Title of Invention

AN AIRBORNE RECONNAISSANCE SYSTEM FOR OBTAINING IMAGES FROM AN AREA OF INTEREST

Abstract An airborne reconnaissance system comprising: (1) Gimbals having at least two degrees of freedom; (2) At least one array of light sensors positioned on the gimbals, for being directed by the same within at least two degrees of freedom; (3) Map storage means for storing at least one Digital Elevation Map of an area of interest, divided into portions; (4) Inertial Navigation System for real-time providing to a gimbals control unit navigation and orientation data of the aircraft with respect to a predefined global axes system;(5) Portion selection unit for selecting, one at a time, another area portion from the area of interest; and (6) servo means for directing the gimbals. The system uses data from the inertial navigation system and from the digital elevation map for real-time calculating direction to selected area portions, and for maintaining the direction during integration of light from the terrain, and for producing corresponding images of area portions.
Full Text Field of the Invention
The present invention relates to a system for carrying out airborne
reconnaissance. More particularly, the present invention relates to an airborne
reconnaissance system which comprises one or more arrays of light-sensitive
sensors, such as UV, visible, IR, multi/hyper-spectral, or active illumination,
the line of sight of which being directed by means of gimbals having at least two
degrees of freedom, said system further uses an Inertial Navigation System
(INS) for providing accurate tracking and capturing, and for providing 3D
motion compensation. The sensors and INS are preferably mounted on the
gimbals.
Background of the Invention
Airborne reconnaissance systems have been widely used for many years now,
particularly for obtaining images from the air of areas of interest.
Originally, a film camera was used on board aircraft for capturing the images.
The main problem of the airborne, film-camera based reconnaissance system is
the length of time required for developing the film, an operation that can be
performed only after landing. This problem has been overcome in more modern
systems by the use of a one-dimensional vector or a two-dimensional array of
light-sensitive sensors in the camera for obtaining electronic images that are
then electronically stored within the aircraft, and/or transmitted to a ground

base station. This is generally done in such systems by scanning by the light-
sensitive sensors of the area of interest in the direction of the flight.
Airborne reconnaissance systems are generally used to obtain images of hostile
areas, and therefore the task of obtaining such images involves some particular
requirements, such as:
1. Flying the aircraft at high elevations and speeds in order to reduce the
risk of being targeted by enemy weapons, and in order to widen the area
captured by each image;
2. Trying to capture as much relevant image information as possible during
as short as possible flight;
3. Trying to operate under various visibility conditions, while not
compromising the resolution of the images and their quality.
4. Trying to photograph rough terrains (e.g., high mountains, areas having
sharp ground variations), in high resolution and image quality.
The need for securing the reconnaissance aircraft, while flying above or close
to hostile areas has significantly increased flying costs and risks, as
sometimes the reconnaissance mission requires escorting of the aircraft by
other, fighter aircrafts. Therefore, the need for enabling a short and reliable
mission is of a very high importance.

There are several other problems generally involved in carrying out airborne
reconnaissance. For example, capturing images from a fast-moving aircraft
introduces the need for the so-called Forward Motion Compensation
(Hereinafter, the term "Forward Motion Compensation" will be shortly
referred to as FMC. Motion Compensation in general will be referred to as
MC), to compensate for aircraft movement during the opening of the camera
shutter (whether mechanical or electronic; in the latter case, the opening of
the camera shutter for the purpose of exposure is equivalent to the
integration of light photons by the light-sensitive components).
When light-sensitive sensors are used in the camera (hereinafter, this type of
image capturing will be referred to as "electronic capturing" in contrast to
"film capturing", wherein a film-type camera is used), three major scanning
types are used:
i. The Along-Track Scanning (also known as "push-broom scanning") - In a
first configuration of the Along-Track Scanning, the light-sensitive
sensors are arranged in a one-dimensional vector (row), perpendicular to
the flight direction. The scanning of the imaged area is obtained by the
progression of the aircraft. In one specific configuration of Along-Track
Scanning, generally called Along-Track TDI (Time Delayed Integration)
configuration, a plurality of such parallel one-dimensional vectors (pixel-
rows) perpendicular to the flight direction are provided at the front of the

camera forming a two-dimensional array. In that case, however, the first
row of the array captures an area section, while all the subsequent rows
are used to capture the same section, but at a delay dominated by the
aircraft progression. Then, for each row of pixels, a plurality of
corresponding pixels of all the rows in the array, as separately measured,
are first added, and then averaged in order to determine the pixel
measured light intensity value. More particularly, each pixel in the
image is measured N times (N being the number of rows) and then
averaged. This Along-Track TDI configuration is found to improve the
signal-to-noise ratio, and to improve the image quality and the reliability
of measuring.
ii. The Across-Track Scanning (also known as "Whiskbroom Scanning") - In
the Across-Track Scanning, a one-dimensional sensing vector of light-
sensitive sensors, arranged parallel to the flight direction, is used. The
sensing vector is positioned on gimbals having one degree of freedom,
which, during the flight, repeatedly moves the whole vector right and left
in a direction perpendicular to the direction of flight, while always
keeping the vector in an orientation parallel to the direction of flight.
Another Across-Track Scanning configuration uses a moving mirror or
prism to sweep the line of sight (hereinafter, LOS) of a fixed vector of
sensors across-track, instead of moving the vector itself. In such a case,
the Across-Track Scanning of the area by the gimbal having one degree

of freedom, while maintaining the forward movement of the aircraft,
widens the captured area. Another configuration of the Across-Track
Scanning is the Across-Track TDI configuration. In this configuration
there exists a plurality of vectors (columns) in a direction parallel to the
flight direction, forming a two-dimensional array. This Across-Track TDI,
in similarity to the Along-Track Scanning TDI, provides an improved
reliability in the measuring of pixel values, more particularly, an
improvement in the signal-to-noise ratio,
iii. Digital Framing Scanning: In Digital Framing Scanning, a two-
dimensional array of light-sensitive sensors is positioned with respect to
the scenery. In US 5,155,597 and US 6,256,057 the array is positioned
such that its column-vectors (a column being a group of the array's
columns) are parallel to the flight direction. Forward motion
compensation (FMC) is provided electronically on-chip (in the detector
focal plane array) by the transferring of charge from a pixel to the next
adjacent pixel in the direction of flight during the sensor's exposure time
(also called "integration time"). The charge transfer rate is determined
separately for each column (or for the whole array as in US 6,256,057
where a slit is moved in parallel to the columns direction), depending on
its individual distance (range) from the captured scenery, assuming flat
ground. In WO 97/42659 this concept is extended to handle transferring
of charge separately for each cell instead of column, a cell being a
rectangular group of pixels. In the system of US 5,692,062, digital image

correlation between successive frames captured by each column is
performed, in order to measure the velocity of the scenery with respect to
the array, and the correlation result is used for estimating the average
range of each column to the scenery, for the purpose of motion
compensation in terrain with large variations. This compensation method
requires capturing of three successive frames for each single image, two
for the correlation process and one for the final motion-compensated
frame. The system of US 5,668,593 uses a 3-axis sightline stepping
mechanism for expanding coverage of the area of interest, and it applies
a motion compensation technique by means of transferring of charge
along columns. US 6,130,705 uses a zoom lens that automatically varies
the camera field of view based on passive range measurements obtained
from digital image correlation as described above. The field of view is
tuned in accordance with prior mission requirements for coverage and
resolution.
A significant problem which is characteristic of the prior art reconnaissance
systems, particularly said electronically scanning Across-Track and Along-
Track scanning methods, is the need for predefining for the aircraft an
essentially straight scanning leg (and generally a plurality of such parallel
straight legs), and once such a leg is defined, any deviation, particularly a
rapid or large deviation, from the predefined leg, is not tolerated, as said
systems of the prior art are not capable of mamtaining a desired line of sight

direction during such a fast and/or large deviation from the predefined leg,
resulting in image artifacts such as tearing (dislocation of image lines),
smearing (elongation of pixels) or substantial gaps in the image information.
This is particularly a significant drawback when carrying out a
reconnaissance mission above or close to a hostile area, when the need arises
for the aircraft to carry out fast maneuvering to escape enemy detection or
targeting. Moreover, sometimes, in order to obtain good imaging of a
complicated terrain, such as of a curved canyon, it is best to follow the course
of the sharply curved edges of the canyon. However, in most cases the
reconnaissance systems of the prior art cannot tolerate carrying out such a
sharply curved maneuvering, involving sharp changes in the angles of the
line of sight with respect to the photographed scenery.
Another drawback characteristic of the reconnaissance systems of the prior art,
for example, US 5,155,597, US 5,692,062, WO 97/42659, and US 6,256,057, is
their need to handle vast amounts of data. The systems of the prior art do not
enable an easy, selective imaging of small portions of an area of interest. Once
operated, the system scans the entire area to which the camera is directed, with
essentially no selection of specific portions of the whole possible. Therefore, even
for a small area of interest, the systems of the prior art must handle a huge
amount of data, i.e., be capable of storing the full image data obtained during
the operation of the camera, and transmission of it to the ground (when such an
option is desired). The transmission of a huge amount of data to the ground,

sometimes in real-time, requires usage of a very wide bandwidth. Another
particular problem which evolves from this limitation is the need for
distinguishing and decoding a small data of interest within the said full, huge
amount of data obtained.
Still another drawback of reconnaissance systems of the prior art, for
example, US 5,155,597, US 5,692,062, WO 97/42659, US 6,130,705, and US
6,256,057 is their limited ability to capture images in a wide range of a field
of regard. Hereinafter, the term "field of regard" refers to the spatial section
within which the camera line of sight can be directed without obscuration.
Systems of the prior art sometimes use separate dedicated sensors for
different sight directions (e.g. separate sensors for down-looking, side-oblique
or forward-oblique). The present invention provides to the aircraft the ability
of capturing images, simultaneously from all sensors, of areas forward,
backward, sideways and in any other arbitrary direction, and to rapidly
switch between these directions.
Yet another drawback of reconnaissance systems of the prior art, for
example, US 5,155,597, US 5,668,593, US 5,692,062, WO 97/42659, US
6,130,705, and US 6,256,057 is the use of large-sized two-dimensional
sensors' arrays, which becomes a necessity for systems having limited or no
control over their line of sight. The present invention enables usage of small
or medium-sized, two-dimensional sensors' arrays, by taking advantage of


the capability to quickly and accurately move the LOS within a large field of
regard, to stably fix the LOS on the ground scenery while capturing an
image, and to gather photographic image data by a multitude of
small/medium frames rather than one single large frame at a time. A small-
sized array would typically be up to 1 megapixels (million pixels), and a
medium-sized array would typically be up to 5 megapixels. In contrast, large-
sized arrays would typically be up to 50 megapixels and even larger. An
important feature of the present invention is that both the small and
medium-sized arrays are commercially available as universal sensors' arrays,
not designed specifically for reconnaissance applications but rather for
commercial applications such as stills and video cameras, and therefore they
are widely available from a few vendors at low prices. This sensors'
technology also benefits from the enormous investment by vendors in such
commercial products due to the demands of the commercial market. In
contrast, the large-sized reconnaissance sensors' arrays are uniquely
developed by reconnaissance systems manufacturers, are complex due to the
need for on-chip motion compensation, are expensive, and are not widely
available. The limitations of prior art systems are more acute when the
sensor is required to operate at the IR range rather than at the visible range,
since the current IR array technology does not provide large-sized IR arrays.
Another drawback of large-sized arrays is their lower frame rate with respect
to small/medium-sized arrays, due to the large amount of pixels processed for
each image.


Some of the prior art systems employ on-chip motion compensation, for
example, as described in US 5,155,597, US 5,692,062, and WO 97/42659.
Several drawbacks are associated with the on-chip motion compensation
concept. On-chip motion compensation is performed by transferring charges
from one column/cell to an adjacent column/cell during the integration time at a
specified rate. This process of transferring charges induces electronic noises and
creates an ambiguity (resulting in smearing or loss of pixels) at the borders
between columns/cells and at the edges of the chip, since the required charge
transfer rate may be different between adjacent columns/cells. Some of the prior
art systems assume flat and horizontal ground for estimating the range from
the sensor to each part of the scenery in the captured image (i.e. longer range
for the farther portion of the scenery and shorter range for the closer portion),
and calculate the motion compensation rate based on simple aircraft velocity
and attitude information with respect to the flat ground. When the terrain has
large variations this generally results in substantial smearing as shown in
example 1 of the present invention. In some cases, the sensor must be oriented
during capturing so that its columns are accurately parallel to the flight
direction without rotation, whereby any deviation from that orientation will
result in further smearing, thus seriously limiting mission planning. The more
advanced prior art systems use digital image correlation between successive
frames for each cell in the chip, in order to estimate more accurately the range
to the scenery for each cell. This process requires three successive image


captures for each usable image, thus wasting system duty cycles. The
correlation accuracy is limited by smearing of the first two images when
photographing a terrain with large variations. Another problem associated with
correlation is the large change of aspect angle with respect to the scenery
between the two successive images. For example, an aircraft flying at a velocity
of 250m/s at a range of 15km to the scenery in side oblique, using a chip with 2
Hz frame rate, will have an LOS angular velocity (sometimes called V/R) of
250/15 = 16.7 milirad/s, resulting in an aspect angle between successive images
of 8.3 milirad. For a typical pixel Instantaneous FOV (IFOV) of 30 microrad this
means a shift of 277 pixels in the image. Moreover, since the value of V/R is not
constant at any time during the mission, especially. when the aircraft is
maneuvering, the elapsed time between the two successive images will induce
an additional error.
Some of the prior art systems employ a step framing method to cover large
areas, for example, as described in US 5,668,593. The step framing method
does not provide mechanical/optical fixing of the LOS on the scenery during
exposure time, and has a limited field of regard. On-chip motion
compensation is used, but inaccuracies are induced due to vibrations of the
aircraft, and delays in transferring the measurement of the vibrations to the
reconnaissance system.

It is therefore an object of the present invention to provide a reconnaissance
airborne system capable of tolerating and compensating for very sharp
maneuvers of the aircraft and for large terrain variations, while still
providing high resolution and reliable images of the area of interest, within a
very wide field of regard.
It is still another object of the present invention to provide a reconnaissance
system in which the amount of irrelevant data is significantly reduced,
therefore reducing work needed for distinguishing relevant data from the
fully obtained data, and reducing airborne and ground image storage and
communication requirements.
It is still another object of the present invention to enable the defining of very
small areas of interest within a large area (i.e., a field of regard), of which
images can be obtained.
It is still another object of the present invention to reduce the communication
load between the aircraft and a ground base station, when communicating
images from the aircraft to the ground.
It is still another object of the present invention to provide an airborne
reconnaissance system with the ability to capture images in a wide range of
the angle of sight (i.e., a wide field of regard).

It is still another object of the invention to provide a new and efficient
manner of obtaining the images required for creating stereoscopic-view
images.
It is still another object of the invention to provide the capability of
combining in the same reconnaissance mission both manual mode operation
and automatic mode operation.
Other objects and advantages of the present invention will become apparent
as the description proceeds.
Summary of the Invention
The present invention relates to an airborne reconnaissance system which
comprises: a. Gimbals having at least two degrees of freedom; b. At least one
array of light sensors positioned on the gimbals for being directed by the same
within at least two degrees of freedom; c. Map storage means for storing at least
one Digital Elevation Map of an area of interest, divided into portions; d.
Inertial Navigation System for real-time providing to a gimbals control unit
navigation and orientation data of the aircraft with respect to a predefined
global axes system; e. Portion selection unit for selecting, one at a time, another
area portion from the area of interest; f. Servo control unit for:

A. Receiving from said Digital Elevation Map one at a time, a
coordinates set of the selective area portion, said set comprising the
x:y coordinates of said area portion and the elevation z of the
center of that portion;
B. Receiving continuously from said inertial navigation system present
location and orientation data of the aircraft;
C. Repeatedly calculating and conveying into a gimbals servo unit in
real time and at a high rate signals for:
a. during a direction period, signals for directing accordingly the
gimbals including said LOS of at least one array of light-sensing
units towards said x : y: z coordinates of the selected area portion,
and;
b. during an integration period in which the array sensors
integrate light coming from the area portion, providing to the
gimbals unit signals for compensating for the change in direction
towards the x:y:z coordinates of the selected portion evolving from
the aircraft motion;
g. Gimbals servo for effecting direction of the gimbals in at least two degrees of
freedom according to the signals provided from said Servo Control Unit; h.
Sampling means for simultaneously sampling at the end of the integration
period pixel levels from each of said array sensors, a set of all of said sampled
pixel levels forms an image of said area portion; and i. Storage means for
storing a plurality of area portion images.


Preferably, said one or more arrays are selected from at least a visual light-
sensitive array, a UV light sensitive-array, an infrared light-sensitive array, a
multi/hyper-spectral array, and an active illumination array.
Preferably, said navigation data of the aircraft comprises data relating to the
3D location of the aircraft, and its velocity and acceleration vectors with respect
to a predefined coordinates system, and its orientation data relating to the
orientation of the aircraft with respect to said predefined coordinate system.
Preferably, said Inertial Navigation System comprises velocity, acceleration,
and orientation sensors, at least some of said sensors being positioned on the
gimbals.
Preferably, at least some of said arrays of sensors are positioned on the gimbals.
Preferably, the system uses two Inertial Navigation Systems, the first inertial
navigation system being the main Inertial Navigation System of the aircraft
and its sensors being positioned within the aircraft, and the second Inertial
Navigation System being an a system dedicated to the reconnaissance system,
at least some of the sensors of said second Inertial Navigation System being
positioned on the gimbals unit, measuring navigation and orientation data of
the gimbals with respect to the said predefined axes system, for better

eliminating misalignments occurring between the gimbals and LOS and the
said main Inertial Navigation System of the aircraft due to aero-elastic
deflections and vibrations of the aircraft, by using a process of transfer
alignment from the said first INS to the said second INS.
Preferably, the Digital Elevation Map is a map comprising a grid of the area of
interest, the x: y: z coordinate values at each of the nodal points in said grid
being provided by said map.
Preferably, the portion selecting unit is used for calculating and determining a
center of a next area portion such that provides a predefined overlap between
the said imaged area portion and the adjacent previously imaged area portion.
Preferably, in an automatic mode of operation the gimbals are activated to
cover in a sequential, step-wise manner, the area of interest, said coverage is
made from a predefined starting portion and according to a stored mission plan,
thereby sequentially scanning one after the other area portions of the area of
interest, and sampling images from each of said portions.
Preferably, in a manual mode of the system the pilot of the aircraft defines an
area of interest during the flight, said area of interest being automatically
divided into at least one area portion, all the area portions being automatically

scanned one after the other by means of correspondingly directing to them the
on-gimbals array, for capturing images of each of said scanned portions.
Preferably, the gimbals comprise two gimbals mechanisms, an external gimbals
mechanism and an internal gimbals mechanism.
Preferably, the external gimbals mechanism is used for coarse directing the on-
gimbals array to the center of a selected area portion.
Preferably, the external gimbals mechanism has two degrees of freedom,
elevation and roll.
Preferably, the internal gimbals mechanism is used for fine directing the on-
gimbals array to the center of a selected area portion, particularly for
compensating the gimbals direction for the aircraft motion and orientation
change during the integration period.
Preferably, the internal gimbals mechanism has two degrees of freedom, yaw
and pitch.
Preferably, the external gimbals mechanism is slaved to the internal gimbals
mechanism.

Preferably, during the integration period each of the array sensors
simultaneously senses light from a corresponding section of the area portion,
and at the end of the integration period the data from all the array sensors is
read simultaneously, and stored as an image of the area portion.
Preferably, the arrays of light sensors are sensitive to light in the range of
visual light, IR, UV, multi/hyper-spectral, and/or an active illumination.
Preferably, the arrays are focal plane arrays.
Preferably, the predefined axes system is a global axes system.
In one embodiment of the invention, the system of the invention is assembled
within a pod attached to the aircraft.
In another embodiment of the invention, the system of the invention is
assembled within a payload installed inside the aircraft with only its windows
protruding for obtaining a clear, unobstructed Line Of Sight.
Preferably, the gimbals are located at the front of the pod, behind a transparent
window.

In an embodiment of the invention, the system further comprising a back-
scanning mechanism comprising a mirror or prism, positioned on the gimbals
and rotatable with respect thereto, light coming from the area portion first
passing through said mirror which deflects the same towards the array, and: a.
the servo control unit applies to the gimbals a continuous row and/or column
scanning movement without stopping; and b. while the direction towards an
area portion is being established, applying to said back-scanning mirror during
the integration period an opposite direction movement with respect to said row
and/or column scanning continuous movement, thereby compensating for that
continuous movement and ensuring a fixed orientation relationship of the array
with respect to the area portion imaged.
The invention further relates to a method for carrying out airborne
reconnaissance, which comprises: a. Providing at least one array of light-
sensitive pixels; b. Mounting the at least one array on gimbals having at least
two degrees of freedom so that the gimbals can direct the array to a selected
Line Of Sight; c. Providing a Digital Elevation Map of an area of interest,
reconnaissance images from said area are to be obtained; d. Providing an
Inertial Navigation System for obtaining at any time during the flight the
updated xa: ya : za coordinates of the center of the array with respect to a
predefined coordinates system; e. Providing a calculation unit for, given xp : y
location coordinates of a center of specific area portion within the area of
interest, and the zp elevation coordinate at said portion center as obtained from

said Digital Elevation Map, and the said xa:ya: za coordinates of the array
center at same specific time, determining the exact angles for establishing a
line of sight direction connecting between the center of the array and the said
XP '■ yP '■ ZP coordinates; f. Given the calculation of step e, directing accordingly
the center of the array's Line Of Sight to the center of the area portion; g.
During an integration period, effecting accumulation of light separately by any
of the array light sensors; h. During the integration period, repeating at a high
rate the calculation of step e with updated array xa : ya : za coordinates, and
repeatedly, following each said calculation, correcting the direction as in step f;
i. At the end of the integration period, sampling all the array sensors, and
saving in a storage as images of the array portion; j. Selecting new portion
coordinates x : y : zp within the area of interest, and repeating steps e to j for
these new coordinates; and, k. When the coverage of all the area of interest is
complete, terminating the process, or beginning coverage of a new area of
interest.
Preferably, the selection of xp :yp coordinates of a new area portion is
performed to assure overlap between adjacent area portions within a predefined
range, by calculating the 3-dimensional footprint of the new area portion on the
ground, and then projecting it on the footprint of a previous area portion.

Preferably, the overlap assurance is obtained by a trial and error selection,
overlap calculation, and correction when necessary, or by an exact analytical
calculation.
Preferably, at least some of the sensors of the Inertial Navigation System are
positioned on the gimbals, for improving the measuring of the orientation of the
array with respect to the selective area portion.
Preferably, at least some of the light sensitive sensors are positioned on the
gimbals, for improving the measuring of the orientation of the Line Of Sight
with respect to the selective area portion.
Preferably, the Inertial Navigation System comprises a dedicated Inertial
Navigation System of the reconnaissance system and the main Inertial
Navigation System of the aircraft, to improve the measuring of the orientation
of the array with respect to the selective area portion, by using a process of
transfer alignment from the aircraft Inertial Navigation System to the
dedicated reconnaissance system's Inertial Navigation System.
The invention further relates to a method for providing motion compensation
during airborne photographing which comprises: a. Providing at least one
array of light-sensitive pixels; b. Mounting the at least one array on gimbals
having at least two degrees of freedom so that the gimbals can direct its Line Of

Sight towards a selective area portion; c. Providing a Digital Elevation Map of
an area of interest, reconnaissance images from said area are to be obtained; d.
Providing an Inertial Navigation System for obtaining at any instant during
flight the updated xa: ya: za coordinates of the center of the array with respect
to a predefined coordinates system; e. Providing a calculation unit for, given
xp : yp location coordinates of a center of specific area portion within the area of
interest, and the zp elevation coordinate at said portion center as obtained from
said Digital Elevation Map, and the said xa : ya : za coordinates of the array
center at same specific time, determining the exact angles for establishing a
line of sight direction connecting between the center of the array and the said
xp : yp : zp coordinates; f. During an integration period, when the center of the
array's Line Of Sight is directed to a center of an area portion effecting
accumulation of light separately by any of the array light sensors; g. During
the integration period, repeating at a high rate the calculation of step e with
updated array xa :ya :za coordinates, and repeatedly, following each said
calculation, correcting the direction by keeping the center of the array directed
to the center of the selected area portion, therefore compensating for aircraft
movement; and h. At the end of the integration period, sampling all the array
sensors, and saving in a storage as images of the array portion.
The invention further relates to a method for carrying out airborne targeting,
which comprises:


a. Providing at least one weapon;
b. Mounting the at least one weapon on gimbals having at least two degrees of
freedom so that the gimbals can direct the weapon to a selected Line Of Sight;
c. Providing a Digital Elevation Map of an area of interest, selected targets
within said area are to be obtained;
d. Providing an Inertial Navigation System for obtaining at any time during
the flight the updated xa : ya : za coordinates of the center of the weapon with
respect to a predefined coordinates system;
e. Providing a calculation unit for, given xp : yp location coordinates of a center
of specific target within the area of interest, and the zp elevation coordinate at
said target center as obtained from said Digital Elevation Map, and the said
xa '■ ya '■ za coordinates of the weapon center at same specific time, determining the
exact angles for establishing a Line of Sight Direction connecting between the
center of the weapon and the said x : v : zp coordinates;
f. Given the calculation of step e, directing accordingly the center of the weapon
Line Of Sight to the center of the target;
h. During the effective targeting and shooting period, motion compensating for
the motion of the aircraft.
The motion compensation of the targeting can be made in any conventional
manner known in the art. According to an embodiment of the present invention
the motion compensation of step h is carried out by repeating at a high rate the

calculation of step e with updated target xa: yg: za coordinates, and repeatedly,
following each said calculation, correcting the direction as in step f.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS(S)
In the drawings:
- Fig. 1 shows a general structure of a reconnaissance system, assembled
within a pod, according to one embodiment of the invention;
- Fig. 1A shows another embodiment of the invention. In this configuration
the reconnaissance system is assembled as a payload into the aircraft
body.
Fig. 2 shows the mechanical structure of a gimbals system according to
one embodiment of the invention;
- Fig. 3 illustrates several modes of operation, typical to the system of the
invention;
- Fig. 3A shows an area of interest divides into a plurality of area portions,
according to an embodiment of the invention;
- Fig. 3B illustrates several staring modes which are possible by the system
of the invention;
- Fig. 4 is a block diagram illustrating the operation of the reconnaissance
system of the invention;
- Fig. 5 is a flow diagram describing the operation principles of the
reconnaissance system of the invention;


- Fig. 6 shows the structure of the INS system of the invention, which
comprises the main INS of the aircraft, and the dedicated INS of the
reconnaissance system of the invention;
- Fig. 7 shows how a stereoscopic image is constructed by the system of the
present invention;
- Fig. 8 illustrates a specific case in which a system of the prior art is
required to carry out a reconnaissance mission;
- Fig. 8A illustrates how the system of the present invention carries out the
same reconnaissance mission of Fig. 8A;
- Fig. 9 exemplifies the significance of the elevation factor when carrying
out a reconnaissance mission, and more particularly shows the
importance of considering directly and in real-time the elevation of the
imaged terrain;
- Fig. 10 illustrates the use of a back-scanning mirror in accordance with
the system of the present invention;
- Fig. 11 is a perspective illustration of a billy terrain, and its division into
area portions, including some overlap between area portions, as
performed by the system of the present invention;
- Fig. 11A shows an upper view of the terrain of Fig. 11, and the manner of
scanning of the said terrain by the airborne reconnaissance system of the
present invention; and


- Fig. 12 is an example illustrating how the system of the present invention,
can photograph selective targets, thereby significantly reducing the
amount of data handled;
Detailed Description of Preferred Embodiments
A preferred embodiment, of the reconnaissance system of the present
invention is particularly characterized by the following main features:
i. The one or more focal plan arrays that are used to sense and capture
images from an area of interest have a Hne of sight (LOS) that is directed
by gimbals having at least two degrees of freedom. The term 'gimbals',
when used herein, refers to any type of mechanism, whether mechanical,
optical (such as one including mirrors, prisms, etc.) or a combination
thereof, which is capable of moving a line of sight of an array of light-
sensitive sensors in at least two degrees of freedom. A mechanical
mechanism is sometimes called 'payload-stabilized gimbals'; an optical
mechanism is sometimes called 'mirror-stabilized gimbals'. One of said
arrays may sense in the visual range, and another may sense, for
example, in the IK, range, and/or the UV range. In another case, a
multi/hyper spectral array or an active illumination array may be used.
Hereinafter, throughout this application, the term "array" refers to any
type of array of light-sensing means for obtaining an image from an area
of interest. The arrays used in the invention may be of small or medium
size, rather than large arrays which are used in prior art systems as are
used in US 5,155,597, WO 97/42659, and US 6,256,057, taking advantage

of the flexibility of the system in taking many snapshots at arbitrary line
of sight directions, and with sharply varying terrain conditions. The
preferred mounting of the sensors' arrays and their optics, when payload-
stabilized gimbals are used, is on the gimbals; in case of mirror-stabilized
gimbals, the sensors are mounted off the gimbals.
ii. The reconnaissance system uses an Inertial Navigational System (INS)
for continuously calculating the direction of the line of sight. In a
preferable case, two INS systems are used: the first one is the main INS of
the aircraft, and the second INS is an internal, dedicated INS of the
system mounted in the reconnaissance system. The reconnaissance
system of the invention continuously receives from the said Inertial
Navigation Systems both navigational information regarding the location
of the aircraft with respect to a fixed, predefined global axes system, and
orientation information of the aircraft with respect to the ground, for
point-directing the one or more arrays positioned on the gimbals to any
desired area portion on the ground within the field of regard of the
aircraft. The preferred mounting of the system INS is on the gimbals,
whether payload-stabilized or mirror-stabilized gimbals.
iii. The gimbals having at least two degrees of freedom, on which the arrays
are preferably mounted, in one mode of the invention are systematically
activated in a step-wise manner for sequentially scanning one after the

other area portions of an area of interest, within a very large field of
regard.
iv. The system of the invention captures by its arrays, when activated, a
snap-shot, two-dimensional image of an area portion, enabling long
exposure times due to the compensation of the line of sight motion;
v. When directed to an area portion, three-dimensional motion compensation
is provided by means of adjusting the gimbals to keep track with the
relevant area portion by means of data provided from the INS, and from a
Digital Elevation Map of the area of interest, which is pre-stored in the
reconnaissance system of the invention; and
vi. In a preferable case, the division of the area of interest into area portions
is performed in real-time, wherein the size of each area portion depends
on several parameters, such as the shape of the terrain, and the range
from the aircraft to the center of the area of interest, as determined from
the Digital Elevation Map (DEM), particularly for assuring proper overlap
between images of area portions.
The above main features, as well as other structural features of the invention,
will become apparent as the description proceeds.

As said, reconnaissance systems of the prior art of the Along-Track or Across-
Track scanning type, relate to the accumulated data of a specific leg as an
essentially one-piece data. More particularly, once a leg is defined, while the
aircraft flies along the leg, the accumulated data is essentially stored as one
huge image file. Later, it is up to the operator to distinguish specific relevant
data from this image. Furthermore, any airborne reconnaissance system must
deal with the problem of motion compensation. As this latter problem is
complicated, the solution provided in systems of the prior art do not allow for
sharp maneuvering of the aircraft during the reconnaissance mission. The
present invention provides a solution to said two problems in a compact and
efficient manner.
The reconnaissance system of the present invention is particularly adapted to
be carried by a fighter aircraft, where environmental conditions, maneuvering
dynamics, system size, aerodynamic limitations, and angular aspects with
respect to the ground are extreme; however, the system is also suitable for
other airborne platforms. In a preferable case, the system is assembled within a
pod or a payload that is generally carried below the aircraft wing or fuselage.
Because of the extreme operating conditions of a fighter aircraft, systems of the
prior art, for example as disclosed in US 5,668,593 sometimes use a mirror to
direct the LOS, a solution which limits the FOR substantially since a mirror
essentially folds the LOS to point at a certain direction with relatively small
angular variations. In the present invention the LOS is directed by means of

the gimbals, a solution that enables a very wide field of regard since gimbals
can be rotated towards any direction.
Fig. 1 shows the general structure of a reconnaissance system, assembled
within a pod, according to one embodiment of the invention. The pod 1
comprises in its forward section 10 gimbals (not shown) carrying light-sensing
arrays and the necessary optics (not shown). The said gimbals and optics are
mounted behind a transparent window 12. At least one of such arrays exists, for
example, in a CCD-type array, or a focal plan array for sensing light in the
visual range. Optionally, more arrays may be included, for example, an IR
array for sensing and capturing an image in the IR range. The plurality of
arrays, when used, as well as the INS, are positioned on the same portion of the
gimbals in such a manner as to be directed to, and cover exactly a same area
portion. Optionally, in a less preferred embodiment, the sensors and/or INS
may be located behind the gimbals, while the gimbals carry a set of mirrors
and/or prisms that folds the LOS towards the sensors. The system further
comprises an Image Handling Unit (IHU) 2 that processes the digital image
information from the sensors, compresses the images, and combines them with
mission data to facilitate later interpretation in the ground station, a Solid
State Recorder (SSR) 3 or a similar fast-access storing device for storing a
Digital Elevation Map (DEM) of the area of interest and a mission plan, and for
recording the captured images. The system further comprises a Servo Unit (SU)
for providing control and power signals to the gimbals servo, and an Interface

Unit (IU) for enabling power interfaces with the aircraft. Other computer
system and control electronics is included within the System Electronics Unit
(SEU). Optionally, a Data Link 16 (DL) is used to transmit images and mission
data to a ground station for near real-time interpretation. The pod is attached
to the aircraft by means of lugs 11.
Fig. 1A shows another embodiment of the invention. In this configuration the
reconnaissance system is assembled as a payload into the aircraft body. The
Forward Section is positioned vertically and is pointing down, with only its
windows protruding outside the aircraft body. The same electronic units as in
the pod configuration are installed inside the aircraft body. Although this
solution may be used by a fast jet aircraft, its main objective is for other types
of aircraft such as helicopters, KPVs (remotely piloted vehicles), and command
& control aircrafts.
Fig. 2 shows the mechanical structure of the gimbals system 20, according to a
preferred embodiment of the invention. The progression direction of the aircraft
is indicated by numeral 27. As said, in order to carry out reconnaissance, the
gimbals system according to the present invention has at least two degrees of
freedom. The direction of the gimbals' axes and the gimbals' order are not
important, provided they are capable of steering the LOS towards any spatial
direction within their specified field of regard.

According to a preferred embodiment of the invention shown in Fig. 2, the
gimbals system 20 comprises two sub-mechanisms, as follows:
Internal gimbals mechanism 36, having two degrees of freedom, Yaw
(rotation around axis 22) and Pitch (rotation around axis 21); and
External gimbals mechanism 37, having two degrees of freedom,
elevation (rotation around axis 21) and roll (rotation around axis 23).
The Pitch and the Elevation degrees of freedom relate essentially to a rotation
about a same axis 21. However, the Pitch degree of freedom relates to a fine
rotation by the internal gimbals mechanism 36, while the Elevation degree of
freedom relates to a coarse rotation of the external gimbals mechanism 37. The
external gimbals mechanism 37 is preferably slaved to the internal gimbals
mechanism 36. Slaving is the process by which the internal gimbals are the
prime gimbals to which LOS steering commands are directed, while the
external gimbals are compensating for the internal gimbals' limited angular
rotation by following the movement of the internal gimbals, always trying to
minimize the angular displacement between the internal and external gimbals.
Although tracking to any specific point in front and below the pod is possible by
means of two degrees of freedom, the separation into two sub-mechanisms is
made in order to obtain a better tracking precision and wider field of regard.
The external gimbals mechanism is particularly used for coarse tracking, for
example, for transferring the direction of the gimbals from one area portion to a
second area portion, while the internal gimbal mechanism is particularly used

for providing motion and orientation compensation, while capturing an image of
a specific area portion. Other gimbals' arrangements, with different number of
gimbals or different direction of axes, may also achieve these goals.
As said, the external gimbals facilitate expansion of the field of regard (FOR).
The limits of the FOR for a pod embodiment are indicated on Figure 1. This
FOR is achieved by the ability of the external elevation gimbals to look
backward as well as forward, combined with the ability of the roll gimbals to
rotate a full turn of 360 degrees. The limits of the FOR for a payload
embodiment are indicated on Figure 1A. This FOR is achieved by the ability of
the external elevation gimbals to look sideways as well as downward, combined
with the ability of the roll gimbals to rotate a full turn of 360 degrees. The only
limitation to the FOR in both embodiments are the pod body and aircraft body,
which obscure the line of sight at the edges of the FOR envelop.
In the preferred embodiment of the invention of Fig. 2, the one or more arrays
are mounted on the internal gimbal, to provide fine adjustment of the array
towards a specific portion of an area of interest. This is required, for example, to
provide motion and orientation compensation.
As said, the one or more arrays of sensors, together with their associated optics,
are positioned on the gimbals to maintain at least two degrees of freedom. In
the embodiment of Fig. 2, an exemplary focal plane array 24 capable of

capturing images in the visual range, is symbolically indicated. The boundaries
of the sensor's field of view (FOV) are symbolically indicated by numerals 25,
and the scene captured by the array is symbolically indicated by numeral 26.
According to the present invention, when the scene 26 is a selected area portion,
the gimbals system directs the center of array 24 towards center 29 of area
portion 26, the line connecting the center of the array to the center of the
selected area portion will be referred to herein as 'line of sight" (LOS). The
sensors' optics may be either separate optics for each sensor, or shared optics
for all/some of the sensors. Shared optics collects hght in a multi-spectral range
and then splits it to each of the sensors according to its unique spectral
waveband. The use of separate versus shared optics will depend on the specific
design goals, taking into consideration available space and required
performance, modularity and maintainability.
Inertial Navigation Systems are well known in the art, and are widely used in
aircraft and in airborne systems for determining with high precision in flight
the aircraft or airborne-system location, its velocity and acceleration vectors,
and its orientation with respect to a stationary, global axes system. The
Inertial Navigation System comprises essentially two separate units (i.e
functions), a Navigational Unit, for determining the location coordinates of the
aircraft or airborne-system, and an Inertial Unit for determining, among
others, the aircraft or airborne-system orientation with respect to a predefined,
fixed, and generally global coordinate system. The INS may also provide the

velocity and acceleration vectors of the aircraft or airborne-system. The
Navigational System may use, for example, GPS information, and the Inertial
Unit generally uses inertial sensors within the aircraft or airborne-system.
Sometimes, a less accurate INS in an airborne system is communicating with a
more accurate INS in the aircraft, and aligns itself continuously to the aircraft
INS by using data received from it. The process is called 'transfer alignment',
and is used by many systems to align two INS's (e.g. to align a missile's INS
before dropping it from the aircraft). Once aligned, the less accurate INS
further calculates independently the line of sight direction (angles) with respect
to a global reference system, until the next alignment occurs.
According to a preferred embodiment of the invention, the reconnaissance
system may have various modes of operation, deriving from its capability to
direct the LOS towards any desired direction with the system's field of regard.
Referring to Fig. 3B, the LOS directions may be side-oblique, forward-oblique,
down-looking or arbitrary. Referring to Fig. 3, the following modes of operation
may typically be used:
i. Path Mode: Images are captured along the flight path of the aircraft, with
the line of sight directed forward oblique, down looking or side oblique. The
path trajectory follows the actual aircraft flight path.
ii. Strip Mode: A linear strip positioned along the flight path, or at an angle to
it, is captured. In this mode the line of sight is usually directed side oblique.

iii. Spot Mode: Images of a selected area are captured. In this mode the line of
sight may be directed in any arbitrary direction,
iv. Staring Mode: Images of the same selected area are taken successively. In
this mode the line of sight may be directed in any arbitrary direction.
In the last three modes, when the aircraft is approaching the selected area, the
entrance observation angle may be any angle (i.e. start capturing well before
arriving), and when the aircraft is leaving the selected area, the exit
observation angle may be any angle (i.e. stop capturing well after leaving).
This way, the reconnaissance system may linger more time on the selected
area.
Basically, the reconnaissance system may work at either automatic mode or
manual mode, and combine both in the same mission. In automatic mode, the
reconnaissance system provides automatic acquisition of reconnaissance
imagery of preplanned targets and targets of opportunity. The modes selected
for the system may contain any combination of path, strip, spot, and staring
modes. Based on the mission plan, the system automatically configures the
sensors as the aircraft approaches the targets' area, activates the selected
sensors, controls the sensors' direction, and initiates/terminates recording and
transmission of image data. The planning of the mission is done in advance at
the ground station, and is uploaded to the system prior to the mission. In
manual mode, the operator can manually change the mission plan during

flight. The operator may interrupt an automatic operation and perform
reconnaissance functions manually. All modes of operation may be available in
both automatic and manual modes.
Referring to Figs. 3 and 3A, according to a preferred embodiment of the
invention, an area of interest is divided into a matrix of a plurality of area
portions. For example, area 100, which is defined by points A, B, C, and D, is
divided into a matrix of a plurality of area portions, for example, portions Pi.i,
Pi,2, Pi,3, P2,i, P2,2, P2,3,..Pn,m, wherein the first subscripted number indicates
the portion column within the matrix, and the second subscripted number
indicates the portion row within the matrix area. Area 100 may assume any
arbitrary quadrangular shape as desired by the mission plan. The size of the
area portions Pn,m varies in accordance with the sensors' FOV and range to the
scene of each area portion. In some cases, and as will be elaborated later, the
area matrix is defined in such a manner that area portions partially overlap one
another, as is shown in Fig. 11, for example, by about 10-20% of their area in
order to assure full coverage of the area of interest, even when the area is a
sharply changed terrain. When stereo photography is required, an overlap
larger than about 56% is required. During the aircraft 102 flight, the gimbals of
the reconnaissance system scan the area matrix 100 in a sequential,
systematic, step-wise manner, by which the gimbals first direct the imaging
array of it to a first area portion and capture its image simultaneously in all
sensors, then to a second area portion to capture its image, and then, repeating

this procedure, the gimbals sequentially "jump" the line of sight and field of
view of the array through all the other portions, until completely capturing
images of all the portions of the area of interest 100. For example, the system
may scan the exemplary 9-portion matrix 100 in the following order:
When the gimbals of the system direct
the light-sensitive array to a specific area portion, generally by directing the
center of the array towards the center of the specific area portion and locking
(i.e fixing the LOS) on it, a "snapshot" is taken, capturing the image of this area
portion. More particularly, the "snap shooting" involves two stages, a light
integration stage during which light from the area of interest is sensed by
components of the array, and a sampling stage during which all the components
of the array are simultaneously sampled at the end of the integration period. As
said, this procedure is sequentially and systematically repeated for all the area
portions of the area 100. Each time an image of a portion is captured, it is saved
in a storage at the reconnaissance system (such as the Solid State Recorder 3 of
Fig. 1), and optionally also transmitted to a ground base station (not shown)
using a Data Link (DL). In order to provide accurate capturing of the image,
location and navigation data are provided in real-time to the gimbals control
unit by the INS.
Fig. 4 is a block diagram illustrating the operation of the reconnaissance system
of the invention. As said, the operation of the system involves three main

phases. At the first phase, the line of sight of the array is directed towards a
selected area portion. At the second phase, the array is "exposed" to light
coming from the area portion, and charge is integrated correspondingly within
the array components. During said second phase, motion compensation is
provided by moving the line of sight with the gimbals, in order to compensate
for the aircraft motion and change of orientation during the exposure
(integration) period, particularly in order to eliminate smearing. At the end of
the integration period, at the third phase, all the array light-sensitive sensors
are simultaneously sampled, and the image is stored. Before takeoff, a Digital
Elevation Map 310 of an area, which includes within it at least the area of
interest, is stored at the reconnaissance system. The Digital Elevation Map 310
is a digital file reflecting a map divided into a grid, wherein for each nodal point
of the grid, the x-y coordinates (with respect to a global or predefined
coordinates system) and the elevation z at that point are provided. The portion
selection block 311 selects an area portion. More particularly,' the portion
selection block 311 sequentially indicates a nodal point being a center of a
selected area portion within the DEM 310, causing the DEM 310 to convey the
coordinates of the center of the area portion to the servo control unit 305. The
concept of finding the 3D center coordinates of a selected target using a DEM,
as described in the present invention, can also be used in systems other than
reconnaissance systems, such as targeting systems, where sometimes it is
desired to measure the exact range to the scene or a selected target without
employing active range finders. Preferably, and as will be elaborated later,

several selection modes exist for selecting an area portion, and determining its
borders, or more particularly, determining its central nodal point. The xp: yp
coordinates of the center point of the selected area portion, and the elevation
coordinate zp of the same point are conveyed to the servo control unit 305. The
area portion direction module 306 of the servo control unit also periodically
receives from the INS 303 the xa : y a: za coordinates of the center of the on-
gimbals array. Having these two sets of x-y-z coordinates, the area portion
direction module 306 geometrically calculates the gimbal angles required for
establishing a Line Of Sight (LOS) between the center of the array (xa :ya : za)
and the center of the selected area portion (xp :yp :zp) and converts said angles
to the analog signals required by the gimbals servo unit 308 for estabhshing
said direction of the gimbals 300. The said direction calculation is repeated and
updated in short time intervals, in order to account for the change in the
aircraft location and orientation. The gimbals servo unit 308 receives a signal
315 from the gimbals unit indicating the state of the gimbals with respect to the
desired LOS direction. When it determines that the LOS direction has been
established, the servo unit conveys a signal 321 to the Integration/Sampling
unit 304, for initiating the integration period. The Integration/Sampling unit
304 provides a signal 322 to the array 301, causing it to begin light integration
of incoming light from the area portion. From that instance, the light sensitive
components of the array begin to accumulate charge relative to the level of light
at each corresponding section of the area portion. During the integration period,

motion compensation is repeatedly calculated by the motion compensation
module 307. The motion compensation module 307, in similarity to the area
portion direction module 306, also receives from the DEM the (xp :yp :z )
coordinates of the center of the selected area portion and from the INS the
(xa :ya'.za) of the center of the on-gimbals array 301. The motion compensation
module 307 repeatedly calculates the gimbal angles required for estabhshing a
Line of Sight (LOS) between the updated coordinates of the center of the array
(xa : yd :za) as received from the INS, and the center of the selected area portion
(xp :yp :zp) and accordingly converts said calculated angles to analog signals
required by the gimbals servo unit 308 for estabhshing said direction (i.e., said
angles) of the gimbals 300, or in other words, to repeatedly compensate for the
motion and change of orientation of the aircraft during the integration period.
Motion compensation for image roll around the LOS may also be done, by using
an additional de-roll gimbals, but this is typically not needed in small or
medium-sized arrays due to the small smearing effect of roll in such arrays. At
the end of the integration period a "sampling" signal 322 is provided to the
array 301, for simultaneously sampling the accumulated charge levels within
all the array sensors, and storing in storage 302 the said charge levels as an
image of the selected area portion. The image storage 302 is essentially the SSR
3 of Fig. 1. Next, the portion selection block 311 selects a center of a next area
portion from the DEM 310, and conveys the same to the area portion direction
module 306, and the same procedure as described above repeats for this next

area portion. The procedure repeats for all the area portions of the area of
interest. It should be noted herein that there are several optional modes by
which the portion selection block 311 operates. In one optional case, the portion
selection block 311 first selects a center of a first area portion and obtains its
image, and then, for any additional portion it determines in real time the center
of a next area portion which satisfies, for example, a requirement of 10%
overlap between the present portion and the previously imaged portion. This
optional case will be described in more detail hereinafter. In another mode of
portion selection, the pilot marks the center of a portion, and the image of that
portion is accordingly obtained after carrying out the above procedure of
direction, motion compensation, integration and sampling. In still another
optional selection mode, all portions of the area of interest and their center are
predefined, for example while the airplane is on the ground, and the selection is
then carried out according to said predefined order, while during the flight the
exact directions are updated automatically based on the actual position and
attitude of the aircraft.
The selection of an area portion, so that a pre-defined overlap will exist between
successive images, is dependent on the overall geometric scenario including
aircraft position with respect to the scene and the ground variations of the
captured scene. Referring to Figs. 11 and 11A, for each snapshot, the footprint
of the sensor's FOV on the ground is calculated using the 3-dimensional ground
data of the DEM. Each footprint is a 3-dimensional plane, or a higher order

surface, tilted in two directions in order to best fit the ground's gradients. After
taking a snapshot, and before taking the next snapshot, the system estimates
the direction of the LOS center using extrapolation from the previous snapshots
or other techniques, and calculates the estimated ground footprint of the next
snapshot. The overlap between this estimated footprint and the footprint of the
previous snapshot is calculated by projecting the former on the latter, and then
the direction of the LOS center is modified in order to ensure an overlap within
a specified range of values. This process repeats iteratively a few times until the
required overlap is achieved, and then the LOS is physically moved to the
location of the new snapshot. The calculation may also be done analytically
without iteration, depending on the mathematical model and the computing
resources available to the reconnaissance system. The number of jumps of the
LOS across track (i.e. along a row), which determines the width of the
photographed strip, is continuously calculated to ensure maximum strip width
without creating an excessive lag in jumping along track to the next row to
compensate for the aircraft progression.
Gimbals having at least two degrees of freedom are well known in the art, and
are used, for example, in some aircrafts for inertial directing and tracking the
targeting system to a target, a targeting system being a system enabling
observation of targets and directing weapon systems towards them. Some of
said targeting systems also use navigational and orientation data from an
Inertial Navigation System for calibrating the tracking in real time. The

present invention uses a gimbals system similar to the one used in said
airborne targeting systems. The "tracking" of the gimbals with the array to the
relevant area portions, each portion in its turn, is performed in a similar
manner as some airborne targeting systems direct and track their weapons to a
target. However, in such targeting systems the area of interest is not divided
into a plurality of matrix-type portions, and there is no systematic scanning of
the relevant area portions within an area of interest in a sequential step-wise
manner. Moreover, in the targeting systems, the problem of motion
compensation is solved by other means, such as electro-optical tracking based
on image information, a solution that is not practical for area scanning systems,
such as the reconnaissance system of the invention. As said, the problem of
motion compensation is implemented in a completely different manner in some
of the prior art reconnaissance systems, for example an on-chip motion
compensation is disclosed in US 5,155,597, US 5,692,062, and WO 97/42659.
The invention uses a combination of the INS and gimbals system having at
least two degrees of freedom for (a) carrying out area scanning by which a
"jump" between area portions is performed in a coarse manner, and (b) motion
compensation during the integration period of an area portion which is
performed in a fine manner. The facts that the elevation (i.e. altitude) at the
center of each selected portion, as obtained from the DEM, and that the gimbals
system has at least two degrees of freedom, enables full and fine motion
compensation in all axes. This structure, as will be elaborated later, enables the
aircraft to carry out sharp maneuvers in a superior manner in comparison to

reconnaissance systems of the prior art. Furthermore, it has been found by the
inventors that due to the longer sensors' exposure time to light (i.e., longer
integration time) which becomes possible in the system of the invention due to
the use of staring arrays, there is essentially no need for a TDI structure in
which a same area pixel is scanned N times, and then averaged. The system
instead can use a single "snapshot" capturing of each area portion.
Fig. 5 is a flow diagram describing the operation principles of the
reconnaissance system of the invention. The flow diagram of Fig. 5 assumes
that an area of interest has been defined, more particularly, the borders of the
area of interest. In a preferable embodiment of the invention, the center of the
first portion of the area of interest to be imaged is determined automatically.
For example, if the area of interest is viewed as a matrix, the first portion may
be the farthest, leftmost portion, and its center is selected automatically by
means of some predefined manner. Next, the centers of all the other area
portions are determined in real time, in order to satisfy some predefined range
of overlap between the images, as explained before. The definition of that range
is necessary in order, on the one hand, to assure that no "holes" of imaging
exist, and on the other hand, that no extreme overlapping exists between
images of adjacent portions, involving more images than necessary. As will be
elaborated hereinafter, this procedure involves using the DEM 310.

In block 500, the center coordinates x1; y1, of the first selected portion is provided
to the DEM 501, which in turn conveys the set x1: y1: z1 (z1 being the elevation
at x1;y1) to the servo control unit 305. The Servo control unit 305, which also
receives the real time present coordinates of the center of the array xa: ya: za
from the INS (step 504), also calculates in step 503 the angles and signals
required to establish a line of sight between the center of the array and the
center of the said first area portion x1:y1:z1. The signals are conveyed to the
gimbals servo unit, which establishes the desired LOS direction in step 505. In
step 506, a check is made to determine whether the establishment of the proper
direction has been completed. Of course, this is a dynamic operation which is
repeated in a very frequent and rapid manner to perform correction according
to the airplane progression, and any change of orientation, for example due to
elasticity or aircraft maneuvering, as being reported by the INS 504, which in a
preferable case has its inertial sensors on the gimbals. In step 507, the light
integration by the array components takes place. Simultaneously, during the
integration period a motion compensation takes place, again, to account for the
aircraft progression and any change of its (or more particularly of the gimbals
array) orientation. This operation is also performed repeatedly, in real time,
with high frequency, typically around 100 Hz, that guaranties highly accurate
motion compensation during the time of integration. At step 509, a check is
made to determine whether the integration period has lapsed. At the end of the
integration period, the light integration by the array terminates (step 511) and
the motion compensation of step 508 may also terminate (step 510). At step

512, all the array sensors are sampled at the same time (in a snap-shot
manner), and the image is stored. At step 513, a check is made whether all the
area of interest has been covered by the images already taken. In the
affirmative case, the procedure terminates (step 514). If, however, the full area
of interest has not been covered yet, the application assumes x: y coordinates of
a next area portion (step 515), which are conveyed to the DEM to obtain the
elevation z at the same portion center. The next area portion may either be
located across-track (same row) or along track (new row) from the previous area
portion, depending on the calculated row width so that a maximum strip width
is achieved while not lagging behind the aircraft progression. Next, in a
preferable case (step 516) a simulation is made to determine whether, if an
image is taken when directing to said x:y:z coordinates, the overlapping area
between the area of the previous image and the area of the said new image
satisfies a predefined overlap range (for example between 10%-20% overlap). If
the overlap is found to be too great, this center point is then positioned slightly
farther from the center of the previous portion. If, however, the overlap is found
to be too low, the portion center is positioned slightly closer to the center of the
previous portion. This simulation uses the DEM, which is essentially a digital
map which also includes elevation at all the grid nodal points. The use of the
DEM for that purpose is advantageous, as the elevation is of high importance
when checking the overlapping issue. It has been found that after one or two
repeated simulations, a new portion center can be determined. The alignment of
step 516 as described is preferable, but not essential. From step 516 the

procedure continues to step 503 using the new x: y: z coordinates of the portion
center as determined at step 516, and the procedure is repeated until coverage
of all the portions of the area of interest is completed. Then, the system may
switch to scan a new area of interest if such is desired. It should be noted that
although it is preferable to scan an area of interest in a sequential order, as it
simplifies the portions overlapping calculations and improves the scanning
efficiency, the scanning may also be performed in any other, predefined (or not)
order.
As said, when directing the array to the center of an area portion, and
compensating for the aircraft motion and the orientation change, the elevation
of the relevant area portion is of particular importance for obtaining high
accuracy. Therefore, according to a preferred embodiment of the invention, a
Digital Elevation Map (DEM), i.e., 3-D map which includes a grid of the area of
interest, is used. Generally, there is no problem in obtaining such Digital
Elevation Maps of almost any area in the world; such information is
commercially available, or can be extracted from a topographic map of the area.
The DEM of the area of interest is loaded into the airborne system before the
reconnaissance mission, generally to the SSR 3.
As said, the reconnaissance systems of the prior art, for example, as disclosed in
US 5,155,597, US 5,668,593, US 5,692,062, WO 97/42659, US 6,130,705, and
US 6,256,057, do not directly consider the elevation of the terrain at the

imaging area portion while calculating the Forward Motion Compensation
(FMC), or Motion Compensation (MC) in general. Some of those systems, for
example, as disclosed in US 5,692,062, US 6,130,705, use image-to-image
correlation in order to indirectly estimate the smearing effects of the terrain
variations and correct them using on-chip techniques, but these techniques
have drawbacks as described before, and therefore are not considered in the
following discussion. These drawbacks include the need for three successive
image captures for each usable image, limited correlation accuracy due to
smearing of the first two images, large pixel-shift between successive images,
and varying V/R during the 3-image capture process. Fig. .9 exemplifies the
significance of the elevation (i.e. altitude) factor, and shows how important it is
to consider directly and in real-time the elevation of the imaged terrain.
Generally, in prior art reconnaissance systems, the aircraft INS, when used,
computes the aircraft position and attitude with respect to a global system, but
has no knowledge whatsoever of the actual shape of the terrain 751 being
photographed. The aircraft 750 therefore assumes some fixed, ground level 756,
generally sea level, as depicted. Now, if the reconnaissance system, photographs
the area whose center point is A, during the exposure time, the aircraft 750
progresses a distance D. The reconnaissance LOS (Line of Sight) will keep
pointing at point C assuming a fixed level 756, thus shifting point A to point B
during the exposure time, and for the mountain 757, a smear of magnitude AB,
or error angle 752 is created.

Example 1
The following is a numeric example for assessing the pixels smear in the prior
art systems when capturing a terrain with large variations, showing a forward
oblique scenario: Aircraft flying at a velocity of 250m/s, range from the aircraft
to scene of 10km to level ground, exposure time of 10ms, and assuming
mountain 757 is at 1/2 range (i.e. 5km), and altitude of aircraft is 5km.
Therefore, the angular velocity of the LOS is approximately 12.5milirad/s
(aircraftVelocity / aircraftAltitude) x SIN2(LOSdepressionAngle), and the
angular travel of the aircraft during integration time is 12.5 x 0.01 = 125
microrad. The angle 752 is therefore 125 microrad; for a typical pixel
Instantaneous FOV (IFOV) of 30 microrad this means a smear of more than 4
pixels.
The situation is even worse for a side oblique scenario, where, in this example,
the angular velocity is 250 / 10,000 = 25milirad/s, and the resulting smear is 8
pixels.
For the system of the invention, the pixel smear is much smaller, as
demonstrated in the following example. The error in the LOS angular velocity
due to range R and velocity V uncertainties is calculated by the following
formula:


For Vnom of 200m/s, Rnom of 15km, LOS depression angle of 20 degrees, terrain
slope up to 15%, a typical INS velocity error of 0.045m/s, a typical LOS angular
error of 2mrad, a typical aircraft position error of 30m, a typical aircraft
altitude error of 42m, and a typical DEM altitude error of 15m, we calculate (all
values 3σ) the range error as 160m, and the LOS angular velocity error:

The pixel smear during the integration time of 10ms will then be 0.14 x 0.01 =
1.4 microrad, which, for a typical IFOV of 30 microrad is a small sub-pixel
smear, i.e., a smear of less than 5% of a pixel.
Various types of scanning may be used in the system of the invention, as
follows:
a. Sequential matrix scanning: The portions of the area of interest are
captured according to their sequential order within the area matrix.
b. Selective scanning: Any selection can be predefined, and the portion
capturing is performed accordingly.
c. Manual capturing: the capturing of an area portion is carried out
manually, according to the pilot selection.
It should be further noted that a stereoscopic imaging could also be obtained by
the system of the invention. Unlike systems of the prior art, especially those
disclosed in US 5,155,597, US 5,692,062, and US 6,256,057, the system of the

present invention can enhance the stereoscopic effect by "revisiting" an area
portion after the aircraft progressed to a substantial angular displacement with
respect to the area portion. Fig. 7 shows how a stereoscopic image can be
constructed by the present invention. As is known in the art, a stereoscopic
image of an area or object can be constructed by using two images, each
covering a substantial overlapping portion of the area or object, if said two
images are taken from two points of views angularly remote enough one from
the other with respect to the imaged area. In Pig. 7, the reconnaissance aircraft
200 flies from the left to the right, in the route as shown. When passing, for
example point A, the aircraft sequentially captures the portion images 201, 202,
and 203, by directing the on-gimbals array to these portions accordingly.
Thereafter, the aircraft continues to point B, at which the gimbals are directed
again to capture correspondingly the images 201', 202', and 203' of the same
area portions; however, now, from the point of view of B. If a substantial
portion, for example, about 56%, of each area portion overlaps in the images as
taken from points A and B respectively, a stereoscopic image of the area portion
can be constructed in a known manner. As shown, the invention provides an
easy, simple, and compact manner for obtaining the images required for
constructing stereoscopic images. When interpreting reconnaissance photos,
the stereoscopic effect may be obtained, for example, by displaying the two
images of the same area portion at different light polarities, and then viewing
the display using polarizing glasses, directing one image to the left eye and the
other to the right eye.

In a more preferred embodiment of the invention, two Inertial Navigation
Systems are used by the reconnaissance system of the invention.. More
particularly, and as is shown in Fig. 6, the INS 303 of Fig. 4 comprises two
separate Inertial Navigation Systems. The first INS is the aircraft main INS
604, usually combined with GPS, and the second INS is the Internal
Reconnaissance INS 603. As said, the INS 303 is used for providing
navigational data, such as the present coordinates of the aircraft with respect to
a predefined, preferably global coordinates system, and orientation data
relating to the orientation of the aircraft with respect to said global coordinates
system. This data has to. be very accurate, and has to be continuously updated
in order to assure accurate direction to the captured area, and not less
important, in order to assure accurate motion compensation, even during fast
and sharp maneuvers of the aircraft. This task involves even more
complication, as due to the-elasticity of the aircraft the portions suffer from very
high accelerations, and very intense airflow. Therefore, in order to best direct
the array of light-sensitive sensors, and to best compensate for the aircraft
motion, it has been found by the inventors that it is essential to position an INS
inside the reconnaissance system, and preferably on the gimbals themselves, for
measuring navigation and orientation data of the gimbals, with respect to a
predefined global coordinates system. Therefore, the Internal Reconnaissance
INS is preferably positioned on the gimbals, proximate to the array that is
preferably positioned on the gimbals as well, and accurately measures said

data. However, as the Internal INS must be limited in size, and therefore may-
suffer from some inaccuracies and drifts, according to the present invention the
Internal INS 603 is connected to the Aircraft Main INS 604. The main aircraft
INS periodically updates the internal INS with navigational data for aligning it
for possible drifts, using the prior art transfer alignment process described
before. In such a manner wider bandwidth and higher accuracy of the gimbals
servo is obtained. Typical values for mechanical misalignment between the
aircraft and the reconnaissance system LOS are 10-20 mrad, while the aligned
on-gimbals INS can measure this misalignment to an accuracy of 1-2 mrad.
It should be noted that the area portions are typically captured by the system of
the invention in a "snapshot" manner, typically with much longer integration
time than the vector or array in systems of the prior art. While the typical
integration period in the system of the invention is in the order of milliseconds,
in systems of the prior art using vectors, such as, US ,5,155,597, US 5,692,062,
and US 6,256,057, the typical integration periods are two to three orders of
magnitude shorter (i.e., between 100 to 1000 times shorter), resulting in a much
lower photonic sensitivity to light. This evolves from the fact that the invention
uses an array having several hundreds or thousands of rows and columns, in
which each pixel is exposed to light during all the area- capturing time. In the
prior art systems using a one-dimension vector, a same capturing period is
divided between the pixels of a same vector, which must be exposed hundreds
or thousands of times in order to cover a same area portion. Moreover, the fact

that the system of the invention allows great flexibility in selecting areas and
portions within areas of interest enables a significant reduction in the amount
of data that the system has to deal with (i.e., to capture, store, and/or transfer
by communications means). More particularly, images of only portions and
areas of interest are captured by the system of the invention.
EXAMPLE 2
The following is an example showing the saving in the amount of data which
the system of the invention handles (i.e., storing, transmitting to a ground
station, etc.), in comparison with a pushbroom or a large-sized array
reconnaissance system:
- Mission duration: 2 hours;
- Fig. 12 illustrates this scenario. Area of high priority targets with
respect to the photographed area: 40% for snap shooting. The term
"snapshot", refers herein to a manner in which all the array pixels are
simultaneously exposed to light from an area portion, and data from all
the array pixels simultaneously is read at the end of the said exposure;
5% for pushbroom or large-sized array - due to the efficiency of LOS and
FOR mission planning (this is an assumption resulting from the ability
of the system of the invention to better select high priority targets
within an area of interest, and to ignore area portions of no interest);
- Sensors' data throughput rate uncompressed: 20 Mbytes/s
- Low compression rate: 1:5

- High compression rate: 1:10
- Overlap area for snapshots reconnaissance (according to the invention):
40% total of along-track and across-track overlap;
- Overlap area for pushbroom: 20%;
Total recording:
1. Snapshooting = (2hr x 60 x 60) x 20MB/s x (0.4/5 + 0.6/10) x 1.4 = 28 GB
2. Pushbroom = (2hr x 60 x 60) x 20MB/s x (0.05/5 + 0.95/10) x 1.2 = 18 GB
As said, the number of high priority targets obtained for snap-shooting
reconnaissance (according to the invention) is 40% / 5% = 8 times higher than
for push-broom or large-sized array reconnaissance, and therefore the overall
efficiency of the mission is: 8 x (18/28) = 5.1 in favor of snapshooting according
to the system of the invention.
This is a significant increase in efficiency.
It should be noted herein that the reconnaissance system of the invention, by
directing the LOS of the array/s of light sensitive sensors using gimbals with at
least two degrees of freedom, enables the defining of an area of interest of
arbitrary shape which is divided, preferably in real time, to a plurality of area
portions that are sequentially scanned in a stepwise systematic and accurate
manner to obtain images of those portions until covering the full area. The

system of the invention enables not only efficient covering of a specific area of
interest, it also eliminates the need for providing dedicated means for forward
motion compensation, as required in reconnaissance systems of the prior art,
for example in US 5,155,597, US 5,668,593, US 5,692,062, WO 97/42659, US
6,130,705, and US 6,256,057. By directing the LOS of the array using gimbals
with at least two degrees of freedom, and by continuously correcting the
direction to the selected area portion during the "exposure", not only forward
motion compensation with respect to the forward axis is provided, but also
consideration is made to the'3D shape of the terrain for providing improved
motion and orientation compensation with respect to all three axes. This fact is
of particular importance, as it enables sharp and wide maneuverings of the
aircraft. Moreover, no matter where the aircraft is positioned with respect to
the area of interest or to any portion within said area, and no matter in what
orientation, the system provides means for obtaining appropriate images of
such area portions (assuming no obstruction from the aircraft body).
Example 3
The invention was successfully implemented with the following parameters:
Airborne pod configuration;
Number of pixels: Visual array: 2000 x 2000, IE array 640 x 480;
Integration times: 1-15 ms;
Operational ranges: up to 30 km and altitude up to 10 km;
Snapshot rate: 3 per second, both sensors arrays operating simultaneously.


: FOR: full spherical coverage, excluding a ±30 degrees backward looking cone;
See also Figs. 11 and 11A that are the result of an actual simulation of the
scanning and overlapping process.
As said, in the embodiment of the invention as described above, the area
scanning operation is performed by the gimbals that first direct the center of
the array's LOS to the center of the relevant area portion, then, an exposure of
the array to the light coming from the area portion occurs (i.e., the array starts
integration of light from the area portion), and at the end of the exposure period
the image of the area portion is captured. Next, the array's LOS is directed to
the center of a next area portion, and the procedure of integration and
capturing repeats. This procedure repeats for all the area portions of the area of
interest. More specifically, in the above embodiment the gimbals operate during
the scanning of the area of interest in a "jumping" manner, by which the
gimbals first move until an alignment to the predefined area portion is
obtained, then the gimbals are stationary during the exposure period (except for
motion compensation movement), and next the gimbals move again to direct the
array to the center of the next area portion, etc. This type of operation is limited
in the number of snapshots per second as demonstrated in Example 3, as the
acceleration-deceleration and stopping of the relatively heavy gimbals is time-
consuming.

According to still another embodiment of the invention, the scanning efficiency
is improved by using a back-scanning mechanism, as is shown in Fig. 9. As
said, in the "jumping"-type scanning, the array and. its associated optics is
preferably positioned on the internal gimbals, and all these are stationary with
respect to said internal gimbals. In the improved, back-scanning embodiment of
the invention a back-scanning array assembly 860 is mounted on the internal
gimbals. The assembly essentially comprises lenses 861, and 862, stationary
mirror 864, and a low-mass single or dual-axis back-scanning rotating mirror of
prism 863. The back-scanning rotating mirror is mounted on a dedicated motor.
In the back-scanning method, the scanning of the area portions is performed
continuously, or, in other words, the gimbals continuously scan columns (or
rows) of the area of interest at high LOS angular velocity, and this scanning
movement comes on top of the direction alignment and motion compensation, as
described above. Whenever an exact alignment to the center of an area portion
is obtained, the light integration (exposure of the array) period begins, and the
back-scanning mirror 863 compensates for the scanning continuous movement
of the gimbals, only during the integration period by maintaining angular
movement to the opposite direction in half the angular velocity. With reference
to Fig. 10, if the gimbals maintain a scanning constant angular inertial velocity
in the direction 870, the back-scanning mirror 863 rotates during the
integration period (only) in the opposite direction 880, in half the angular
velocity. In this manner, the area portion is maintained stationary at the array
305. At the end of the integration (exposure) period, the mirror 863 returns to

its initial position, until a new integration period, in which the same constant
movement of the mirror repeats. The back-scanning enables the gimbals to
move at higher velocity without having to stop for each snapshot. Stopping the
gimbals consumes most of the duty cycle time due to the high
acceleration/deceleration and to the high inertial mass of the gimbals and their
payload (i.e. the sensors). The back-scanning mirror can move much faster
thanks to its much smaller inertial mass.
EXAMPLE 4
The angular range of the back-scanning mirror is very small. For example, if
the gimbals move at 60 deg/s and the exposure time is 10 ms, the angular
displacement of the back-scanning mirror is 60 x 0.01 = 0.6 deg, which is very
small.
A typical comparison: Using gimbals without back-scanning enables a snapshot
rate of 3 frames per second in a typical installation (e.g. Bxamle 3). The average
gimbals velocity, for a Field of View of 3 degrees, would be approximately 3x3
= 9 deg/s. On the other hand, using back-scanning, the gimbals can move at a
velocity of 60 deg/s, resulting in 60 / 3 = 20 snapshots/s, a rate which is more
than 6 times higher. The maximum allowable rate is limited by the electronic
frame rate of the sensor, which is typically 30 or 60 Hz,and therefore higher
than 20 Hz.

Fig. 8 and Fig. 8A illustrate a specific case in which the present invention is
advantageous over prior art reconnaissance systems. Suppose that the aircraft
700 has a mission to obtain images of the two posts 705, and of a highway 710
located between the mountains. In a reconnaissance system of the prior art, in
which the camera (i.e., the vector of light sensitive elements) is essentially fixed
with limited FOR, the aircraft can cover from point Q (while having a field of
view limited by lines 701 and 702) only the area between points B and D of the
first (right) mountain and the area between points A and C of the second (left)
mountain. Images of the two posts 705 and of the highway 710 are not
obtained. In long range oblique photography (LOROP) the aircraft will fly
towards the page, and the LOS will be side-oblique with substantial obscuration
due to the small LOS depression angle. If the camera, however, is not fixed, as
in the case of the prior art push-broom or whiskbroom systems, there is also no
assurance of full coverage of the posts 705 and highway 710, as there is no
synchronization between the movement of the field of view of the camera and
the shape of the terrain. According to the present invention, this problem is
easily solved. While preparing the mission and the division of the area of
interest, it is possible to select any coordinate to be the center of an area of
interest, and to program the reconnaissance system to direct its array/s' LOS to
these selected coordinates from any predefined or manually selected location of
the aircraft, so long as the LOS is within the system's FOR. Therefore, as
shown in Fig. 8A, while being at location R the array's LOS may be forward
directed to cover the area between points F and E, and later, while reaching

point S, the array's LOS may be backward directed to cover the area between
points G and H. In that case, the full area between the mountains, including
the two posts 705 and the full image of the highway, can be obtained. The lines
711 and 712 indicate the limits of the field of regard of the reconnaissance
system from point R, while the lines 721 and 722 indicate the limits of the field
of regard of the reconnaissance system from point S.
Fig. 11 is a perspective view of a hilly terrain 560, and its division into area
portions, including some overlap between area portions. Also shown in Fig. 11 is
an instance in which one area portion is captured by aircraft 561, and a later
instance in which another area portion, 564, is captured by the same aircraft.
Fig. 11A shows an upper view of the same terrain, and the manner of scanning
of the area of interest by the aircraft reconnaissance system, as indicated by the
arrows 565.
To summarize, the present invention is characterized by the following main
advantages over the prior art systems:
- The ability to photograph in any LOS direction within a large Field of
Regard (FOR). In order to have this ability (e.g., forward-oblique, side-
oblique, down, and arbitrary looking) the prior art reconnaissance
requires use of separate light- sensing units or a plurality of separate
pods. This ability of the present invention enables the coverage of more

targets (i.e., area portions) during a mission, with reduced storage
requirements;
- The ability to photograph in any aircraft flight direction within a large
FOR;
- The ability to focus on selective quality targets for a long duration and
get many pictures at the highest quality while the aircraft is
progressing. The overall mission area is not recorded, but only selective
portions, thus saving storage;
- The ability to photograph in terrain with large variations, by directing
the LOS so that no obscuring will occur;
- The ability to photograph while the aircraft is maneuvering, thus
increasing mission flexibility and aircraft survivability;
- The ability to operate manually or automatically in the same mission.
While some embodiments of the invention have been described by way of
illustration, it will be apparent that the invention can be carried into practice
with many modifications, variations and adaptations, and with the use of
numerous equivalents or alternative solutions that are within the scope of
persons skilled in the art, without departing from the spirit of the invention or
exceeding the scope of the claims.


WE CLAIM:
1. An airborne reconnaissance system for obtaining images from an area of
interest comprising:
- Gimbals having at least two degrees of freedom;
- At least one array of light sensors positioned on the gimbals, for being
directed by the same within at least two degrees of freedom;
- Map storage means for storing at least one Digital Elevation Map of an
area of interest, divided into portions;
- Inertial Navigation System for real-time providing to a gimbals control
unit navigation and orientation data of the aircraft with respect to a
predefined global axes system;
- Portion selection unit for selecting, one at a time, another area portion
from the area of interest;
- Servo control unit for:
A. Receiving from said Digital Elevation Map one at a time, a
coordinates set of the selective area portion, said set comprising the x: y
coordinates of said area portion, and the elevation z of the center of that
portion;
B. Receiving continuously from said inertial navigation system
present location and orientation data of the aircraft;
C. Repeatedly calculating and conveying into a gimbals servo unit
in real time and at a high rate signals for:


a. during a direction period, signals for directing accordingly
the gimbals including said at least one array of light-sensing units towards
said x: y : z coordinates of the selected area portion, and;
b. during an integration period, in which the array sensors
integrates light coming from the area portion, providing to the gimbals unit
signals for compensating for the change in direction towards the x: y : z
coordinates of the selected portion evolving from the aircraft motion;
- Gimbals servo for effecting direction of the gimbals in at least two degrees
of freedom as claimed in the signals provided from said Servo Control Unit;
- Sampling means for simultaneously sampling at the end of the integration
period pixel levels from each of said array sensors, a set of all of said
sampled pixel levels forms an image of said area portion; and
- Storage means for storing a plurality of area portion images.
2. System as claimed in claim 1, wherein said one or more arrays are
selected from at least a visual light-sensitive array, a UV light sensitive-
array, an infrared light-sensitive array, a multi/hyper-spectral array, and
an active illumination array.
3. System as claimed in claim 1, wherein said navigation data of the
aircraft comprises data relating to the 3D location of the aircraft, and its
velocity and acceleration vectors with respect to a predefined coordinates


system, and its orientation data relating to the orientation of the aircraft
with respect to said predefined coordinates system.
4. System as claimed in claim 1, wherein said Inertial Navigation System
comprises velocity, acceleration, and orientation sensors, at least some of
said sensors being positioned on the gimbals.
5. System as claimed in claim 1, wherein at least some of said arrays of
sensors being positioned on the gimbals.
6. System as claimed in claim 1, comprising two Inertial Navigation
Systems, the first inertial navigation system being the main Inertial
Navigation System of the aircraft and its sensors being positioned within
the aircraft, and the second Inertial Navigation System being a system
dedicated to the reconnaissance system, at least some of the sensors of said
second Inertial Navigation System being positioned on the gimbals unit,
measuring navigation and orientation data of the gimbals with respect to
the said predefined axes system, for better eliminating misalignments
occurring between the gimbals and LOS and the said main Inertial
Navigation System of the aircraft due to aero-elastic deflections and
vibrations of the aircraft, by using a process of transfer alignment from the
said first INS to the said second INS.

7. System as claimed in claim 1, wherein the Digital Elevation Map is a
map comprising a grid of the area of interest, the x: y : z coordinate values
at each of the nodal points in said grid being provided by said map.
8. System as claimed in claim 1, wherein the portion selecting unit is used
for calculating and determining a center of a next area portion that
provides a predefined overlap between the said imaged area portion and the
adjacent previously imaged area portion.
9. System as claimed in claim 1, wherein in an automatic mode of
operation the gimbals are activated to cover in a sequential, step-wise
manner, the area of interest, said coverage is made from a predefined
starting portion and according to a stored mission plan, thereby
sequentially scanning one after the other area portions of the area of
interest, and sampling images from each of said portions.
10. System as claimed in claim 1, wherein in a manual mode of the system
the pilot of the aircraft defines an area of interest during the flight, said
area of interest being automatically divided into at least one area portion,
all the area portions being automatically scanned one after the other by
means of correspondingly directing to them the on-gimbals array, for
capturing images of each of said scanned portions.


11. System as claimed in claim 1, wherein the gimbals comprise two gimbals
mechanisms, an external gimbals mechanism and an internal gimbals
mechanism.
12. System as claimed in claim 1, wherein the external gimbals mechanism
is used for coarse directing the on-gimbals array to the center of a selected
area portion.
13. System as claimed in claim 11 wherein the external gimbals mechanism
has two degrees of freedom, elevation and roll.
14. System as claimed in claim 10, wherein the internal gimbals mechanism
is used for fine directing the on-gimbals array to the center of a selected
area portion, particularly for compensating the gimbals direction for the
aircraft motion and orientation change during the integration period.
15. System as claimed in claim 11, wherein the internal gimbals mechanism
has two degrees of freedom, yaw and pitch.
16. System as claimed in claim 10, wherein the external gimbals mechanism
is slaved to the internal gimbals mechanism.
17. System as claimed in claim 1, wherein during the integration period
each of the array sensors simultaneously senses light from a corresponding


section of the area portion, and at the end of the integration period the data
from all the array sensors is read simultaneously, and stored as an image of
the area portion.
18. System as claimed in claim 1, wherein the array light sensors are
sensitive to light in the range of visual light, IR, UV, multi/hyper-spectral,
and/or an active illumination.
19. System as claimed in claim 1, wherein the arrays are focal plane arrays.
20. System as claimed in claim 1, wherein the predefined axes system is a
global axes system.
21. System as claimed in claim 1, assembled within a pod attached to the
aircraft.
22. System as claimed in claim 1, assembled within a payload installed
inside the aircraft with only its windows protruding for obtaining a clear,
unobstructed Line of Sight.
23. System as claimed in claim 21, wherein the gimbals are located at the
front of the pod, behind a transparent window.


24. System as claimed in claim 1, further comprising a back-scanning
mechanism comprising a mirror or prism, positioned on the gimbals and
rotatable with respect thereto, light coming from the area portion first
passing through said mirror which deflects the same towards the array,
and,
a. the servo control unit applies to the gimbals a continuous row and/or
column scanning movement without stopping; and
b. while the direction towards an area portion is being established,
applying to said back-scanning mirror during the integration period an
opposite direction movement with respect to said row and/or column
scanning continuous movement, thereby compensating for that continuous
movement and ensuring a fixed orientation relationship of the array with
respect to the area portion imaged.
25. A method for carrying out airborne reconnaissance, comprising:
a. Providing at least one array of light-sensitive pixels;
b. Mounting the at least one array on gimbals having at least two degrees
of freedom so that the gimbals can direct the array to a selected Line of
Sight;
c. Providing a Digital Elevation Map of an area of interest,
reconnaissance images from said area are to be obtained;


d. Providing an Inertial Navigation System for obtaining at any time
during the flight the updated xa : ya : za coordinates of the center of the
array with respect to a predefined coordinates system;
e. Providing a calculation unit for, given xp : yp location coordinates of a
center of specific area portion within the area of interest, and the zp
elevation coordinate at said portion center as obtained from said Digital
Elevation Map, and the said xa : ya : za coordinates of the array center at
same specific time, determining the exact angles for establishing a line of
sight direction connecting between the center of the array and the said
XP : yP : zp coordinates;
f. Given the calculation of step e, directing accordingly the center of the
array's Line of Sight to the center of the area portion;
g. During an integration period, effecting accumulation of light
separately by any of the array light sensors;
h. During the integration period, repeating at a high rate the calculation
of step e with updated array xa : ya : za coordinates, and repeatedly,
following each said calculation, correcting the direction as in step f;
i. At the end of the integration period, sampling all the array sensors,
and saving in a storage as images of the array portion;
j. Selecting new portion coordinates xp : yp : zp within the area of interest,
and repeating steps e to j for these new coordinates;
k. When the coverage of all the area of interest is complete, terminating
the process, or beginning coverage of another area of interest.


26. Method as claimed in claim 25, wherein the selection of xp : yp
coordinates of a new area portion is performed to assure overlap between
adjacent area portions within a predefined range, by calculating the 3-
dimensional footprint of the new area portion on the ground, and then
projecting it on the footprint of a previous area portion.
27. Method as claimed in claim 26, wherein the overlap assurance is
obtained by a trial and error selection, overlap calculation, and correction
when necessary, or by an exact analytical calculation.
28. Method as claimed in claim 25, wherein at least some of the sensors of
the Inertial Navigation System are positioned on the gimbals, for improving
the measuring of the orientation of the array with respect to the selective
area portion.
29. Method as claimed in claim 25, wherein at least some of the light
sensitive sensors are positioned on the gimbals, for improving the
measuring of the orientation of the Line of Sight with respect to the
selective area portion.


30. Method as claimed in claim 25, wherein the Inertial Navigation System
comprises a dedicated Inertial Navigation System of the reconnaissance
system and the main Inertial Navigation System of the aircraft, to improve
the measuring of the orientation of the array with respect to the selective
area portion, by using a process of transfer alignment from the aircraft
Inertial Navigation System to the dedicated reconnaissance system's
Inertial Navigation System.
31. A method for providing motion compensation during airborne
photographing comprising:
a. Providing at least one array of light-sensitive pixels;
b. Mounting the at least one array on gimbals having at least two degrees
of freedom so that the gimbals can direct its Line of Sight towards a
selective area portion;
c. Providing a Digital Elevation Map of an area of interest,
reconnaissance images from said area are to be obtained;
d. Providing an Inertial Navigation System for obtaining at any instant
during flight the updated xa : ya : za coordinates of the center of the array
with respect to a predefined coordinates system;
e. Providing a calculation unit for, given xp : yp location coordinates of a
center of specific area portion within the area of interest, and the zp
elevation coordinate at said portion center as obtained from said Digital
Elevation Map, and the said xa : ya : za coordinates of the array center at

same specific time, determining the exact angles for establishing a line of
sight direction connecting between the center of the array and the said
xp : yp : zp coordinates;
f. During an integration period, when the center of the array's Line
of Sight is directed to a center of an area portion, effecting accumulation of
light separately by any of the array light sensors;
g. During the integration period, repeating at a high rate the
calculation of step e with updated array xa : ya : za coordinates, and
repeatedly, following each said calculation, correcting the direction by
keeping the center of the array directed to the center of the selected area
portion, therefore compensating for aircraft movement; and
h. At the end of the integration period, sampling all the array
sensors, and saving in a storage as images of the array portion.
32. Method as claimed in claim 25, for further carrying out airborne
targeting, comprising:
a. Providing said gimbals having at least two degrees of freedom, so that
the gimbals can be directed to a selected Line of Sight;
b. Providing said Digital Elevation Map of an area of interest, selected
objects within said area are to be targeted;
c. Providing said Inertial Navigation System for obtaining at any time
during the flight the updated xa : ya : za coordinates of the center of the
gimbals with respect to a predefined coordinates system;

d. Providing said calculation unit for, given xp : yp location coordinates
of a center of a specific target within the area of interest, and the zp
elevation coordinate at said target center as obtained from said Digital
Elevation Map, and the said xa:ya: za coordinates of the gimbals center at
same specific time, determining the exact angles for establishing a Line of
Sight direction connecting between the center of the gimbals and said
XP : yP : ZP coordinates;
e. Given the calculation of step d, directing accordingly the center of the
gimbals Line of Sight to the center of the selected target;
f. During the effective targeting period, motion compensating for the
motion of the aircraft by repeating at a high rate the calculation of step d
with updated target xa : ya : za coordinates, and repeatedly, following each
said calculation, correcting the direction as in step e.

Documents:

1784-KOLNP-2004-(14-12-2011)-CORRESPONDENCE.pdf

1784-KOLNP-2004-ABSTRACT 1.1.pdf

1784-kolnp-2004-abstract.pdf

1784-KOLNP-2004-AMANDED PAGES OF SPECIFICATION.pdf

1784-kolnp-2004-assignment.pdf

1784-kolnp-2004-assignment1.1.pdf

1784-KOLNP-2004-CLAIMS 1.1.pdf

1784-kolnp-2004-claims.pdf

1784-KOLNP-2004-CORRESPONDENCE 1.1.pdf

1784-KOLNP-2004-CORRESPONDENCE-1.1.pdf

1784-KOLNP-2004-CORRESPONDENCE-1.2.pdf

1784-kolnp-2004-correspondence.pdf

1784-kolnp-2004-correspondence1.3.pdf

1784-KOLNP-2004-DESCRIPTION (COMPLETE) 1.1.pdf

1784-kolnp-2004-description (complete).pdf

1784-KOLNP-2004-DRAWINGS 1.1.pdf

1784-kolnp-2004-drawings.pdf

1784-KOLNP-2004-EXAMINATION REPORT REPLY RECIEVED.pdf

1784-kolnp-2004-examination report.pdf

1784-KOLNP-2004-FORM 1.1.pdf

1784-kolnp-2004-form 1.pdf

1784-KOLNP-2004-FORM 13.pdf

1784-kolnp-2004-form 18.1.pdf

1784-kolnp-2004-form 18.pdf

1784-KOLNP-2004-FORM 2.1.pdf

1784-KOLNP-2004-FORM 2.pdf

1784-kolnp-2004-form 3.1.pdf

1784-kolnp-2004-form 3.pdf

1784-kolnp-2004-form 5.1.pdf

1784-kolnp-2004-form 5.pdf

1784-kolnp-2004-gpa.pdf

1784-kolnp-2004-gpa1.1.pdf

1784-kolnp-2004-granted-abstract.pdf

1784-kolnp-2004-granted-claims.pdf

1784-kolnp-2004-granted-description (complete).pdf

1784-kolnp-2004-granted-drawings.pdf

1784-kolnp-2004-granted-form 1.pdf

1784-kolnp-2004-granted-form 2.pdf

1784-kolnp-2004-granted-specification.pdf

1784-KOLNP-2004-OTHERS DOCUMENTS 1.1.pdf

1784-kolnp-2004-others.pdf

1784-kolnp-2004-petetion under rule 137.pdf

1784-kolnp-2004-reply to examination report.pdf

1784-kolnp-2004-specification.pdf


Patent Number 251665
Indian Patent Application Number 1784/KOLNP/2004
PG Journal Number 13/2012
Publication Date 30-Mar-2012
Grant Date 27-Mar-2012
Date of Filing 24-Nov-2004
Name of Patentee RAFAEL-ARMAMENT DEVELOPMENT AUTHORITY LTD.
Applicant Address P.O. BOX 2250, 31021 HAIFA
Inventors:
# Inventor's Name Inventor's Address
1 YAVIN ZVI TOPAZ STREET, 20103 GILON-MISGAV
2 UHL BERND 34/5 HERMLINSTRASSE, D-73434 AALEN, GERMANY
3 GREENFELD ISRAEL 23 HERMON STREET, 25147 KFAR VRADIM
PCT International Classification Number G01C 11/02
PCT International Application Number PCT/IL2003/00422
PCT International Filing date 2003-05-22
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 149934 2002-05-30 Israel