide-ranging agreement, the US agreed to adopt
A
SRAAM
SRAAM for their new short-range missile, while the Europeans would
adopt
AMRAAM
AMRAAM as their medium-range weapon. However, A
SRAAM
SRAAM soon ran
into intractable delays as each of the member countries decided a
different performance metric was more important. The US eventually
bowed out of the program, and instead adapted the new seekers
developed for A
SRAAM
SRAAM on yet another version of the Sidewinder, the
AIM-9X. This so extends its lifetime that it will have been in service
for almost a century when the current aircraft leave service. ASRAAM
did, eventually, deliver a missile that has been adopted by a number
of European forces and many of the same technologies have appeared in
the Chinese PL-10 and Israeli Python-5.
MANPADs[edit]
The Stinger has been used in Afghanistan since 1986. Where it was
provided to the anti Soviet forces by the USA.
Based on the same general principles as the original Sidewinder, in
1955
Convair
Convair began studies on a small man-portable missile (MANPADS)
that would emerge as FIM-43 Redeye. Entering testing in 1961, the
preliminary design proved to have poor performance, and a number of
major upgrades followed. It was not until 1968 that the Block III
version was put into production.[30]
The Soviets started development of two almost identical weapons in
1964, Strela-1 and Strela-2. They seemed to have a much easier time of
it, as the
9K32 Strela-2
9K32 Strela-2 entered service in 1968 after fewer years of
development than the Redeye.[31] Originally a competing design, the
9K31 Strela-1
9K31 Strela-1 was instead greatly increased in size for vehicle
applications and entered service as the around the same time. The UK
began development of their Blowpipe in 1975, but placed the seeker on
the launcher instead of the missile itself. The seeker sensed both the
target and the missile and sent corrections to the missile via a radio
link. These early weapons proved relatively useless, with Blowpipe
failing in almost every combat use,[32] while Redeye fared somewhat
better. The Strela-2 did better and claims a number of victories in
the middle east and Vietnam.[33]
A major upgrade program for Redeye started in 1967, as Redeye II.
Testing did not begin until 1975 and the first deliveries of the now
renamed
FIM-92 Stinger
FIM-92 Stinger began in 1978. An improved rosette seeker was
added to the B model in 1983, and several additional upgrades
followed. Sent to the Soviet–Afghan War, they claimed a 79% success
rate against Soviet helicopters,[34] although this is debated.[35] The
Soviets likewise improved their own versions, introducing the 9K34
Strela-3 in 1974, and the greatly improved dual-frequency
9K38 Igla
9K38 Igla in
1983, and Igla-S in 2004.[36]
Seeker types[edit]
The three main materials used in the infrared sensor are lead(II)
sulfide (PbS), indium antimonide (InSb) and mercury cadmium telluride
(HgCdTe). Older sensors tend to use PbS, newer sensors tend to use
InSb or HgCdTe. All perform better when cooled, as they are both more
sensitive and able to detect cooler objects.
Nag missile
Nag missile with Imaging
Infrared
Infrared (IIR) seeker closeup
Early infrared seekers were most effective in detecting infrared
radiation with shorter wavelengths, such as the 4.2 micrometre
emissions of the carbon dioxide efflux of a jet engine. This made them
useful primarily in tail-chase scenarios, where the exhaust was
visible and the missile's approach toward it was carrying it toward
the aircraft as well. In combat these proved extremely ineffective as
pilots attempted to make shots as soon as the seeker saw the target,
launching at angles where the target's engines were quickly obscured
or flew out of the missile's field of view. Such seekers, which are
most sensitive to the 3 to 5 micrometre range, are now called
single-color seekers. This led to new seekers sensitive to both the
exhaust as well as the longer 8 to 13 micrometer wavelength range,
which is less absorbed by the atmosphere and thus allows dimmer
sources like the fuselage itself to be detected. Such designs are
known as "all-aspect" missiles. Modern seekers combine several
detectors and are called two-color systems.
All-aspect seekers also tend to require cooling to give them the high
degree of sensitivity required to lock onto the lower level signals
coming from the front and sides of an aircraft. Background heat from
inside the sensor, or the aerodynamically heated sensor window, can
overpower the weak signal entering the sensor from the target. (CCDs
in cameras have similar problems; they have much more "noise" at
higher temperatures.) Modern all-aspect missiles like the AIM-9M
Sidewinder and Stinger use compressed gas like argon to cool their
sensors in order to lock onto the target at longer ranges and all
aspects. (Some such as the AIM-9J and early-model R-60 used a peltier
thermoelectric cooler).
Scanning patterns and modulation[edit]
The detector in early seekers was barely directional, accepting light
from a very wide field of view (FOV), perhaps 100 degrees across or
more. A target located anywhere within that FOV produces the same
output signal. Since the goal of the seeker is to bring the target
within the lethal radius of its warhead, the detector must be equipped
with some system to narrow the FOV to a smaller angle. This is
normally accomplished by placing the detector at the focal point of a
telescope of some sort.
This leads to a catch-22 situation. As the FOV is reduced, the seeker
becomes more accurate, and this also helps eliminate background
sources which helps improve tracking. However, limiting it too much
allows the target to move out of the FOV and be lost to the seeker. To
be effective for guidance to the lethal radius, tracking angles of
perhaps one degree are ideal, but to be able to continually track the
target safely, FOVs on the order of 10 degrees or more are desired.
This situation leads to the use of a number of designs that use a
relatively wide FOV to allow easy tracking, and then process the
received signal in some way to gain additional accuracy for guidance.
Generally, the entire seeker assembly is mounted on a gimbal system
that allows it to track the target through wide angles, and the angle
between the seeker and the missile aircraft is used to produce
guidance corrections.
This gives rise the concepts of instantaneous field of view (IFOV)
which is the angle the detector sees, and the overall field of view,
also known as the tacking angle or off-boresight capability, which
includes the movement of the entire seeker assembly. Since the
assembly cannot move instantly, a target moving rapidly across the
missile's line of flight may be lost from the IFOV, which gives rise
to the concept of a tracking rate, normally expressed in degrees per
second.
Linear scan[edit]
Some of the earliest German seekers used a linear-scan solution, where
vertical and horizontal slits were moved back and forth in front of
the detector, or in the case of Madrid, two metal vanes were tilted to
block off more or less of the signal. By comparing the time the flash
was received to the location of the scanner at that time, the vertical
and horizontal angle-off can be determined.[18] However, these seekers
also have the major disadvantage that their FOV is determined by the
physical size of the slit (or opaque bar). If this is set too small
the image from the target is too small to create a useful signal,
while setting it too large makes it inaccurate. For this reason,
linear scanners have inherent accuracy limitations. Additionally, the
dual reciprocating motion is complex and mechanically unreliable, and
generally two separate detectors have to be used.
Spin-scan[edit]
Most early seekers used so-called spin-scan, chopper or reticle
seekers. These consisted of a transparent plate with a sequence of
opaque segments painted on them that was placed in front of the IR
detector. The plate spins at a fixed rate, which causes the image of
the target to be periodically interrupted, or chopped.[37]
Hamburg system[edit]
The Hamburg system developed during the war is the simplest system,
and easiest to understand. Its chopper was painted black on one half
with the other half left transparent.[38]
For this description we consider the disk spinning clockwise as seen
from the sensor; we will call the point in the rotation when the line
between the dark and light halves is horizontal and the transparent
side is on the top to be the 12 o'clock position. A photocell is
positioned behind the disk at the 12 o'clock position.[38]
A target is located just above the missile. The sensor begins to see
the target when the disk is at 9 o'clock, as the transparent portion
of the chopper is aligned vertically at the target at 12 o'clock
becomes visible. The sensor continues to see the target until the
chopper reaches 3 o'clock.[38]
A signal generator produces an AC waveform that had the same frequency
as the rotational rate of the disk. It is timed so the waveform
reaches its maximum possible positive voltage point at the 12 o'clock
position. Thus, during the period the target is visible to the sensor,
the AC waveform is in the positive voltage period, varying from zero
to its maximum and back to zero.[38]
When the target disappears, the sensor triggers a switch that inverts
the output of the AC signal. For instance, when the disk reaches the 3
o'clock position and the target disappears, the switch is triggered.
This is the same instant that the original AC waveform begins the
negative voltage portion of its waveform, so the switch inverts this
back to positive. When the disk reaches the 9 o'clock position the
cell switches again, no longer inverting the signal, which is now
entering its positive phase again. The resulting output from this cell
is a series of half-sine waves, always positive. This signal is then
smoothed out to produce a DC output, which is sent to the control
system and commands the missile to turn up.[38]
A second cell placed at the 3 o'clock position completes the system.
In this case, the switching takes place not at the 9 and 3 o'clock
positions, but 12 and 6 o'clock. Considering the same target, in this
case, the waveform has just reached its maximum positive point at 12
o'clock when it is switched negative. Following this process around
the rotation causes a series of chopped-off positive and negative sine
waves. When this is passed through the same smoothing system, the
output is zero. This means the missile does not have to correct left
or right. If the target were to move to the right, for instance, the
signal would be increasingly positive from the smoother, indicating
increasing corrections to the right. In practice a second photocell is
not required, instead, both signals can be extracted from a single
photocell with the use of electrical delays or a second reference
signal 90 degrees out of phase with the first.[38]
This system produces a signal that is sensitive to the angle around
the clock face, the bearing, but not the angle between the target and
the missile centerline, the angle off (or angle error). This was not
required for anti-ship missiles where the target is moving very slowly
relative to the missile and the missile quickly aligns itself to the
target. It was not appropriate for air-to-air use where the velocities
were greater and smoother control motion was desired. In this case,
the system was changed only slightly so the modulating disk was
patterned in a cardioid which blanked out the signal for more or less
time depending on how far from the centerline it was. Other systems
used a second scanning disk with radial slits to provide the same
result but from a second output circuit.[39]
Later concepts[edit]
AEG
AEG developed a much more advanced system during the war, and this
formed the basis of most post-war experiments. In this case the disk
was pattered with a series of opaque regions, often in a series of
radial stripes forming a pizza-slice pattern. Like the Hamburg, an AC
signal was generated that matched the rotational frequency of the
disk. However, in this case the signal does not turn on and off with
angle, but is constantly being triggered very rapidly. This creates a
series of pulses that are smoothed out to produce a second AC signal
at the same frequency as the test signal, but who's phase is
controlled by the actual position of the target relative to the disk.
By comparing the phase of the two signals, both the vertical and
horizontal correction can be determined from a single signal. A great
improvement was made as part of the Sidewinder program, feeding the
output to the pilot's headset where it creates as sort of growling
sound known as the missile tone that indicates that the target is
visible to the seeker.[40]
In early systems this signal was fed directly to the control surfaces,
causing rapid flicking motions to bring the missile back into
alignment, a control system known as "bang-bang". Bang-bang controls
are extremely inefficient aerodynamically, especially as the target
approaches the centerline and the controls continually flick back and
forth with no real effect. This leads to the desire to either smooth
out these outputs, or to measure the angle-off and feed that into the
controls as well. This can be accomplished with the same disk and some
work on the physical arrangement of the optics. Since the physical
distance between the radial bars is larger at the outer position of
the disk, the image of the target on the photocell is also larger, and
thus has greater output. By arranging the optics so the signal is
increasingly cut off closer to the center of the disk, the resulting
output signal varies in amplitude with the angle-off. However, it will
also vary in amplitude as the missile approaches the target, so this
is not a complete system by itself and some form of automatic gain
control is often desired.[40]
Spin-scan systems can eliminate the signal from extended sources like
sunlight reflecting from clouds or hot desert sand. To do this, the
reticle is modified by making one half of the plate be covered not
with stripes but a 50% transmission color. The output from such a
system is a sine wave for half of the rotation and a constant signal
for the other half. The fixed output varies with the overall
illumination of the sky. An extended target that spans several
segments, like a cloud, will cause a fixed signal as well, and any
signal that approximates the fixed signal is filtered out.[40][37]
A significant problem with the spin-scan system is that the signal
when the target is near the center drops to zero. This is because even
its small image covers several segments as they narrow at the center,
producing a signal similar enough to an extended source that it is
filtered out. This makes such seekers extremely sensitive to flares,
which move away from the aircraft and thus produce an ever-increasing
signal while the aircraft is providing little or none. Additionally,
as the missile approaches the target, smaller changes in relative
angle are enough to move it out of this center null area and start
causing control inputs again. With a bang-bang controller, such
designs tend to begin to overreact during the last moments of the
approach, causing large miss distances and demanding large
warheads.[37]
Conical scan[edit]
A great improvement on the basic spin-scan concept is the conical
scanner or con-scan. In this arrangement, a fixed reticle is placed in
front of the detector and both are positioned at the focus point of a
small
Cassegrain reflector
Cassegrain reflector telescope. The secondary mirror of the
telescope is pointed slightly off-axis, and spins. This causes the
image of the target to be spun around the reticle, instead of the
reticle itself spinning.[41]
Consider an example system where the seeker's mirror is tilted at 5
degrees, and the missile is tracking a target that is currently
centered in front of the missile. As the mirror spins, it causes the
image of the target to be reflected in the opposite direction, so in
this case the image is moving in a circle 5 degrees away from the
reticle's centerline. That means that even a centered target is
creating a varying signal as it passes over the markings on the
reticle. At this same instant, a spin-scan system would be producing a
constant output in its center null. Flares will still be seen by the
con-scan seeker and cause confusion, but they will no longer overwhelm
the target signal as it does in the case of spin-scan when the flare
leaves the null point.[41]
Extracting the bearing of the target proceeds in the same fashion as
the spin-scan system, comparing the output signal to a reference
signal generated by the motors spinning the mirror. However,
extracting the angle-off is somewhat more complex. In the spin-scan
system it is the length of time between pulses that encodes the angle,
by increasing or decreasing the output signal strength. This does not
occur in the con-scan system, where the image is roughly centered on
the reticle at all times. Instead, it is the way that the pulses
change over the time of one scan cycle that reveals the angle.[42]
Consider a target located 10 degrees to the left of the centerline.
When the mirror is pointed to the left, the target appears to be close
to the center of the mirror, and thus projects an image 5 degrees to
the left of the centerline of the reticle. When it has rotated to
point straight up, the relative angle of the target is zero, so the
image appears 5 degrees down from the centerline, and when it is
pointed to the right, 15 degrees to the left.[42]
Since angle-off on the reticle causes the length of the output pulse
to change, the result of this signal being sent into the mixer is
frequency modulated (FM), rising and falling over the spin cycle. This
information is then extracted in the control system for guidance. One
major advantage to the con-scan system is that the FM signal is
proportional to the angle-off, which provides a simple solution for
smoothly moving the control surfaces, resulting in far more efficient
aerodynamics. This also greatly improves accuracy; a spin-scan missile
approaching the target will be subject to continual signals as the
target moves in and out of the centerline, causing the bang-bang
controls to direct the missile in wild corrections, whereas the FM
signal of the con-scan eliminates this effect and improves circular
error probable (CEP) to as little as one metre.[41]
Most con-scan systems attempt to keep the target image as close to the
edge of the reticle as possible, as this causes the greatest change in
the output signal as the target moves. Unfortunately this also often
causes the target to move off the reticle entirely when the mirror is
pointed away from the target. To address this, the center of the
reticle is painted with a 50% transmission pattern, so when the image
crosses it the output becomes fixed. But because the mirror moves,
this period is brief, and the normal interrupted scanning starts as
the mirror begins to point toward the target again. The seeker can
tell when the image is in this region because it occurs directly
opposite the point when the image falls off the seeker entirely and
the signal disappears. By examining the signal when it is known to be
crossing this point, an AM signal identical to the spin-scan seeker is
produced. Thus, for the cost of additional electronics and timers, the
con-scan system can maintain tracking even when the target is
off-axis, another major advantage over the limited field of view of
spin-scan systems.[42]
Crossed array seekers[edit]
The crossed array seeker simulates the action of a reticle in a
con-scan system through the physical layout of the detectors
themselves. Classical photocells are normally round, but improvements
in construction techniques and especially solid-state fabrication
allows them to be built in any shape. In the crossed-array system
(typically) four rectangular detectors are arranged in a cross-like
shape (+). Scanning is carried out identically to the con-scan, which
causes the image of the target to scan across each of the detectors in
turn.[43]
For a target centered in the FOV, the image circles around the
detectors and crosses them at the same relative point. This causes the
signal from each one to be identical pulses at a certain point in
time. However, if the target is not centered, the image's path will be
offset, as before. In this case the distance between the separated
detectors causes the delay between the signal's reappearance to vary,
longer for images further from the centerline, and shorter when
closer. Circuits connected to the mirrors produce this estimated
signal as a control, as in the case of the con-scan. Comparing the
detector signal to the control signal produces the required
corrections.[43]
The advantage to this design is that it allows for greatly improved
flare rejection. Because the detectors are thin from side to side,
they effectively have an extremely narrow field of view, independent
of the telescope mirror arrangement. At launch, the location of the
target is encoded into the seeker's memory, and the seeker determines
when it expects to see that signal crossing the detectors. From then
on any signals arriving outside the brief periods determined by the
control signal can be rejected. Since flares tend to stop in the air
almost immediately after release, they quickly disappear from the
scanner's gates.[43] The only way to spoof such a system is to
continually release flares so some are always close to the aircraft,
or to use a towed flare.
Rosette seekers[edit]
The rosette seeker, also known as a pseudoimager, uses much of the
mechanical layout of the con-scan system, but adds another mirror or
prism to create a more complex pattern drawing out a rosette.[44]
Compared to the fixed angle of the con-scan, the rosette pattern
causes the image to scan to greater angles. Sensors on the drive
shafts are fed to a mixer that produces a sample FM signal. Mixing
this signal with the one from the seeker removes the motion, producing
an output signal identical to that from the con-scan. A major
advantage is that the rosette seeker scans out a wider portion of the
sky, making it much more difficult for the target to move out of the
field of view.[43]
The downside to the rosette scan is that it produces a very complex
output. Objects within the seeker's FOV produce completely separate
signals as it scans around the sky; the system might see the target,
flares, the sun and the ground at different times. In order to process
this information and extract the target, the individual signals are
sent into a computer memory. Over the period of the complete scan this
produces a 2D image, which gives it the name pseudo imager.[43]
Although this makes the system more complex, the resulting image
offers much more information. Flares can be recognized and rejected by
their small size, clouds for their larger size, etc.[44]
Imaging systems[edit]
Modern heat-seeking missiles utilise imaging infrared (IIR), where the
IR/UV sensor is a focal plane array which is able to produce an image
in infra-red, much like the CCD in a digital camera. This requires
much more signal processing but can be much more accurate and harder
to fool with decoys. In addition to being more flare-resistant, newer
seekers are also less likely to be fooled into locking onto the sun,
another common trick for avoiding heat-seeking missiles. By using the
advanced image processing techniques, the target shape can be used to
find its most vulnerable part toward which the missile is then
steered.[45] All western Short-range air-to-air missile such as AIM-9X
Sidewinder and ASRAAM, Chinese PL-10
SRAAM
SRAAM and Israeli Python-5 use
imaging infrared seekers, while Russian R-73 still uses infrared
seeker.
Countermeasures[edit]
There are two primary ways to defeat IR seekers, using flares or IR
jammers.
Flares[edit]
Early seekers did not image the target, and anything within their FOV
would create an output. A flare released by the target causes a second
signal to appear within the FOV, producing a second angle output, and
the chance that the seeker will begin to aim at the flare instead.
Against early spin-scan seekers this was extremely effective because
the signal from the target was minimized through the midcourse, so
even a dim signal from the flare would be seen and tracked. Of course
if this happens, the flare now disappears from view and the aircraft
becomes visible again. However, if the aircraft moves out of the FOV
during this time, which happens rapidly, the missile can no longer
reacquire the target.
One solution to the flare problem is to use a dual-frequency seeker.
Early seekers used a single detector that was sensitive to very hot
portions of the aircraft and to the jet exhaust, making them suitable
for tail-chase scenarios. To allow the missile to track from any
angle, new detectors were added that were much more sensitive and in
other frequencies as well. This presented a way to distinguish flares;
the two seekers saw different locations for the target aircraft - the
aircraft itself as opposed to its exhaust - but a flare appeared at
the same point at both frequencies. These could then be eliminated.
More complex systems were used with digital processing, especially
crossed-array and rosette seekers. These had such extremely narrow
instantaneous fields of view (IFOV) that they could be processed to
produce an image, in the same fashion as a desktop scanner. By
remembering the location of the target from scan to scan, objects
moving at high speeds relative to the target could be eliminated. This
is known as cinematic filtering.[46] The same process is used by
imaging systems, which image directly instead of scanning, and have
the further capability of eliminating small targets by measuring their
angular size directly.
Jammers[edit]
Early seeker systems determined the angle to the target through timing
of the reception of the signal. This makes them susceptible to jamming
by releasing false signals that are so powerful that they are seen
even when the seeker reticle is covering the sensor. Early jammers
like the
AN/ALQ-144
AN/ALQ-144 used a heated block of silicon carbide as an IR
source, and surround it with a spinning set of lenses that send the
image as a series of spots sweeping around the sky. Modern versions
more typically use an infrared laser shining on a rapidly rotating
mirror. As the beam paints the seeker it causes a flash of light to
appear out of sequence, disrupting the timing pattern used to
calculate angle. When successful, IR jammers cause the missile to fly
about randomly.[47]
BAE Venetian Blind Filter for "Hot Brick"
Infrared
Infrared Jammer
IR jammers are far less successful against modern imaging seekers,
because they do not rely on timing for their measurements. In these
cases, the jammer may be detrimental, as it provides additional signal
at the same location as the target. Some modern systems now locate
their jammers on towed countermeasures pods, relying on the missile
homing on the strong signal, but modern image processing systems can
make this ineffective and may require the pod to look as much as
possible like the original aircraft, further complicating the
design.[47]
A more modern laser-based technique removes the scanning and instead
uses some other form of detection to identify the missile and aim the
laser directly at it. This blinds the seeker continually, and is
useful against even modern imaging seekers. These directional infrared
countermeasures (DIRCMs) are very effective, they are also very
expensive and generally only suitable for aircraft that are not
maneuvering, like cargo aircraft and helicopters. Their implementation
is further complicated by placing filters in front of the imager to
remove any off-frequency signals, requiring the laser to tune itself
to the frequency of the seeker or sweep through a range. Some work has
even been put into systems with enough power to optically damage the
nose cone or filters within the missile, but this remains beyond the
current state of the art.[47]
Tracking[edit]
The
Type 91 Surface-to-air missile
Type 91 Surface-to-air missile
MANPAD
MANPAD has an optical seeker
mounted as a means of tracking airborne targets.
Most infrared guided missiles have their seekers mounted on a gimbal.
This allows the sensor to be pointed at the target when the missile is
not. This is important for two main reasons. One is that before and
during launch, the missile cannot always be pointed at the target.
Rather, the pilot or operator points the seeker at the target using
radar, a helmet-mounted sight, an optical sight or possibly by
pointing the nose of the aircraft or missile launcher directly at the
target. Once the seeker sees and recognises the target, it indicates
this to the operator who then typically "uncages" the seeker (which is
allowed to follow the target). After this point the seeker remains
locked on the target, even if the aircraft or launching platform
moves. When the weapon is launched, it may not be able to control the
direction it points until the motor fires and it reaches a high enough
speed for its fins to control its direction of travel. Until then, the
gimballed seeker needs to be able to track the target independently.
Finally, even while it is under positive control and on its way to
intercept the target, it probably will not be pointing directly at it;
unless the target is moving directly toward or away from the launching
platform, the shortest path to intercept the target will not be the
path taken while pointing straight at it, since it is moving laterally
with respect to the missile's view. The original heat-seeking missiles
would simply point towards the target and chase it; this was
inefficient. Newer missiles are smarter and use the gimballed seeker
head combined with what is known as proportional guidance in order to
avoid oscillation and to fly an efficient intercept path.
See also[edit]
Infrared
Infrared countermeasures
Directional
Infrared
Infrared Counter Measures
infra-red search and track
AIM-9 Sidewinder
References[edit]
Citations[edit]
^ Turpin, Lauri (5 February 2009). "Large Aircraft Infrared
Countermeasures-LAIRCM". 440th Airlift Wing, USAF. Archived from the
original on 20 September 2010.
^ MULTISERVICE AIR-AIR, AIR-SURFACE, SURFACE-AIR BREVITY CODES (PDF),
Air Land Sea Application (ALSA) Center, 1997, p. 6, archived from
the original (PDF) on 2012-02-09, retrieved 2008-02-23
^ Mukherj, V (February 1979). "Some Historical Aspects of Jagadls
Chandra Bose's Microwave Research During 1895—1900". Indian Journal
of History of Science Calcutta: 87–104.
^ a b c d Rogalski 2000, p. 3.
^ Fielding, Raymond (1967). A Technological History of Motion Pictures
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Society of Motion Pictures and Television". University of California
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^ Hastings 1999, p. 91.
^ Paterson, Clifford; Clayton, Robert; Algar, Joan (1991). A
Scientist's War: The War Diary of Sir Clifford Paterson, 1939-45. IET.
p. 577.
^ Johnston, Sean (2001). A History of Light and Colour Measurement:
Science in the Shadows. CRC Press. pp. 224–225.
^ Forczyk, Robert (2013). Bf 110 vs Lancaster: 1942-45. Osprey
Publishing. p. 22.
^ Goodrum, Alastair (2005). No Place for Chivalry. Grub Street.
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^ McNab, Chris (2013). German Automatic Rifles 1941-45. Osprey.
pp. 63–64.
^ Kutzscher 1957, p. 201.
^ Kutzscher 1957, p. 204.
^ Kutzscher 1957, p. 206.
^ Kutzscher 1957, p. 207.
^ Kutzscher 1957, p. 210.
^ Kutzscher 1957, p. 215.
^ a b Kutzscher 1957, p. 216.
^ Smith, Julian (October 2005). "Dive Bomber". Smithsonian
Magazine.
^ O'Connor, Sean (June 2011). "Arming America's Interceptors: The
Hughes Falcon
Missile
Missile Family". Airpower Australia.
^ a b c Dunnigan, James; Nofi, Albert (2014). Dirty Little Secrets of
the Vietnam War. Macmillan. pp. 118–120.
^ a b Hollway 2013.
^ Lerner, Preston (November 2010). "Sidewinder". Air and Space
Magazine.
^ Size Knaak, Marcelle (1978). "F-4E". Encyclopedia of US Air Force
aircraft and missile systems. US Air Force History Office, DIANE
Publishing. p. 278.
^ Gibson, Chris; Buttler, Tony (2007). British Secret Projects:
Hypersonics, Ramjets and Missiles. Midland. pp. 33–35.
^ "Matra R.511". Flight International: 714. 2 November 1961.
^ "A
SRAAM
SRAAM - Europe's new dogfight missile". Flight International:
1742. 6 June 1981.
^ "Naval Weapons Center AIM-95 Agile". Flight International: 765. 8
May 1975.
^ "AA-11 ARCHER R-73". FAS. 3 September 2000.
^ Cagle, Mary (23 May 1974). History of the Redeye Weapon System (PDF)
(Technical report). Historical Division, Army
Missile
Missile Command.
^ Jane's Land Based Air Defence 2005–2006.
^ Grau, Lester; Ahmad Jalali, Ali (September 2001). "The Campaign For
The Caves: The Battles for Zhawar in the Soviet-Afghan War". The
Journal of Slavic Military Studies. 14: 69–92.
doi:10.1080/13518040108430488. Archived from the original on
2005-11-13. 13 Blowpipe missiles fired for no hits
^ ""Стрела-2" (9К32, SA-7, Grail), переносный
зенитный ракетный комплекс — ОРУЖИЕ
РОССИИ, Информационное агентство".
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2013-08-24.
^ Bonds, Ray; Miller, David l. Illustrated Directory of Special
Forces. p. 359.
^ Leshuk, Leonard (2008). "Stinger Missiles in Afghanistan".
^ "9K338 9M342 Igla-S / SA-24 Grinch". Globalsecurity.
^ a b c Deuerle 2003, pp. 2401-2403.
^ a b c d e f Kutzscher 1957, p. 212.
^ Kutzscher 1957, p. 214.
^ a b c Chang 1994, pp. 13-14.
^ a b c Deuerle 2003, pp. 2404-2405.
^ a b c Deuerle 2003, p. 2405.
^ a b c d e Deuerle 2003, p. 2407.
^ a b Strickland, Jeffrey (2012).
Missile
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^ Deuerle 2003, pp. 2407-2408.
^ Neri 2006, p. 247.
^ a b c Neri 2006, p. 457.
Bibliography[edit]
Chang, Ting Li (September 1994). The IR
Missile
Missile Countermeasures
(Technical report). Naval Postgraduate School.
Deuerle, Craig (2003). "Reticle Based
Missile
Missile Seekers". In Driggers,
Ronald. Encyclopedia of Optical Engineering. CRC Press.
pp. 2400–2408.
Hollway, Don (March 2013). "Fox Two!". Aviation History.
Kutzscher, Edgar (1957). "The Physical and Technical Development of
Infrared
Infrared Homing Devices". In Benecke, T,; Quick, A,. History of German
Guided Missiles Development. NATO.
Neri, Filippo (2006). Introduction to Electronic Defense Systems.
SciTech Publishing.
Rogalski, Antonio (2000).
Infrared
Infrared Detectors. CRC Press.
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