Patent Description:
Conformal antennas typically utilize a phased array of antenna elements, where each antenna element is driven by a controlled phase shifter, to provide directionality of radiation pattern of the antenna. Hence, the antenna can transmit radiation mainly in a prescribed direction (particular target zone), and be sensitive to the signal from the particular target while rejecting interfering signals from other directions. In a conformal antenna, the antenna elements are mounted on a curved surface, and therefore the phase shifters operate to compensate for the different phase shifts caused by the varying path lengths of the radiation waves due to the location of the individual antenna elements on the curved surface.

<CIT> describes a cylindrical antenna array system having two cylindrical subarrays flush mounted on a conducting cylinder, each consisting of a plurality of linear phased arrays fed through a pair of feed rings on the conducting cylinder that has a diode switch for each linear phased array coupled through a switching network to switch one-quarter to one-third of the linear phased arrays ON in a rotating manner to scan throughout <NUM>° around the cylinder axis, and each linear phased array having a pair of rotatable dielectric slabs behind the waveguide slots thereof with all dielectric slabs mechanically coupled to rotate in synchronism to phase the radio waves for angular direction with respect to the cylinder axis, the received signals being coupled through a magic-T j unction to provide sum and difference monopulse signals of targets in sight of the antenna.

<CIT> describes a system utilizing a transmission--reception radar antenna protected by a radome and an interrogation antenna having at least one set of two networks engaged laterally on the outer wall of the radome. The networks are arranged symmetrically to an axis of revolution of the radome. Supply means supply the interrogation antenna with an ultra-high frequency interrogation signal and the switching and phase-displacement means and the networks constitute an electronic scanning antenna.

<CIT> describes a wideband electronically scanned cylindrical array includes an array of end-fire radiating elements, the elements arranged in a first plurality of columns, the columns arranged radially about a center axis of the array. A beamforming network is connected to the array of radiating elements. The beamforming network includes a power divider circuit for dividing an input RF drive signal into a second plurality of drive signals, and a matrix of electronically controlled transfer switches. A true time delay network comprising a third plurality of delay lines couples respective ones of the drive signals to the matrix of transfer switches. A third plurality of transmit amplifiers is coupled to the matrix of transfer switches, each amplifier for amplifying a respective one of the drive signals. The beamforming network further includes apparatus for coupling the amplified drive signals to selected ones of the columns of radiating elements. A beamforming controller is connected to the coupling apparatus and the matrix of transfer switches for selecting sectors of the columns of radiating elements to be driven by the drive signals to form a desired beam. The columns of radiating elements are arranged in a circularly symmetric fashion about the axis in the disclosed embodiment.

<CIT> describes systems and methods for use in a vehicle. A vehicle can be an aircraft, truck, ship, automobile, locomotive, etc. A system includes a housing having an exterior surface for housing sensor or communication equipment and interior surface for housing electronics associated with the equipment. The sensor or communication equipment can include a radar antenna mounted on or adjacent to the exterior surface, and at least one of a Satcom antenna, altimeter antenna, vision sensor or any communication link antenna. <CIT> describes a conformal antenna array. Embodiments of the present invention provide a transceiver for communicating data in a cell site of a wireless communication system. The transceiver includes the conformal antenna array including a plurality of antenna elements, where the plurality of antenna elements has a non-linear antenna configuration to occupy at least two dimensions, and a controller configured to transmit multiple beamforming signals using at least two same antenna elements of the plurality of antenna elements.

<CIT> describes an improved antenna system that, in one embodiment, includes an antenna array comprised of a plurality of elements, each of which is capable of providing a signal. Also included in the improved antenna system is, a multi-beam beamformer for producing two spatially independent overlapping beams from the signals provided by two different subsets of the antenna array. The phase of the two beams is compared to realize an interferometer that can provide high or fine resolution data on the position of an object relative to the antenna system. The amplitude of the two beams can also be compared to obtain coarse data on the position of the object. The beamformer includes a switching network for selecting which elements of the antenna array form the two subsets. This permits, for example, the position of the beams to moved, the baseline of the two beams to be varied, and/or the beam width of the beams to be altered. To reduce adverse aerodynamic effects in certain applications, the antenna array is located conformal to the exterior surface of the body on which the array is mounted. Further, to reduce temperature related problems associated with high speed movement of the body on which the array is located, the array is located on the side of the body, as opposed to the front of the body. The side location also provides space for other types of sensors that are preferably located adjacent to the front surface of the body.

There is a need in the art for a novel configuration of a conformal antenna unit, which can be placed at the front end of platforms and is capable of providing maximal performance in a generally forward-looking direction relative to the platform nose, as well as electronic steering of the antenna beam within a wide angular range, for a wide range of frequencies (e.g. <NUM>%-<NUM>% band width with respect to the central frequency).

In particular, there is need for such antenna which can be placed on platforms having relatively small cross sectional size (diameter), e.g. of about <NUM>-<NUM> wavelengths. In this connection, it should be noted that the conventional approach of conformal antenna configuration makes it difficult, if not impossible, to use such antenna at the small-diameter front end of the platform. This difficulty is associated with a need to deal with a small-diameter conformal antenna and radome effects on the antenna beam.

A conventional conformal antenna with electronic steering property typically has an antenna boresight substantially perpendicular to the antenna surface (i.e. to the surface of the platform carrying such conformal antenna). Antenna boresight is the axis of maximum gain (maximum radiated power) of a directional antenna, and for most antennas the boresight is the axis of symmetry of the antenna. Phased array antennas can electronically steer the antenna beam, changing the angle of the boresight by shifting the relative phase of radiation emitted by different antenna elements. For conformal antennas with generally forward-looking direction, the wide angular range of antenna beam steering is required, i.e. about <NUM>-<NUM> degrees, which significantly affects the antenna performance. Further, conventional conformal antenna allows only partial space coverage, usually around the side of the platform on which such antenna is placed. Even if the antenna is almost spherical, different groups of antenna elements are involved for operation in different space segments. Hence, in order to increase the space coverage up to <NUM> degrees around the platform, two or more antenna are used each for operating in a space segment, which complicates the entire antenna system and makes it more expensive.

The present invention provides a novel conformal antenna unit, which solves that above described problem of limited operational volume (space coverage) of the conventional antennas, which is more critical for the use of antenna at the front end of the platform for generally forward-looking direction of the antenna.

The antenna unit of the invention is configured and operable as an end-fire traveling wave antenna. The antenna unit includes at least one phased array of end-fire antenna elements. The antenna elements of the array are arranged in a spaced-apart relationship along at least a portion of the circumference of the platform carrying the antenna, or preferably along a closed-loop circumferential path conforming the circumference of the platform carrying the antenna. The antenna unit may include more than one such phased arrays arranged concentrically in a spaced-apart relationship along a longitudinal axis of the platform.

The antenna elements of the array may be equally spaced from one another along the circumferential path. Considering a substantially cylindrical or generally conical geometry of the front portion of the platform, on which the antenna is placed, the antenna array(s) are appropriately spaced from the front end (cone tip / apex).

The number N (N≥<NUM>) of the antenna elements in the array is appropriately selected in accordance with the platform diameter (generally, cross-sectional dimension) at the respective location of the array with respect to the front end (tip) of the platform and the required distance between the adjacent antenna elements in the array. It should be understood that the larger the number N of the antenna elements in the array, the higher is the gain and the steering angle of the array, as well as the better control of the radiation pattern of the array with regard to sidelobes' arrangement.

Considering multiple antenna arrays spaced from one another along the longitudinal axis of the platform of the conical geometry, the number of the elements in the array increases with the array's distance from the cone tip. It should also be understood that the larger the number M of such spaced-apart arrays, the higher is the gain and better is the radiation pattern of the antenna, for a given steering angle of the antenna operation.

Each of the antenna elements emits radiation of linear polarization. Phases of the antenna elements of the array are controlled in accordance with the required angular direction of the antenna beam of the entire array. For the forward direction operation of the antenna (substantially zero-steering), a phase shift, Δφ=φi-φi+<NUM>, between the phases of ith and (i+<NUM>)th neighboring antenna elements in the array of n antenna elements is determined as Δφ=2π/n. For example, for <NUM>-element array, the phase shift between two sequential antenna elements in the direction along the circular path is <NUM> degrees, and for the <NUM>-elements array, the phase shift is <NUM> degrees. For small-angle steering, i.e. from zero to about <NUM> degrees of angular range of steering, phases of the antenna elements are shifted/controlled to be substantially the same for circular polarization. For relatively large-angle steering, e.g. angular range higher than <NUM> degrees, the phases of all the elements in the array are controlled to be substantially the same for arbitrary linear polarization.

As will be described more specifically further below, a need for such a phase shift between the successive antenna elements is associated with the fact that in the antenna configuration of the invention, each antenna element is an end-fire type antenna, namely the antenna element boresight (the axis of maximum gain of the antenna element) is substantially parallel to the surface of antenna element or, in other words, substantially along the axis an elongated antenna element, rather than perpendicular to it. The polarization components of the radiation emitted by the antenna element are perpendicular to the boresight direction. Hence, in order to provide boresight of the antenna array in the desired direction while effectively utilizing the radiation emitted by all the antenna elements in the array, the above-described phase shift between the successive elements is controllably maintained.

As also will be described further below, with the above-described configuration of the phased array(s) of antenna elements, the antenna elements may be placed on / incorporated in a metallic body/surface, preferably such that the antenna array(s) is/are spaced from the front end (tip) of the platform by a metallic tip (cinder or cone, as the case may be) which actually operates as a radiating element, positively contributing to the antenna radiation pattern. The longitudinal dimension of the front end portion or tip portion, i.e. a distance from the tip to the antenna array (<NUM>st antenna array), as well as such geometrical parameters as a distance between the antenna elements in the array, and a distance between the adjacent arrays (if more than one array is used), are appropriately selected in accordance with an operational frequency band of the antenna and the geometry/dimension of the conical platform on which the antenna is to be mounted.

It should be noted that the antenna elements of different arrays may be different in geometry (i.e. lateral dimension and/or thickness and/or length). The geometrical parameters of the antenna elements of the different arrays may be optimized to enable the antenna operation with higher steering angles. For example, proper selection of such parameters provides for optimizing coupling between all the antenna elements to optimize (increase) the steering angles, which is more expressive when arranging the antenna elements of multiple arrays on a platform portion having a conical body; and proper variation of the size of the antenna element to optimize the coupling is more essential for the case of a tubular body of the platform portion carrying the antenna.

Additionally or alternatively to the optimization of the geometry of the antenna elements, the number of arrays, and the number(s) of elements in the array(s), the coupling between the antenna elements can be further optimized / controlled by arranging the antenna elements of the adjacent arrays in a chess-like fashion. This also allows for decreasing a gap between such arrays.

Further, it should be noted that in order to even more increase the steering angle of the antenna up to <NUM>° or higher (up to <NUM>°), one or more additional antenna elements can be provided on the platform body configured with a boresight substantially perpendicular to the longitudinal axis of the platform body. For example, this may be a ring-like antenna or an array of two or more discrete controllably switchable phased arrays of antenna elements.

The antenna device may also include phase sifter circuits, which may be analogue or digital circuits.

In some embodiments, the platform, in addition to the above-described antenna device, may include one or more additional sensors which may be optical and/or RF sensors. This would add additional frequency channel(s) to the entire sensing system.

Thus, according to an aspect of the invention, it provides an antenna device, as disclosed in appended claim <NUM>.

The antenna body may be of a substantially cylindrical shape or substantially conical shape or substantially spherical shape. The antenna unit is spaced a predetermined distance from a base region of the cylindrical antenna body or apex region of the conical antenna body. Such "base region" or "apex region" is at times referred to hereinbelow as a tip portion/end of the body. The antenna body may be made of a metallic material.

Generally, the antenna body of a conformal antenna of the present invention may be of any required geometry, and the arrangement of antenna array(s) on the body may be of any suitable configuration. For example, the antenna body may be of a conical geometry, or of a tubular like geometry; or may have a distal portion of a conical-like geometry and a proximal portion of a tubular-like geometry. In the latter configuration, the antenna elements may be located within the distal portion and/or the proximal portion.

It should be noted that, although in the description below the "closed-loop path" is at times referred to as a "circular path", the invention is not limited to a circular cross section of the antenna body, and this expression should therefore be interpreted broadly, covering any curved-surface geometry of the antenna body, e.g. circular, oval-like, polygonal, as well as geometry of varying cross-sectional shape and/or dimension.

As described above, the antenna elements in the antenna array may be equally spaced from one another along the closed loop path. The antenna unit may comprise two or more antenna arrays arranged in a spaced-apart relationship along the antenna body. The different antenna arrays may include the same number of antenna elements; or may include arrays having different number of antenna elements. As also described above, the antenna elements of different arrays may or may not have the same geometry, and such geometrical parameters are properly selected to optimize the performance of the antenna device.

The antenna device further includes a phase controller circuit for controlling phases of all the antenna elements in each antenna array to provide a desired boresight of the antenna array in accordance with a selected radiation direction. The phase controller is configured and operable for providing a predetermined phase pattern of the antenna array resulting in a circular polarization of the antenna radiation of said antenna elements. Such phase pattern may be such that the phases of the antenna elements in the array are shifted one with respect to the other along a circular direction, such that each successive antenna element in said direction has a phase shifted by a predetermined value with respect to a preceding antenna element.

Referring to <FIG>, there is schematically illustrated, by way of a bock diagram, an example of an antenna device <NUM> of the present invention. The antenna device <NUM> includes at least one conformal antenna unit - one such antenna unit <NUM> being exemplified in the figure - mounted on a supporting antenna body <NUM> having a curved surface corresponding to that of a platform on which the antenna device is to be mounted.

As exemplified in the figure, the antenna body <NUM> is an elongated body having a substantially tubular or substantially conical geometry, or having a substantially conical distal portion and a substantially tubular proximal portion. It should, however, be understood that the invention is not limited to any specific geometry of the curved surface carrying the antenna unit(s). The antenna unit <NUM> includes a plurality of antenna elements, generally at AEi, which are arranged in one or more antenna arrays spaced from one another along a longitudinal axis of the body <NUM> - three such antenna arrays A<NUM>, A<NUM>, and A<NUM> being shown in the non-limiting example of <FIG>. The antenna elements of each array are arranged in a spaced apart relationship along a closed-loop path (e.g. circular path).

The antenna device <NUM> of the invention is particularly useful for placing the antenna unit <NUM> on a front portion <NUM> of a platform and is configured and operable for operating in a so-called "forward-looking mode", namely having a general forward-looking radiation direction D with an ability to be electronically steered within a wide angular range around this general radiation direction. As will be described more specifically further below, the antenna unit <NUM> is located at a predetermined distance d from a base or tip end <NUM>' of the platform body. Such distance d may be of about 2λ or higher, where λ is the operation wavelength of the antenna device.

Each antenna element AEi is configured as an end-fire antenna element capable of emitting linearly polarized radiation. The array of the antenna elements is thus operable as a forward looking end-fire antenna array. This enables electronic steering of an antenna beam by controllably modifying phases of the antenna elements of each array.

The construction and operation of the end-fire antenna element are generally known and do not form part of the present invention. An example of an end-fire antenna element suitable to be used in the antenna device of the present is described further below with reference to <FIG>.

As also schematically shown in the figure, each antenna element AEi is associated with its own operational module including a phase shifter PSi. The construction and operation of the operational module of the antenna element implanting the phase shifting technique will be exemplified further below with reference to Figs.

As described above, the antenna unit of such end-fire antenna elements with their boresight BS (being the axis of maximum gain of the antenna element) substantially parallel to the surface of the antenna element, may generally include M antenna arrays (M≥<NUM>); the antenna array may include number N (N≥<NUM>) of the antenna elements arranged in a spaced-apart relationship along a closed-loop circumferential path. The number of antenna elements, as well as their geometry, in the arrays may or may not be the same. As exemplified in <FIG>, the antenna elements of two adjacent arrays A<NUM> and A<NUM> may be arranged in a chess-like fashion.

As further exemplified in <FIG>, in dashed curves, the antenna device <NUM> may include an additional antenna unit <NUM>, in order to increase the steering angle of the entire antenna device <NUM> up to <NUM>°. Such additional antenna unit <NUM> includes antenna elements (arranged in one- multi-array fashion) having boresight BS' substantially perpendicular to the longitudinal axis LA of the platform body. It should be noted, although not specifically shown, that such additional antenna unit <NUM> may include a ring-like antenna or an array of two or more discrete controllably switchable phased arrays of antenna elements.

Also, as exemplified in <FIG>, at least one additional sensor device <NUM> may be provided of any suitable known type, including optical and/or RF sensor elements. The sensor device(s) <NUM> may generally be located at any suitable site(s) of the antenna body <NUM>, e.g. upstream of the antenna unit <NUM> and possibly also downstream thereof. Such sensor device(s) <NUM> together with the antenna device <NUM> form a sensing system, in which the sensor device(s) <NUM> add(s) additional frequency channel(s) to that / those of the antenna device <NUM>.

<FIG> show a few more specific, but not limiting examples, of the arrangement of antenna element of the antenna unit <NUM> on the antenna body <NUM>. To facilitate illustration and understanding, the same reference numbers are used to indicate components that are common in all the examples of the invention. In the example of <FIG>, the antenna body <NUM> has a distal portion 14A of a substantially conical geometry and a proximal portion 14B of a substantially tubular geometry. In the example of <FIG>, the antenna unit <NUM>, which may for example include more than one array of antenna elements (three arrays in this non-limiting example) is located on the proximal portion 14B. As shown, additional antenna array <NUM> may optionally be provided as described above, and also optionally the additional sensor(s) <NUM> may be provided. In the example of <FIG>, the antenna elements of the antenna unit <NUM> are located at the distal conical portion 14A. Optionally, sensor device <NUM> and/or the additional antenna unit <NUM> may be provided on the antenna body <NUM>. In the example of <FIG>, the antenna elements of the antenna unit <NUM> are distributed on both the distal conical and proximal tubular portions 14A and 14B. Similarly, devices <NUM> and / or <NUM> (which is not shown here) may or may not be used. In the example of <FIG>, the antenna body <NUM> has a conical configuration, and the antenna elements of the antenna unit <NUM> are appropriately arranged in one or more arrays on the antenna body. Although not specifically shown, additional antenna unit(s) and sensor(s), such as antenna unit <NUM> and sensor <NUM> described above may be used.

It should also be noted, although not specifically shown in <FIG>, for the purposes of the present application, each antenna element is associated with its operational module including the phase shifter utility / circuit.

Further, it should be understood that in all the above examples, the antenna unit <NUM> is located at a certain predetermined distance from the base / tip <NUM>' of the antenna body <NUM> or that of the platform <NUM> on which the antenna device is mounted.

Reference is now made to <FIG> showing two more specific but not limiting examples of an antenna device <NUM> of the present invention utilizing two different configurations of the antenna unit <NUM>.

In both examples of <FIG>and <FIG>, the antenna device <NUM> includes a conformal antenna unit <NUM> mounted on a supporting antenna body <NUM> having a curved surface corresponding to that of a platform on which the antenna device is to be mounted. In these examples, the antenna body <NUM> has a substantially conical geometry. As indicated above, the invention is not limited to any specific geometry of the curved surface carrying the antenna unit, in which the antenna elements are arranged in one or more circular antenna arrays, i.e. antenna elements are arranged in a spaced apart relationship along one or more closed-loop paths.

The antenna device <NUM> is configured and operable for operating in the "forward-looking mode", with a general forward-looking radiation direction D and ability to be electronically steered within a wide angular range around this general radiation direction. In the example of <FIG> the antenna unit <NUM> includes one phased array A<NUM>, and in the example of <FIG> the antenna unit <NUM> includes two phased arrays A<NUM> and A<NUM>.

As described above, the principles of the invention are not limited to a number of phased arrays of antenna elements, as well as are not limited to number(s) of the antenna elements in the array(s). Thus, generally, the antenna unit <NUM> may include m antenna arrays, m≥<NUM>, such that in case of multiple antenna arrays they are located in a spaced-apart relationship along the longitudinal axis LA of the body <NUM>, and each of the antenna arrays includes multiple antenna elements located in a spaced-apart relationship along a circumferential path, with the same or different numbers of antenna elements in the arrays. In these specific examples, where the antenna body <NUM> has a substantially conical geometry, the number of the elements in the arrays increases with the <NUM>st array's distance d from a cone tip/apex <NUM>'. For example, the antenna array A<NUM> (which is the single array in the example of <FIG>, and is the first array located closer to the tip portion <NUM>' in the example of <FIG>) has eight antenna elements AE<NUM>-AE<NUM>, and in the second antenna array A<NUM> in the example of <FIG>, located farer from the tip portion <NUM>' includes sixteen antenna elements. In the specific not limiting example of <FIG>, the antenna unit <NUM> is spaced from the tip <NUM>' distance d=<NUM>. 1λ, the antenna element is of the length l=<NUM>. 4λ, where λ is the operational wavelength of the antenna. Generally, such parameters as d and l may be in the ranges of <NUM>. 5λ-10λ, and <NUM>. 8λ-10λ, respectively.

The antenna elements of the same array are preferably equally spaced from one another. In case more than one antenna arrays are used, the distance between the antenna elements of one array may or may not be equal to the distance of the antenna elements in one or more other arrays. The number(s) of the antenna elements in the array(s) is/are selected in accordance with the dimensions and shape of the antenna body, i.e. of the platform, and frequency and gain requirements for the antenna operation, as well as the requirement for antenna radiation pattern (reduction / suppression of sidelobes).

The antenna body <NUM> may be a metallic body. The metallic tip portion <NUM> of the body contributes to the antenna radiation pattern. Such parameters as the longitudinal dimension d of the tip portion <NUM> (i.e. a distance of the antenna array from the tip <NUM>' of the antenna body), as well as a distance b between the antenna elements in the array, and possibly also a distance c between the antenna arrays, are selected / optimized in accordance with the frequency and gain requirements for the antenna operation. For example, when higher operational frequencies are to be used, the distance d may be lower than that preferred for lower operational frequencies of the antenna device.

Each antenna element AE is an end-fire antenna element, whose boresight BS (shown in <FIG> and <FIG>), being the axis of maximum gain of the antenna element, is substantially parallel to the surface of the antenna element.

Reference is made to <FIG> showing an example of the configuration of the end-fire antenna element AE suitable to be used in the present invention. The antenna element is configured as an end-fire waveguide WG dimensioned for propagating two orthogonal linearly polarized wave energy modes. A radiating wall W of the waveguide WG has a plurality of thin, narrow, radiating slots S, which are arranged in a spaced-parallel relationship along the radiating wall W and extend along an axis perpendicular to the longitudinal axis of the waveguide WG. The slots S are dimensioned (have a length) such that the slots are nonresonant with respect to the operating wavelength of the antenna element, and arranged with small gaps between them to form a leaky line. The gaps between the slots S and the electrical driving parameters determine the radiating beam angle, and the slot dimension affects the shape of the radiating beam. The radiating slots S are excitable by polarized electric fields EF (from a field source which is not specifically shown here) to excite linearly polarized electric fields EF within the slots having a plane of polarization P oriented along the slot axis (parallel to the wall W and perpendicular to the longitudinal axis of the wall W). At the opposite end of the waveguide is configured as a termination unit formed by a conductive facet CM of the waveguide WG and a diagonal member operable as a polarization rotator PR.

Linearly polarized wave propagates through the waveguide WG and excites the lowest order TE-mode in the waveguide with the plane of polarization of the waves being parallel to the wall W. The radiating slots S are excitable only by linearly polarized waves with the plane of polarization orthogonal to the wall W (or generally, selected plane dependent on the selected slots' arrangement). Hence, the wave energy mode excited by the electric field EM propagates along the waveguide WG without exciting the slots S (since currents induced into the waveguide wall W has no component transverse to the longitudinal axis of the slots S). At the facet CM with the polarization rotator PR, the plane of polarization is rotated by <NUM> degrees to be parallel with the selected plane, i.e. from plane of polarization P<NUM> to plane of polarization P<NUM>; and the rotated linearly polarized wave is substantially reflected to propagate back along the waveguide WG. The reflected wave has the plane of polarization parallel to the selected plane and thus excites the slots similarly to that of the forward end-fire excitation. Thus, in this non-limiting example the end-fire beam is reversed with respect to the input EM propagated from the source and is forward with respect to the direction of the reflected electromagnetic wave.

It should, however, be understood that the present invention is not limited to the above-exemplified configuration of the end-fire antenna element, and any other known suitable configuration can be used, provided that the antenna element is configured and operable to produce a radiation beam whose axis is either parallel to the axis of the element or makes an angle with said axis other than <NUM> degrees, or in other words the radiation beam is not a boresight.

It should also be noted that, although nor specifically shown in <FIG>, but as described above and schematically shown in <FIG>, for the purposes of the present invention each antenna element is associated with (i.e. includes or connected to) the operational module including the phase shifter utility PS.

Reference is now made to Figs. 3A and 3B schematically illustrating the structural and operational principles of the antenna array, e.g. array A<NUM>, for the forward-looking direction in the antenna unit <NUM> of the invention. As described above, the polarization components P of the radiation emitted by the antenna element AE are perpendicular to the boresight BS direction. Hence, in order to provide desired orientation of the boresight of the antenna array A<NUM> (to provide desired directional operation of the antenna), while effectively utilizing the radiation emitted by all the antenna elements in the array (i.e. maximizing the performance) for each required direction, the phases of the antenna elements in the array are appropriately controlled.

As shown schematically in Fig. 3A (and is also be relevant for all the previously described examples), each of the antenna elements AE in the antenna device has its associated operational module utilizing the phase sifter utility PS, and all the phase shifters are associated with (connectable to) a control system <NUM> which includes inter alia suitable a phase shifter controller <NUM>, and an analyzer unit / module <NUM> configured and operable to analyze input data about the operational direction and generate corresponding phase control data with respect to each antenna element in each array and communicate corresponding control data pieces to the respective phase shifters PS. The phase shifters PS utilize this control data to adjust the phases for the antenna elements. If the antenna operation with relatively small-angle steering, angular range from zero to up to about <NUM> degrees, is needed, the phases of all the elements in the array are controlled to be substantially the same for each direction within this angular range for circular polarization of the beam. For the antenna operation with relatively wide-angle steering, i.e. angular range of about <NUM> degrees or higher, the phases of all the elements in the array are controlled to be substantially the same for each direction in this angular range for circular or arbitrary linear polarization of the beam.

For substantially forward direction D, zero-steering from this direction, a phase, φi+<NUM>, of each successive antenna element AEi+<NUM> is shifted from the phase, φI, of the preceding antenna element AEi in a direction along the circular path (as shown in <FIG>) by the same value of the phase shift, Δφ=φi-φi+<NUM>,, such that the antenna beam of the entire array A<NUM> is of circular polarization. A phase shift Δφ between the phases of each two neighboring elements, considered as the successive elements in the direction along the circular path, in the array of n antenna elements is determined as Δφ=2π/n. For example, for <NUM>-element array A<NUM>, the phase shift Δφ is <NUM> degrees, and for the <NUM>-elements array A<NUM>, the phase shift is <NUM> degrees.

<FIG> exemplifies, by way of a block diagram, the configuration of the operational module <NUM> of the antenna element configured to implement the phase shifting technique. The operational module includes a receiving channel RC and a transmitting channel TC coupled to a linearly polarized end-fire antenna element AE (e.g. configured as described above with reference to <FIG>). The receiving channel RC includes a receiver (Rx) <NUM> that includes a phase shifting circuit <NUM> of the phase shifter utility PS, a receiver amplifier/attenuator <NUM> and an analog-to-digital converter (ADC) <NUM>. The receiving channel RC also includes a signal processing system (SPS) <NUM>. In turn, the transmitting channel TC includes a transmitter (TR) <NUM> that includes a source <NUM> of radio frequency (RF) radiation and a TR phase shifting element/circuit <NUM> of the phase shifter utility PS configured to provide required phase shifts to the signals provided by the RF source <NUM>. Further, the transmitter <NUM> includes a TR amplifier/attenuator <NUM> configured for tuning power of the polarized signals transmitted to the linearly polarized antenna element AE.

In this non-limiting example, the operational module <NUM> also includes a duplexer <NUM> coupled to the receiver <NUM> and to the transmitter <NUM>. The duplexer <NUM> which isolates the receiving channel RC from the transmitting channel TC, while permitting them to share the common antenna element AE. For example, the duplexer <NUM> can be implemented as a switch. Alternatively, the duplexer <NUM> can be implemented as a circulator.

It should be understood that by supplying a suitable phase shift and amplitude to each of the antenna elements, the entire antenna beam produced by the antenna array can be of any desired polarization and power. Reference is made to <FIG> and <FIG> illustrating simulation results for the performance of the antenna device according to the invention. Here, <FIG> and <FIG> correspond to the antenna device utilizing an antenna unit configuration of <FIG>; and <FIG> and <FIG> correspond to the antenna device utilizing an antenna unit configuration of <FIG>.

More specifically, the simulation results illustrated in <FIG> correspond to the antenna unit configuration of <FIG> with the following parameters: the platform diameter of <NUM>. 2λ, the antenna element length and width of <NUM>. 4λ and <NUM>. 5λ respectively, and the distance d between the end of the platform and the antenna unit (first array) of <NUM>. The simulation illustrated in <FIG> correspond to the antenna unit configuration of <FIG> with the following parameters: the platform diameter of <NUM>. 8λ, the antenna element length and width of <NUM>. 2λ and <NUM>. 5λ respectively, the distance d between the end of the of platform and the antenna unit (first array) of <NUM>. 1λ, and the distance c between the first and second antenna arrays of <NUM>.

<FIG> exemplifies simulation of the antenna unit operation (in a receiving mode), and shows the sum signal pattern versus azimuth angle of a target (graph G<NUM>) and the azimuth difference signal pattern versus azimuth angle of a target (graph G<NUM>), in the azimuth plane, when the boresight angle is substantially zero, the antenna received signals have circular polarization. It should be understood that for the antenna operation in a transmitting mode, there is no such azimuth difference signal pattern vs azimuth angle, while the sum signal pattern vs azimuth angle is substantially the same as for the receiving mode operation. <FIG> illustrates the dependencies of the monopulse ratio on the azimuth angle obtained for the transceiver elements (antenna elements) of the array that receive signals having circular polarization, when the antenna boresight angle is zero degrees.

<FIG> exemplify simulation for the sum signal pattern (graph G<NUM>) and the azimuth difference signal pattern (graph G<NUM>) in the azimuth plane versus azimuth angle of a target, when the boresight angle is <NUM> degrees and the received signal have circular polarization. <FIG> is a zoom on the specific angular segment of the graphs in <FIG>. Fig. 45E shows dependencies of the monopulse ratio on the azimuth angle obtained for the transceiver elements of the array that receive signals having circular polarization, when the antenna boresight angle is at <NUM> degrees orientation.

<FIG> show the sum signal pattern (graph H<NUM>) and the azimuth difference signal pattern (graph H<NUM>) in the azimuth plane versus azimuth angle of a target (<FIG>), and the dependencies of the monopulse ratio on the azimuth angle (<FIG>), for the circular polarization and the zero angle of boresight orientation. <FIG> show similar results in the elevation plane, for the circular polarization and the zero angle of boresight orientation: <FIG> shows the sum signal pattern in the elevation plane versus elevation angle of a target (graph P<NUM>), and the elevation difference signal pattern in the elevation plane versus elevation angle of a target (graph P<NUM>), and <FIG> shows the dependencies of the monopulse ratio on the elevation angle.

Claim 1:
An antenna device (<NUM>) comprising: a conformal antenna body (<NUM>) which has a proper geometry corresponding to a front portion of a platform (<NUM>) having a platform nose on which the antenna device is to be mounted, and an antenna unit (<NUM>) carried by the antenna body, the <NUM> antenna unit comprising at least one phased array (A<NUM>, A<NUM>, A<NUM>) of antenna elements (AEi), the antenna elements of each of said at least one array being arranged in a spaced-apart relationship in a closed loop path along a circumference of the antenna body having a proper geometry corresponding to a front portion of the platform on which the antenna unit is to be mounted,
wherein:
<NUM> each of the antenna elements of said at least one phased array is configured as an elongated end-fire antenna element (AE<NUM>-AE<NUM>) having a boresight substantially parallel to the elongated surface thereof and being capable of emitting linearly polarized radiation,
each of the end-fire antenna elements of said at least one phased array <NUM> extends substantially along a longitudinal axis of the body, and
each of the end-fire antenna elements of said at least one phased array is associated with a respective operational module comprising a phase shifting utility (PS), characterized by the entire phased array of the end-fire antenna elements being operable as <NUM> a forward looking end-fire antenna array producing an antenna beam in a generally forward-looking direction (D) relative to the platform nose, enabling electronic steering of the antenna beam produced by the entire phased array by controllably modifying phases of the antenna elements of the phased array to provide a predetermined phase pattern of a radiating beam emitted by all the <NUM> antenna elements in the array in accordance with a selected radiation direction around said generally forward-looking direction.