Title of Invention

PHASED ARRAY PLANAR ANTENNA FOR TRACKING A MOVING TARGET AND TRACKING METHOD

Abstract A phased array antenna system accommodating onto a platform for tracking a target moving relatively to the platform, the antenna system comprising a first planar active subsystem operable for receiving/transmitting an RF signal of a certain linear polarization direction and for selectively performing electronic scanning; a second, roll subsystem coupled to the active subsystem and operable for rotational movement of the active subsystem about a first axis perpendicular to a plane defined by the planar active subsystem; a third, elevation subsystem coupled to the second, roll subsystem and to a fourth azimuth subsystem, the azimuth subsystem defining a central axis of the antenna system and being operable for providing rotational movement of the first planar subsystem about the central axis, the elevation subsystem being configured to provide a certain angular orientation between the plane defined by the active subsystem and a plane defined by the azimuth subsystem, thereby allowing positioning the first planar active subsystem with respect to the target such that the linear polarization direction is substantially aligned with a linear polarization direction of RF radiation received and/or transmitted by the target.
Full Text FORM 2
THE PATENTS ACT, 1970
(39 of 1970)
&
THE PATENTS RULES, 2003
COMPLETE SPECIFICATION
(See section 10, rule 13)
PHASED ARRAY PLANAR ANTENNA FOR TRACKING A MOVING TARGET AND TRACKING METHOD"
ELTA SYSTEMS LTD an Israel company of 100 Sderot Itzhak Hanasie, P.O.B. 330, 77102 Ashdod (IL)
The following specification particularly describes the invention and the manner in which it is to be performed.

WO 2006/057000

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PCT/IL2005/001272

PHASED ARRAY PLANAR ANTENNA FOR TRACKING A MOVING TARGET AND TRACKING METHOD
FIELD OF THE INVENTION
This invention relates to phased array antennas and planar antennas and more specifically to phased array antennas of the kind suitable to be mounted onto moving platforms e.g. aircrafts, ships, cars etc., used for satellite
5 communication, or for tracking moving targets.
BACKGROUND OF THE INVENTION
Nowadays, many moving platforms (e.g. aircrafts, ships, cars, etc.) are required to have satellite communication capabilities. One exemplary requirement relates to an entertainment system for .offering passengers with e.g.
10 internet access, live television broadcast and the like.
During motion, the moving platform (e.g. the aircraft) is engaged in communication with a particular satellite, tracking it across the sky until it disappears over the horizon, and prior to its disappearance establishes communication with another satellite. Therefore, antennas on-board the moving
15 platforms are typically equipped with suitable positioning and tracking systems.
US Patent No. 5,796,370 discloses a dual polarization antenna for direct
broadcast satellites. The antenna is orientable, directional and capable of use as a
transmit and/or receive antenna. It includes at least one reflector, at least one
source of electromagnetic radiation including means for exciting the source with
20 two orthogonal linear polarizations and a mechanical system for positioning and holding the source and the reflector. The orientation of the antenna is made up of depointing and rotation about a preferred direction of propagation of the radiation and the mechanical system enables such rotation while keeping the source fixed,

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so conserving the orientation of the orthogonal linear polarization. A preferred embodiment of the antenna includes a parabolic main reflector and a hyperbolic auxiliary reflector in a Cassegrain geometry, and the mechanical system enables rotation of both reflectors about the preferred direction of radiation and holds the
5 source fixed to conserve the orthogonal linear polarization axes of the beam. Applications include radar, direct broadcast satellites and telecommunications employing frequency re-use by polarization diversity, especially advantageous in space and airborne applications.
US Patent No. 6,034,634 discloses an inexpensive high gain antenna for
10 use on terminals communicating with low earth orbit (LEO) satellites which include an elevation table mounted for accurate movement about a transverse axis on an azimuth turntable mounted for rotational movement about a central axis. A plurality of antenna elements forming a phased array antenna is mounted on the top of the elevation table and have a scan plane which is parallel to and
15 extends through the transverse axis of the elevation table. The antenna may be both mechanically and electrically scanned and is used to perform handoffs from one LEO satellite to another by positioning the elevation table of the antenna with its bore sight in a direction intermediate the two satellites and with the scan plane of the antenna passing through both satellites. At the moment of handoff,
20 the antenna beam is electronically scanned from one satellite to another without any loss in data communication during the process.
US Patent No. 6,034,643 discloses a directional beam antenna device that includes an antenna supporting member which is supported on a base in such a manner as to be rotatable about a first rotational axis; an antenna portion which is
25 supported on the antenna supporting member in such a manner as to be rotatable about a second rotational axis which is perpendicular to an antenna aperture and is inclined at a first angle with respect to the first rotational axis, the direction of an antenna beam being inclined at a second angle with respect to the second rotational axis; a first driving unit for rotating the antenna supporting member
30 about the first rotational axis with respect to the base; and a second driving unit

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for rotating the antenna portion about the second rotational axis with respect to the antenna supporting member. A directional beam controlling apparatus is provided with a controlling unit for controlling an elevation angle of the antenna beam to a target value by causing the second driving unit to rotate the antenna
5 portion with respect to the antenna supporting member, and for controlling an azimuth angle of the antenna beam to a target value by causing the first driving unit to rotate the antenna supporting member with respect to the base.
PCT Application No. WO2004/075339 discloses a low profile receiving and/or transmitting antenna that includes an array of antenna elements that
10 collect and focuses millimeter wave or other radiation. The antenna elements are physically configured so that radiation at a tuning wavelength impinging on the antenna at a particular angle of incidence is collected by the elements and focused in-phase. Two or more mechanical rotators may be disposed to alter the angle of incidence of incoming or outgoing radiation to match the particular
15 angle of incidence.
Also relating to positioning of satellite communication antennas on-board moving platforms are US Patent Nos. 6,400,315, 6,218,999, 6,741,841, 6,356,239, and 6,751,801.
As is known, polarization of a linear polarized radio wave may be rotated
20 as the signal passes through any anomalies (such as Faraday rotation) in the ionosphere. Furthermore, due to the position of the Earth with respect to the satellite, geometric differences may vary due to relative movements between the satellite and the communicating station (e.g. aircraft, fixed station, etc.). Therefore, most geostationary satellites operate with circular polarization, as
25 circular polarization will keep the signal constant regardless of the above-mentioned anomalies. However, some geostationary satellites use linear polarization. In linear polarization, a misalignment of polarization of 45 degrees will degrade the signal up to 3 dB and if misaligned 90 degrees, the attenuation can be 20 dB or more. Furthermore, polarization purity is required by
30 international regulation of satellite communication. Therefore, on-board antenna

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systems for communication with a satellite using linear polarization need to provide polarization tracking.
Furthermore, on-board antenna systems for moving platforms are required to be relatively small in size and low in profile (diameter and height) in order to
5 adapt to the overall design and specifically the aerodynamic design of the moving platform. However, polarization tracking typically requires a considerable antenna size, for compensating for losses of signal strength involved in polarization tracking.
There is a need in the art for an improved antenna that provides
10 positioning capabilities as well as polarization tracking capabilities. There is a
further need in the art for an improved antenna suitable for use on board moving
platforms and specifically airborne platforms and aircrafts, which is relatively
small and has low profile (e.g. diameter of about 90cm or less).
15 SUMMARY OF THE INVENTION
According to one embodiment, the present invention provides for a phased array antenna system accommodating onto a platform for tracking a target moving relatively to the platform, comprising:
- a first planar active subsystem operable for receiving/transmitting an
20 RF signal of a certain linear polarization direction and for selectively
performing electronic scanning;
- a second, roll subsystem coupled to said active subsystem and operable
for rotational movement of said active subsystem about a first axis
perpendicular to a plane defined by said planar active subsystem;
25 - a third, elevation subsystem coupled to said second, roll subsystem and
to a fourth azimuth subsystem, said azimuth subsystem defining a central axis of the antenna system and being operable for providing rotational movement of the first planar subsystem about the central axis, the elevation subsystem being configured to provide a certain

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angular orientation between said plane defined by said active
subsystem and a plane defined by the azimuth subsystem,
thereby allowing positioning said first planar active subsystem with respect to said target such that said linear polarization direction is substantially aligned with
5 a linear polarization direction of RF radiation received and/or transmitted by the target. The term 'planar' is used hereinafter to denote a planar or a substantially planar activesubsystem.
According to another embodiment, the above-mentioned first, second and fourth subsystems are coupled to a common control system configured to operate
10 said first, second and fourth subsystems in synchronization. According to yet another embodiment, the common control subsystem comprising:
- a Central Processing Unit (CPU);
- a memory coupled to the CPU;
- a data input module coupled to said CPU and connectable to data
15 systems of said platform, for inputting data relating to the relative
position of said platform with respect to said target; and
- a positioning and polarization tracking module coupled to the CPU and
configured for operating said first, second and fourth subsystems.
According to another embodiment, the third, elevation subsystem being
20. configured to provide a controllably changeable angular orientation between the
plane defined by the active subsystem and a plane defined by the azimuth
subsystem. According to yet another embodiment, the common control unit is
further configured for controlling the operation of said third, elevation
subsystem, thereby allowing selective adjustment of said scanning cone.
25 According to another embodiment, the present invention provides for a
method for tracking at least one target with a phased array antenna system having a planar active subsystem and accommodating onto a platform moving relatively to the target, the method comprising:
(i) receiving/transmitting an RF signal of a certain linear polarization
30 direction;

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(ii) receiving and storing data regarding the position and polarization of
the target and the antenna system, constituting position and
polarization data;
(iii) in response to said position and polarization data, having the active
5 subsystem selectively performing azimuth rotational movement about
a central axis of the antenna system, roll rotational movement about a first axis perpendicular to a plane defined by the planar active subsystem, and
electronic scanning;
thereby allowing positioning said planar active subsystem with respect to said
10 target such that said linear polarization direction is aligned with a linear polarization direction of RF radiation received and/or transmitted by at least one moving target.
According to another embodiment, the present invention provides for a phased array antenna system accommodating onto a platform for tracking a target
15 moving relatively to the platform comprising:
- a first planar active subsystem operable for receiving/transmitting an
RF signal of a certain linear polarization direction and for selectively
performing electronic scanning;
- a second, roll subsystem coupled to said active subsystem and operable
20 for rotational movement of said active subsystem about a first axis
perpendicular to a plane defined by said planar active subsystem;
- a third, elevation subsystem coupled to said second, roll subsystem and
to a fourth azimuth subsystem, said azimuth subsystem defining a
central axis of the antenna system and being operable for providing
25 rotational movement of the first planar subsystem about the central
axis, the elevation subsystem being configured to provide a certain angular orientation between said plane defined by said active subsystem and a plane defined by the azimuth subsystem.

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According to another embodiment, the present invention provides for an antenna system accommodating onto a platform for tracking a target moving relatively to the platform, comprising:
- a first planar active subsystem operable for receiving/transmitting an
5 RF signal of a certain linear polarization direction;
- a second, roll subsystem coupled to said active subsystem and operable
for rotational movement of said active subsystem about a first axis
perpendicular to a plane defined by said planar active subsystem;
- a third, elevation subsystem coupled to said second, roll subsystem and
10 to a fourth azimuth subsystem, said azimuth subsystem defining a
central axis of the antenna system and being operable for providing
rotational movement of the first planar subsystem about the central
axis, the elevation subsystem being configured to provide an adjustable
angular orientation in a range of 0°-90° between said plane defined by
15 said active subsystem and a plane defined by the azimuth subsystem,
thereby allowing positioning said first planar active subsystem with respect to
said target such that said linear polarization direction is substantially aligned with
a linear polarization direction of RF radiation received and/or transmitted by the
target.
20 According to yet another embodiment, the present invention provides for a
method for tracking at least one target with an antenna system accommodating onto a platform moving relatively to the target, and having a planar active subsystem, the method comprising:
(i) receiving/transmitting an RF signal of a certain linear polarization
25 direction;
(ii) receiving and storing data regarding the position and polarization of
the target and the antenna system, constituting position and
polarization data;
(iii) in response to said position and polarization data, having the active
30 subsystem selectively performing azimuth rotational movement about

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a central axis of the antenna system, roll rotational movement about a
first axis perpendicular to a plane defined by the planar active
subsystem, and selectively adjusting the angular orientation in a range
of 0°-90° between the plane defined by the active subsystem and the
5 plane defined by the azimuth subsystem,
thereby allowing positioning said planar active subsystem with respect to said target such that said linear polarization direction is aligned with a linear polarization direction of RF radiation received and/or transmitted by at least one target.
10
BRIEF DESCRIPTION OF THE DRAWINGS
In order to understand the invention and to see how it may be carried out
in practice, a preferred embodiment will now be described, by way of non-
limiting example only, with reference to the accompanying drawings, in which:
15 Fig. 1 is a general side view (in cross section) of an antenna system
according to an embodiment of the invention;
Fig. 2 is a more detailed side view (in cross section) of an antenna system according to an embodiment of the invention;
Fig. 3 is an isometric partial view of a part of an antenna according to an 20 embodiment of the invention;
Fig. 4 is a general side view (in cross section) of an antenna according to another embodiment of the invention;
Fig. 5 is a general block diagram of an antenna system according to an
embodiment of the invention;
25 Figs. 6a-6c illustrate the principles of positioning and polarization
tracking according to an embodiment of the invention; and
Fig. 7 is a flow chart showing a sequence of operations carried out by a control unit according to an embodiment of the invention.

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DESCRIPTION OF A SPECIFIC EMBODIMENT OF THE INVENTION
According to certain embodiments, the present invention provides for a planar antenna and preferably a phased array antenna system to be disposed onto a platform, and preferably a moving platform (e.g. airborne platform) for
5 transmitting and/or receiving RF signal having linear polarization to and from at least one target moving relatively to the platform (e.g. geostationary satellite). The antenna system provides positioning capabilities as well as polarization tracking capabilities, thereby improving communication of RF signal having linear polarization between the platform and a target.
10 Fig. 1 is a general side view (in cross section) of an antenna system 10
according to an embodiment of the invention. Antenna system 10 includes, inter -alia, an azimuth driving subsystem 12 defining a horizontal axis B and a ZB axis perpendicular thereto (constituting the central axis of the antenna system). Antenna system 10 further includes a tilt driving subsystem 14 defining an axis A
15 and a ZA axis perpendicular thereto. Also shown is axis D, perpendicular to both B and ZB. A substantially planar active subsystem 16 is coupled to the tilt driving subsystem 14, along axis A, and is operable to perform electronic scanning within cone C (preferably providing scanning angle of ±60°). Axis ZA represents the bore sight of the antenna. The active subsystem 16 is connected to a roll
20 subsystem 18.
According to an embodiment of the present invention (shown in fig. 1),
antenna system 10 has four degrees of freedom, allowing it to selectively perform
electronic scanning, azimuth, and roll movements, as well as tilt adjustment as
required for positioning and polarization tracking, in the following manner:
25 - electronic scanning within scan cone C.
- the azimuth driving subsystem rotates the tilt driving subsystem 14 (and the active subsystem 16 accommodated thereon) around axis ZB.
- the tilt driving subsystem 14 rotates the active subsystem 16 around axis D, thereby tilting the active subsystem (axis A) with respect to
30 axis B.

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- the roll subsystem rotates the active subsystem 16 around axis ZA.
According to another embodiment of the invention, generally shown in
Fig. 4, a fixed tilt is provided, e.g. an angle in the range of 20°-30° between axis B and axis A. According to this embodiment, positioning as well as polarization
5 tracking are carried out based on movements in only three degrees of freedom, as follows:
- electronic scanning within scan cone C.
- the azimuth driving subsystem rotates the tilt driving subsystem 14
(and the active subsystem 16 accommodated thereon) around axis ZB.
10 - the roll subsystem rotates the active subsystem 16 around axis ZA.
As will be detailed further on, all degrees of freedom are controlled by a common control system (not shown in Figs. 1, 2 and 4) and operate in synchronization to provide positioning and polarization tracking. The selective nature of the dynamic operation of the various subsystems will be explained
15 further on, with reference to Fig. 7.
Turning back to the embodiment of the invention shown in Fig. 1: Fig. 2 is a more detailed side view (in cross section) of the antenna system 10 shown in Fig. 1. According to an embodiment of the invention, antenna system 10 incorporates an active subsystem 16 which comprises an electronically scanned,
20 substantially planar phased array antenna 15, e.g. as shown in Fig. 3. Antenna 15 is constructed from two interleaved arrays of radiating elements 73 and 75, orthogonal to each other, having linear polarization, designed to transmit and receive RF radiation in different frequency bends, respectively. According to an embodiment of the invention, the radiating elements are the known wide-band
25 Vivaldi antennas, which may be excited by a transmit module TX, receive module RX or a combination of TX and RX. (TX and RX modules are not shown in Fig. 3). As is known in the art, antenna 15 further comprises, inter alia, PCB 78, heat-sinks 80 and DC/DC converters 83. As is also known in the art, the two interleaved arrays 73 and 75, which have orthogonal linear polarization, are
30 suitable for communication purposes since transmitted and received beams have

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different frequencies, thus do not interfere with each other. According to an
embodiment of the invention, antenna 15 is designed for operating in the Ku-
band, e.g. transmission (from aircraft to satellite) in the 14-14.5 GHz band,
receiving (satellite to aircraft) in the 10.95-11.7GHz band.
5 Turning back to Fig. 2: the active subsystem 16 further accommodates roll
driving subsystem 18, comprising roll plate 28 to which the antenna 15 is connected. Roll plate 28 has a hollow shaft mounted on roll bearings 30 and is movable by roll motor 35 and pinion 38. Roll subsystem 18 is thus designed to provide roll movement (i.e. rotate around axis ZA, as shown in Fig. 1), thereby
10 allowing antenna 15 to keep matching its linear polarization to that of the tracked satellite. According to an embodiment of the invention, the roll movement is limited to +180°. The Antenna 15 is fed via e.g. a rotary-joint slip-rings block (not shown), assembled in the hollow shaft, or by flexible cables (not shown).
As known in the art with respect to electronically scanned phased array
15 antennas, better antenna performance is achieved by maintaining the elevation angle above the plane of the array above a certain value, typically about 30° or less. Therefore, according to one embodiment of the invention, a tilt angle of up to ±30°, is combined with an azimuth movement for yielding elevation coverage of ± 90°, as follows.
20 Tilt subsystem 14 (shown in Figs. 1 and 2) comprises a tilt base 32, to
which is connected the radiating subsystem 16, via the roll subsystem 18. Tilt base 32 is movable around tilt axis D, e.g. by a motor-gear unit (not shown), coupled with a gear, (not shown), attached to tilt shaft 42. Tilt subsystem 14 is connected to the azimuth subsystem 12 by side plates 45 via tilt bearings (not
25 shown).
Azimuth driving subsystem 12 (shown in both Figs. 1 and 2) comprises azimuth turntable 48, rotatable around axis ZB. According to an embodiment of the invention, azimuth turntable 48 has a hollow shaft, on which azimuth bearings 50 are installed. Azimuth bearings 50 are carried by pedestal base 52,
30 which is used to install the antenna 10 onto the mounting base of the moving

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platform (e.g. an aircraft). Azimuth movement is achieved by azimuth motor 55
and azimuth pinion 58 meshed with azimuth gear 65. A rotary joint-slip rings
block 63 is attached to the hollow shaft of the azimuth table 48, to allow
conveying RF radiation and electricity.
5 The azimuth, tilt and roll driving subsystems (elements 12, 14 and 18) are
coupled to and controlled by a control system (not shown in Figs. 1 and 2). The common control system and its operation will be discussed further on with reference to Figs. 5 to 7.
As is clear to a person versed in the art, digital, mechanical, or other servo
10 components, as well as encoder components (not shown in Fig. 2) used for controlling the various movements, can readily be integrated in the system. It should be understood that the invention is not limited by the type and kind of drivers (motors, gears, etc.) used, and other driving components, such as pancake torque motors directly mounted onto the shafts, can be appropriately used
15 without departing from the scope of the invention.
When used in aircrafts, the antenna system of the present invention can be implemented as a relatively small and low profile system (e.g. diameter of about 90cm or less, height of about 40cm or less). The system can be flatly mounted e.g. on the crown of the aircraft, thereby providing the aircraft with improved
20 communication capabilities without harming the aerodynamic design of the aircraft.
Turning now to Fig. 5 there will follow a description of the common control system mentioned above. Fig. 5 is a block diagram of an antenna system 100 according to the embodiment of the invention shown in Fig. 1. As mentioned
25 before, antenna system 100 is mounted on-board a moving platform (e.g. an aircraft) and is used for communication with a moving target (e.g. a satellite). As shown the active subsystem 110, roll driving subsystem 120, tilt driving subsystem 130 and azimuth driving subsystem 140 are all coupled to a common control system 150. The control system 150 comprises, inter-alia, a central

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processing unit (CPU) 160 and a memory 170 coupled to the CPU. Note that the invention is not limited to the exemplary configuration of the control system.
Control system 150 is connectable to external systems not shown in Fig. 5 (e.g. data systems accommodated onto the moving platform (e.g. global
5 positioning system (GPS), inertial navigation system (INS), localization system and the like) for receiving position data. Control system 150 accommodates a data input module 180 coupled to the CPU 160 and configured for providing position data relating to the relative position of the moving platform with respect to the moving target. Control system 150 further accommodates a positioning
10 and polarization tracking module 190 coupled to the CPU 160 and configured for providing control signals for driving the active, roll, tilt and azimuth subsystems 110-140.
The principles of positioning and polarization tracking according to an embodiment of the invention will now be detailed with reference to an exemplary
15 scene and exemplary control parameters shown in Figs. 6a-6c. Fig. 6a shows the moving platform, aircraft 202 in this exemplary scene, and the aircraft's coordinate system 204 used for describing the movements of the antenna system according to an embodiment of the invention, in which X axis starches along the aircraft's wings; Y axis starches along the aircraft's body; and Z axis is
20 perpendicular to X and Y. The antenna system is mounted on top of the aircraft 202 and therefore, with reference to Figs. 1 and 3, Z axis shown in Fig. 6a is axis ZB, the center axis of the antenna. The top of the scanning cone (element C shown in Fig. 1, not shown in Fig. 6a) located on the surface of the active subsystem (element 15 shown in Fig. 1) and along the center axis of the antenna
25 is the origin O of the coordinate system 206. Also shown in Fig. 6a is a moving target, satellite 206 in this exemplary scene. The position of the satellite 206 is defined by its position vector S, represented by 9S (the angle between S axis and Z axis), and the angular components ax, av and az.
Fig. 6b illustrate the cone of broadside directions AC of the antenna
30 system, resulting from a 360° rotation of the active subsystem (element 16

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shown in Fig. 1) by the azimuth subsystem (element 12 shown in Fig. 1). In other words, the cone of broadside directions AC is the result of a 360° rotation of axis ZA about axis ZB (both shown in Fig. 1). The solid angle T of the cone AC equals to the angular orientation (the so-called 'tilt') between plains A and B
5 (shown in Fig. 1), as detailed above with reference to Figs. 1 and 3. Note that by one embodiment, of the invention, T is changeable (e.g. as shown in Fig. 2). By another embodiment, T is fixed (e.g. as shown in Fig. 3).
Fig. 6c illustrates an exemplary set of control parameters and a desired disposition of the antenna system mounted onboard the aircraft with respect to
10 the satellite, in which the linear polarization direction of the antenna system is aligned with that of the satellite. There are shown:
qS: the angle between S and the central axis of the antenna (ZB);
T: the tilt angle of the broadside (ZA) with respect to the central axis of
the antenna (ZB);
15 qscan: the solid angle of scanning cone C shown in Fig. 1;
S: the position vector of the satellite, represented by (ax, ay, az), (aq, ap); V: the broadside vector of the antenna (pointing along ZA, the central
axis of the antenna), represented by
According to one embodiment of the invention, in the desired disposition,
20 V lays at ZB-S plane. During the relative movement of the aircraft and the
satellite, 9s may vary from zero to 90°. In order to keep the linear polarization
direction of the antenna aligned with that of the satellite, qscan is required to
follow the following relations:
(1) qscan ³9S - T if 9S > T, or
25 (2) qscan £ 9S - T if 9S In other words, in the desired disposition, S passes through the scanning
cone C while substantially intersecting the cone top. According to another
embodiment of the invention, in the desired position S substantially coincides
with the center axis of the scanning cone to yield minimal scanning angle, up to
30 zero (no scanning is required).

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In order to achieve the desired disposition of the antenna system with
respect to the satellite, the following sequence of operations 300 shown in Fig. 7
is carried out by the common control unit in a cyclic manner (element 150 shown
in Fig. 5) according to an embodiment of the invention:
5 In operation 310: receiving and storing the position and polarization of the
satellite (e.g. using lookout tables), and the position and polarization of the antenna (e.g. using data received from the host aircraft's systems), constituting position and polarization data of the current cycle of operation. Note that the position and polarization data can be achieved from various sources, e.g.
10 localizer of the moving target, GPS (Global Positioning System) system, INS (Inertial Navigation System) system, altitude system measuring the altitude of the moving platform, encoders measuring the changes in position of the azimuth, roll and tilt subsystem, and more. Note that the invention is not bound by the type of information, and the manner used for detecting the position and polarization of
15 the satellite and the antenna and evaluating their relative disposition in a timely manner. Also, note that the invention is not bound by the specific set of control parameters that are used. Using the coordinate systems shown in Figs. 6a-6c, at this stage the following control parameters are defined in a manner known per

20 In operation 312: the current control parameters are checked e.g. if no
previous data regarding this satellite is stored, or that current data differs from stored data, indicating that a certain adjustment of one of the degrees of freedom is required.
In operations 314, 316 and 318: the specific control parameters per
25 subsystem are evaluated, e.g. as described further below. Note that the invention is not bound by the specified control parameters and relations, and others may be used.
In operation 320: if needed (as evaluated in operations 314, 316 and 318), providing azimuth and roll rotation, and if possible and needed, providing tilt
30 rotation. Note that the relative position and polarization of the satellite and the




aircraft is dynamic, due to the relative movement of the satellite and the aircraft, and therefore at any instance in which new position and polarization data is received, the need for azimuth, roll and if possible - tilt adjustments is evaluated.
The azitnuth adjustment (carried out by e.g. the azimuth driving subsystem 12,
5 shown in both Figs. 1 and 2) is performed in order to rotate the broadside (ZA) to the
ZB-S plain. Therefore, the required asimuth adjustment equals the change, in the relative
displacement of the aircraft and the satellite, when projected over the ZB-S plain.
According to an embodiment of the invention, the azim adjustm.c-.nt is
provided and follows relation (3):
10

The roll adjustment (carried out by the roll driving subsystem 18 siown in Figs.
1 and 2) is performed in order to adjust the direction of polarization of the antenna
according to changes in the direction of the polarization of the satellite. According to an
embodiment of the invention, the roll adjustment cVou is provided if (cte, a,,) £ (aW9,



As described above with reference to Fig. 1, the angle T may be changed (by use
of the driven subsystem 14 as shown in Fig. 1). In mis embodiment, tilt adjustment can
be performed in order to provide minimum scanning angle (preferably achieved at 65 a
20 T). Therefore, the required tilt adjustment Stat may provide a new tilt angle T such that
minimum function min(0s - T) will follow the relation:


According to another embodiment, the tilt adjustment is defined as the minimum that is required such that 65 - T is equal to or less than a predetermined value (e.g. in
25 the range of 60*- 70°), It should be appreciated that hit adjustment may be required only if qs extends a predetermined value (e.g. in the range of 60°- 70°). W should also be appreciated mat other considerations for defining the required tilt adjustment may be applied, e.g. limiting the tilt angle to fell between
deceived at the EPO on Mar 29, 2007 17:22:12. Pi AMENDED SHEET

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20°-30°, and more. Furthermore, the invention can be applied with a fixed tilt angle, as shown in Fig. 2, and in such an implementation, no dynamic tilt adjustment is provided at all.
In operation 330: if needed (checked in operation 326), perform electronic
5 scanning. Note that no electronic scanning is required when the broadside of the antenna coincides with the satellite position vector S. in other words, electronic scanning is performed if 0S ^ T.
Referring now to Fig. 7 in combination with Fig. 5: according to an embodiment of the invention illustrated above, operation 310 is performed by the
10 data input module (element 180), and operations 312-330 are carried out by the position and polarization tracking module (element 190).
It should be appreciated that the invention is not bound by the specific considerations exemplified herein with reference to Fig. 7 in order to illustrate one embodiment of the invention, and other considerations can apply, with the
15 necessary modifications, without departing from the scope of the invention.
The present invention was described with relation to a transmit/receive antenna and RF radiation of a certain linear polarization. It should be appreciated that the present invention is equally concerned with transmit antenna or receive antenna, and RF radiation of non-linear polarization, with the appropriate
20 modifications.
The invention was described mainly with reference to communication between an aircraft and a geostationary satellite. It should be noted that the invention is not limited by the type of moving platform onto which the antenna system is mounted, e.g. ships, land vehicles and more. Furthermore, the present
25 invention was described in details with respect to communication of RF signal having linear polarization between a moving platform and a target. It should be appreciated that the concepts and principles of the invention can also be implemented for communication of RF signals having linear polarization between a fixed platform and a moving target or vice versa (moving platform and
30 fixed target), or moving platform and moving target, with the appropriate

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modifications and alterations, without departing from the scope of the present invention.
It should also be appreciated that the present invention can be implemented by using only three degrees of freedom as follows (the following
5 reference numbers refer to Fig. 1):
- an azimuth driving subsystem (element 12 in Fig. 1) that rotates the tilt
driving subsystem (element 14 in Fig. 1) and the active subsystem
(element 16) accommodated thereon around axis ZB.
- a tilt driving subsystem 14 that rotates the active subsystem 16 around
10 axis D, thereby tilting the active subsystem (axis A) with respect to
axis B by a tilt angle T, wherein 0 - a roll subsystem that rotates the active subsystem 16 around axis ZA.
As described with reference to operation 320 shown in Fig. 7, by
providing a tilt angle in the range of 0 15 can be minimized, up to 9s=0. In other words, by using dynamic adjustment of the tilt angle T, according to an embodiment of the present invention, it is possible to maintain position and polarization tracking without the need to perform electronic scanning. Preferably, this embodiment is useful for an antenna system for tracking moving targets, mounted onto fixed platforms, land vehicles,
20 ships and more.
It should be appreciated that the antenna system according to the invention
may be used as a radar, an electronic counter measures (ECM) system or as a
communication antenna, such as two-way broadband data communication via
satellites having linear polarization mode.
25 Those skilled in the art to which the present invention pertains, can
appreciate that while the present invention has been described in terms of certain embodiments, the concept upon which this disclosure is based may readily be utilized as a basis for the designing of other systems, services and processes for carrying out the several purposes of the present invention.

WO 2006/057000 PCT/IL2005/001272
20
lt will also be understood that the system according to the invention may be a suitably programmed computer system. Likewise, the invention contemplates a computer program being readable by a computer for executing the method of the invention. The invention further contemplates a machine-
5 readable memory tangibly embodying a program of instructions executable by the machine for executing the method of the invention.
Also, it is to be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting.
It is important, therefore, that the scope of the invention is not construed as
10 being limited by the illustrative embodiments and examples set forth herein. Other variations are possible within the scope of the present invention as defined in the appended claims and their equivalents.



CLAIMS;
1. A-method for operating a phased array antenna system accommodated
onto a platform moving relatively to at least one target, the method comprising:
(i) providing a planar active subsystem. (1.6) with an azimuth rotational
movement about a central axis (Za) of the antenna system and a roll
rotational movement about a first axis (ZA) perpendicular to a plane
(A) defined by the planar active subsystem (16);
(U.) dynamically receiving from data systems of the platform, and
storing position data regarding position of the target and the
antenna system, and polarization data regarding linear polarization
direction of RF radiation, received and/or transmitted by the target
and the antenna system, respactively;
(iii) in response to said position data, having the active
subsystem (16) selectively performing azimuth adjustment and in
response to said polarization, data, having the active subsystem (16)
selectively performing roll adjustment, as required; and
(iv) unless not required, performing electronic scanning within a
predefined scanning cone coaxial with said first axis (ZA). thereby ensuring that linear-polarization direction of RF radiation received and/or transmitted by the antenna system is substantially aligned with linear polarization direction of RF radiation received and/or transmitted by the target, and facilitating tracking of the target by the antenna system.
2, A method according to Claim. 1 further comprising, in response to said
position, providing a tilt angle (T) between the plane (A) defined by the active subsystem (16) and the plane (B) perpendicular to the central axis (Z*) of the antenna system.





3. A method according to Claim 2 further comprising, selectively adjusting said tilt angle T in case it is different from an orientation 9S of the target with respect to the central axis of the antenna.
4. A method according to Claim 2 or 3, wherein said tilt angle T is selected in accordance with one of the following conditions:

- T is in a range of 0°-90°;
- 6S-T is equal or less than a predetermined value: and
- If is substantially equal to 9S.
5. A;metbod according to any one of claims 1 to 3 wherein, with respect to
a coordinate system corresponding to the central axis (Z©) of the antenna and said
plane (B) perpendicular thereto, said target is associated with a target vector (S)
having angular position parameters (aXs ay, az) and polarization direction,
parameters (ao, amp) and the active subsystem (16) is associated with position
parameter corresponding to the first axis (Z^) and polarization
direction parameters and wherein at least one of the following is
performed:


6. A phased array antenna system accommodated onto a platform for
tracking a target moving relatively to the platform, comprising:
- a planar active subsystem (16) operable for receiving/transmitting an RF signal of a certain linear polarization direction and for selectively performing electronic scanning;
- a roll subsystem (18) coupled to said active subsystem (16) and Operable for rotational movement of said active subsystem about a first
0)638592\43-0l
Received at the EPO on Apr 01,2007 15:09:25. Pa AMENDED SHEET



axis (ZA) perpendicular to a plane (A) defined by said planar active
subsystem (16); and
- •an azimuth subsystem (12) defining a central axis (ZB) of the antenna system and being operable for providing rotational movement of the planar subsystem (16) about the central, axis (ZB)5; and
- a common controller (150) connectable to data systems of the platform and coupled to ar least said planar active subsystem (16), roll subsystem (18) and azimuth, subsystem (1.2) and configured for operating said active subsystem (16). roll subsystem (18) and azirouth Subsystem (12) subsystems by performing at least {the following operations:
(a) receiving from data systems of the platform and storing position data regarding the position of the target and the antenna system and polarization data regarding a linear polarization direction of RF radiation received and/or transmitted by the target and the antenna system; and
(b) in response to said position data, selectively providing said azimuth subsystem (1.2) with control signals for having the active subsystem (16) selectively performing azimuth adjustment about the central axis, and in. response to said polarization data, selectively providing said roll subsystem (18) with control signals for having the active subsystem (16) selectively performing roll adjustment about the first axis, as required, and providing said planar active subsystem (16) with, control signals, such that electronic scanning, if performed, is performed within a predefined scanning cone coaxial with said first axis !(ZA),
thereby ensuring that linear polarization direction of RF radiation received and/or transmitted! by the antenna system is substantially aligned with linear polarisation direction of RF radiation received and/or transmitted by the target.
i


7. The phased array antenna system according to Claim 6 further comprising an elevation subsystem (14) coupled to said roll. subsystem (18) and said azimuth subsystem (12), the elevation subsystem, being [configured to provide aj certain tilt angle (T) between said plane defined liy said active subsystem (16) and a plane (B) defined by the azimuth subsystem i(l 2).
8. The phased array antenna system according to Claim 6 or *7 wherein said common Control subsystem (150) comprises:

- a Central Processing Unit (CPU);
- a memory coupled to the CPU;
- a data input module coupled to said CPU and connectable to data. systems of said platform,, for inputting data relating to the relative position of said platform with respect to said target; and'
- a. positioning and polarization tracking module coupled td the CPU and configured for dynamically operating at least said roll subsystem (18) knd azimuth subsystem (12).
i
9. The antenna system according to Claim 8 wherein said data input module
is configured to dynamically receive at least one data item from the following
group of data items: relative disposition of the platform and the target, location of
the target,! GPS (Global Positioning System.) data, INS (Inertial Navigation
System) data, altitude of the platform, position data of said roll subsystem (18);
position data of said elevation subsystem (14); position data of said azmiuth
subsystem i( 1.4).
10. An antenna system according to any one of claims 6 to 9\ wherein said
elevation subsystem (14) being configured to provide a fixed tijlt angle (T)
between said plane (A) defined by said active subsystem (16) and .the plane (B)
defined by the azimuth subsystem (12).







11. Ah antenna system according to Claim 10 wherein said predefined
scanning cone provides scanning angle of about ±70° about the bore sight of the
active subsystem.
i I
12. Aid antenna system according to any one of claims 6 to lb wherein said elevation Subsystem (14) being configured to provide a controllably changeable tilt angle (T) between said plane defined by the active subsysten (16) and the plane (B) defined by the azimuth subsystem.
13. An antenna system according to Claim 12 wherein said common cgntrooller (150) is further configured for controlling the operation of said elevation, subsystem (14), thereby allowing selective adjustment of, said scanning
cone.
i
14. An antenna system according to Claim 12 wherein -said changeable tilt
angle (T) Is changed ID case it is different from an orientation qs of the target
with respect to the central axis of the antenna. ;
i |
15. An antenna system according to Claim 14 wherein said tilt angle (T) is
selected inaccordanee with one of the Following conditions:
- f is in a range of 0o-90°; i
- qS-T is equal or less than a predetermined value; and
- T is substantially equal to 0S.
16. An antenna system according to any one of claims 6 to 15, Wherein, with respect to b coordinate system corresponding to the plane (B) defined by the azimuth, subsystem (1.4) and the central axis (Zg) of the antenna, said target is associated with a target vector (S) having angular position parameters (ax. ay, az) and polarization direction parameters (aq, aj) and the active subsystem (16) is
0J63859Z\43-dl deceived at the EPO on Apr 01J2007 15:09:25. Pa AMENDED SHEET




associated with position parameters corresponding to the first axis (ZA) and, polarization direction parameters ; and wherein at least one of the! following is performed
17, Ah antenna system according to any one of claims 6 to 16 wherein said
platform i$ an airborne platform,
18. An antenna system according to any one of claims 6 to J.7 wherein said
target is a geostationary satellite.



27
ABSTRACT
"PHASED ARRAY PLANAR ANTENNA FOR TRACKING A MOVING TARGET AND TRACKING METHOD"
A phased array antenna system accommodating onto a platform for tracking a target moving relatively to the platform, the antenna system comprising a first planar active subsystem operable for receiving/transmitting an RF signal of a certain linear polarization direction and for selectively performing electronic scanning; a second, roll subsystem coupled to the active subsystem and operable for rotational movement of the active subsystem about a first axis perpendicular to a plane defined by the planar active subsystem; a third, elevation subsystem coupled to the second, roll subsystem and to a fourth azimuth subsystem, the azimuth subsystem defining a central axis of the antenna system and being operable for providing rotational movement of the first planar subsystem about the central axis, the elevation subsystem being configured to provide a certain angular orientation between the plane defined by the active subsystem and a plane defined by the azimuth subsystem, thereby allowing positioning the first planar active subsystem with respect to the target such that the linear polarization direction is substantially aligned with a linear polarization direction of RF radiation received and/or transmitted by the target.

Documents:

988-mumnp-2007-abstract.doc

988-mumnp-2007-abstract.pdf

988-MUMNP-2007-CLAIMS(AMENDED)-(9-1-2014).pdf

988-mumnp-2007-claims.pdf

988-MUMNP-2007-CORRESPONDENCE(16-9-2013).pdf

988-MUMNP-2007-CORRESPONDENCE(2-8-2012).pdf

988-MUMNP-2007-CORRESPONDENCE(25-3-2008).pdf

988-MUMNP-2007-CORRESPONDENCE(26-11-2008).pdf

988-MUMNP-2007-CORRESPONDENCE(7-8-2012).pdf

988-mumnp-2007-correspondence-received.pdf

988-mumnp-2007-description (complete).pdf

988-MUMNP-2007-DRAWING(9-1-2014).pdf

988-mumnp-2007-drawings.pdf

988-MUMNP-2007-FORM 1(25-3-2008).pdf

988-MUMNP-2007-FORM 1(7-8-2012).pdf

988-MUMNP-2007-FORM 13(7-8-2012).pdf

988-MUMNP-2007-FORM 18(26-11-2008).pdf

988-MUMNP-2007-FORM 2(TITLE PAGE)-(29-6-2007).pdf

988-MUMNP-2007-FORM 26(25-3-2008).pdf

988-MUMNP-2007-FORM 26(9-1-2014).pdf

988-MUMNP-2007-FORM 3(16-9-2013).pdf

988-MUMNP-2007-FORM 3(2-8-2012).pdf

988-MUMNP-2007-FORM 3(25-3-2008).pdf

988-MUMNP-2007-FORM 3(9-1-2014).pdf

988-mumnp-2007-form-1.pdf

988-mumnp-2007-form-2.pdf

988-mumnp-2007-form-3.pdf

988-mumnp-2007-form-5.pdf

988-mumnp-2007-form-pct-ipea-409.pdf

988-mumnp-2007-form-pct-ipea-416.pdf

988-mumnp-2007-form-pct-isa-220.pdf

988-mumnp-2007-form-pct-isa-237.pdf

988-mumnp-2007-form-pct-separate sheet-237.pdf

988-mumnp-2007-form-pct-separate sheet-409.pdf

988-MUMNP-2007-MARKED COPY(9-1-2014).pdf

988-MUMNP-2007-OTHER DOCUMENT(16-9-2013).pdf

988-MUMNP-2007-OTHER DOCUMENT(9-1-2014).pdf

988-mumnp-2007-pct-search report.pdf

988-MUMNP-2007-PETITION UNDER RULE-137(9-1-2014).pdf

988-MUMNP-2007-PETITION UNDER RULE-137-(9-1-2014).pdf

988-MUMNP-2007-REPLY TO EXAMINATION REPORT(9-1-2014).pdf

988-MUMNP-2007-SPECIFICATION(AMENDED)-(9-1-2014).pdf

988-MUMNP-2007-WO INTERNATIONAL PUBLICATION REPORT(29-6-2007).pdf

abstract1.jpg


Patent Number 259938
Indian Patent Application Number 988/MUMNP/2007
PG Journal Number 14/2014
Publication Date 04-Apr-2014
Grant Date 29-Mar-2014
Date of Filing 29-Jun-2007
Name of Patentee ELTA SYSTEMS LTD.
Applicant Address 100 SDEROT ITZHAK HANASIE, P.O.B. 330, ASHDOD
Inventors:
# Inventor's Name Inventor's Address
1 SAMSON CLAUDE 3 ASAVION STREET, 76568 REHOVOT
2 ILUZ ZEEV 19/2 REVIVIM STREET, 70800 GAN-YAVNE
3 GAFNI AMNON 25 SDEROT CHEN,76253 REHOVOT
PCT International Classification Number H01Q1/18 H01Q3/10
PCT International Application Number PCT/IL2005/001272
PCT International Filing date 2005-11-29
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10/998,155 2004-11-29 U.S.A.