EP2415120B1 - Mehrschichtige pillbox-antenne mit parallelen ebenen und entsprechendes antennensystem - Google Patents
Mehrschichtige pillbox-antenne mit parallelen ebenen und entsprechendes antennensystem Download PDFInfo
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- EP2415120B1 EP2415120B1 EP10711224.5A EP10711224A EP2415120B1 EP 2415120 B1 EP2415120 B1 EP 2415120B1 EP 10711224 A EP10711224 A EP 10711224A EP 2415120 B1 EP2415120 B1 EP 2415120B1
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q19/00—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic
- H01Q19/10—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces
- H01Q19/12—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces wherein the surfaces are concave
- H01Q19/13—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces wherein the surfaces are concave the primary radiating source being a single radiating element, e.g. a dipole, a slot, a waveguide termination
- H01Q19/138—Parallel-plate feeds, e.g. pill-box, cheese aerials
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q13/00—Waveguide horns or mouths; Slot antennas; Leaky-waveguide antennas; Equivalent structures causing radiation along the transmission path of a guided wave
- H01Q13/20—Non-resonant leaky-waveguide or transmission-line antennas; Equivalent structures causing radiation along the transmission path of a guided wave
- H01Q13/22—Longitudinal slot in boundary wall of waveguide or transmission line
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q19/00—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic
- H01Q19/10—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces
- H01Q19/12—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces wherein the surfaces are concave
- H01Q19/17—Combinations of primary active antenna elements and units with secondary devices, e.g. with quasi-optical devices, for giving the antenna a desired directional characteristic using reflecting surfaces wherein the surfaces are concave the primary radiating source comprising two or more radiating elements
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q21/00—Antenna arrays or systems
- H01Q21/0006—Particular feeding systems
- H01Q21/0037—Particular feeding systems linear waveguide fed arrays
- H01Q21/0043—Slotted waveguides
- H01Q21/005—Slotted waveguides arrays
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q21/00—Antenna arrays or systems
- H01Q21/06—Arrays of individually energised antenna units similarly polarised and spaced apart
- H01Q21/061—Two dimensional planar arrays
- H01Q21/064—Two dimensional planar arrays using horn or slot aerials
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01Q—ANTENNAS, i.e. RADIO AERIALS
- H01Q3/00—Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system
- H01Q3/12—Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system using mechanical relative movement between primary active elements and secondary devices of antennas or antenna systems
- H01Q3/16—Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system using mechanical relative movement between primary active elements and secondary devices of antennas or antenna systems for varying relative position of primary active element and a reflecting device
- H01Q3/18—Arrangements for changing or varying the orientation or the shape of the directional pattern of the waves radiated from an antenna or antenna system using mechanical relative movement between primary active elements and secondary devices of antennas or antenna systems for varying relative position of primary active element and a reflecting device wherein the primary active element is movable and the reflecting device is fixed
Definitions
- the field of the invention is that of multilayer antennas with parallel planes, also called “pillbox antennas” or “cheese antennas” in English.
- Parallel Plate Waveguide and single layer (also called monolayer systems) antenna systems
- the energy provided by a source is confined between two metal plates located on each side of the board. another of a substrate layer, to then be guided to a radiating part also included in this layer.
- This radiating part is generally composed of integrated slotted waveguides ("Slotted waveguide array” in English) for example made in SIW technology ("Substrate Integrated Waveguides” in English) or leaky wave structures.
- Conductive vertical walls connecting the two metal plates, which behave as a mirror for the energy of the wave, make it possible to reflect or direct the energy. These vertical walls generally have a parabolic profile in order to collimate the energy coming from the source. But to avoid a backscattering towards the source, it is necessary to use a solution based on double reflector or off-center configuration, or a double layer structure.
- the source and the radiating part are in two different layers, connected by a 180 ° parallel plate bend plate of often parabolic profile. .
- the main advantage of these antennas is their modularity. Indeed, three parts corresponding to different functions can be distinguished: a supply part (source), a radiating part and a guide part.
- the latter makes it possible to guide the energy of the wave generated by the source, from the supply portion to the radiating part, through the superimposed layers of the parallel plan guide type.
- the guide portion comprises transition means between these layers, comprising a reflector cooperating with a slot.
- the goal of the next generation of radar for automotive applications is to improve safety along the roads, by controlling and responding effectively to different scenarios at the front of the car (accident, vehicles too close to each other). others, .
- a short radar range SRR
- LRR long radar range
- a first well known technique is based on the use of diélecriques lenses.
- Commercial solutions already exist. These solutions are very attractive but remain cumbersome.
- a second well-known technique consists in using Rotman lenses which are quasi-optical planar systems having three focal points, as described for example in the following scientific document: W. Rotman, RF Turner, "Wide-angle microwave lens for line source applications," IEEE Transactions on Antennas and Propagation, Vol. 11, no.6, pp. 623-632, Nov.1956 .
- a major disadvantage of this second technique is the large size of the complete antenna system and its low modularity, because all the parts (power supply, guide portion and radiating portion) are made on the same substrate.
- the Rotman lens has large dimensions that can not reduce the overall size of the antenna.
- This structure is also limited in the number of input beams to perform a full scan.
- a third known technique concerns a plane-parallel ("pillbox") and double-layer antenna, as presented in the following scientific document: T. Teshirogi, Y. Kawahara, A. Yamamoto, Y. Sekine, N. Baba, M. Kobayashi, "Dielectric Slab Based Leaky-Wave Antennas for Millimeter-Wave Applications", IEEE Antennas and Propagation Society International Symposium, 2001, Vol. . 1, pp. 346-349, Jul. 2001 .
- the Figures 1 and 2 show views, in perspective and in section respectively, of an antenna according to this third known technique. It comprises a low layer 5 and a high layer 6.
- the low layer 5 is a parallel plan structure comprising two metal plates 8, 9.
- the high layer 6 is also a parallel plan structure comprising two metal plates 9, 4, including one (that referenced 9) is common to both layers and two parallel plan structures.
- the two layers 5, 6 are connected by transition means comprising a reflector 2 (180 ° parallel plate bend plate) of parabolic profile and a single slot 7 extending along and along the entire length of the parabolic reflector 2.
- the feed portion comprising a single sectorial horn 1.
- In the upper layer 6 is placed the radiating portion 3.
- the transition means allow the transfer of energy between the low layer 5 and the high layer 6 (that is to say from the horn 1 to the radiating portion 3), the wavefront incident on the parabolic reflector being a cylindrical wavefront.
- the main disadvantages of this third known technique lie in the fact that the transition means comprise a single slot, which does not allow an optimal energy transfer (due to the existence of resonance phenomena in a single slot) and is effective only in a narrow angular range. The resolution is not optimal.
- the combined use (in the transition means) of a parabolic reflector and a single slot does not allow, according to the patent document WO91 / 17586 to obtain a perfectly plane wavefront in the high layer (after reflection on the reflector) if the incident wavefront of the lower layer is a cylindrical (or more generally non-planar) wavefront.
- this third known technique does not allow to use several sources of excitation since the horn extends directly to the edge of the reflector parabolic (sectoral cornet). No beam reconfiguration or beam scanning is therefore possible.
- a fourth known technique is a variant of the aforementioned third known technique. It is described in the following scientific document: V. Mazzola, JE Becker, "Coupler-Type Bend for Pillbox Antennas", IEEE Transactions on Microwave Theory and Techniques, Vol. 15, no.8, pp. 462-468, Aug. 1967 » ).
- the single slot (included in the transition means between the two layers) is replaced by a plurality of circular openings, distributed in a triangular mesh (that is to say a mesh whose basic pattern is a triangle) that extends all along the reflector.
- a triangular mesh that is to say a mesh whose basic pattern is a triangle
- a disadvantage of this fourth known technique is that it can only operate with a single polarization (horizontal polarization: TE mode in waveguide with parallel planes (PPW, for "parallel flat waveguide” in English). therefore not work in double polarization.
- Another disadvantage of the fourth known technique is that the increase of the efficiency of the transition is achieved to the detriment of an increase of the coupling region (number and size of the circular openings included in the triangular mesh), and therefore to the final an increase in the size and cost of the antenna.
- the invention in at least one embodiment, is intended in particular to provide a multilayer antenna with parallel planes ("pillbox") not having the disadvantages of the known technical solutions discussed above.
- An object in at least one embodiment of the invention is to provide an antenna comprising transition means between two adjacent layers (called low and high layers, for example), allowing optimal and efficient energy transfer. in a wide angular range and frequency, even if these transition means comprise a non-planar shape reflector (parabolic for example). It is therefore desired to obtain a perfectly plane wavefront in the high layer (after reflecting on the reflector) even if the incident wavefront of the lower layer is a non-plane wavefront (for example cylindrical).
- Another object of at least one embodiment of the invention is to provide an antenna that can operate in double polarization or circular polarization.
- Another objective, of at least one embodiment of the invention is to provide an antenna for using several excitation sources, and therefore whose beam is reconfigurable (multi-beam, beam misalignment (x) , beam (x) with variable directivity).
- Another objective, of at least one embodiment of the invention, is to provide a compact and low weight antenna.
- Another objective, of at least one embodiment of the invention is to provide a simple antenna to implement and inexpensive.
- the combined use (in the transition means) of a non-planar shaped reflector (the incident wavefront of the lower layer is therefore a non-plane wavefront) and a plurality of slots allows to obtain a perfectly plane wavefront in the high layer (after reflection on the reflector).
- the use of a plurality of slots provides an antenna capable of operating in dual polarization. This also provides an antenna that can use multiple excitation sources, and thus whose beam is reconfigurable.
- said plurality of slots is arranged on a single row.
- each slot comprises a main body having an elongated shape along at least one axis substantially parallel or perpendicular to the reflector.
- At least some slots comprise a main body having an elongate shape along a single axis.
- the antenna can operate in single polarization.
- the Figures 17A to 17C illustrated in detail later, illustrate some non-limiting examples of slots that can be used in this first embodiment of the invention.
- At least some slots comprise a main body having a cross shape, said main body comprising a first leg having an elongate shape along a first axis and a second leg having an elongate shape along a second axis substantially perpendicular to the first axis.
- the antenna can operate in double polarization.
- the Figures 17D and 17E illustrated in detail later, illustrate some non-limiting examples of slots that can be used in this second embodiment of the invention.
- the plurality of cross slots can be replaced by a set of first slots comprising a main body having an elongate shape along a first axis, and a set of seconds. slots comprising a main body having an elongate shape along a second axis substantially perpendicular to the first axis.
- the shape of the pattern that together form said plurality of slots has a shape substantially identical to that of the reflector.
- the reflector has either a conventional shape (parabola, ellipse, hyperbola, circle), or any other form adapted to a specific need.
- each slot of said plurality of slots has a length of between 0.25 * ⁇ d and 0.5 * ⁇ d , and a width of between 0.1 * ⁇ d and 0.2 * ⁇ d , with ⁇ d the wavelength in the superimposed layers of guide type with parallel planes, at the operating frequency of the antenna.
- the length and width of the slots are parameters on which it is possible to play, for each slot, to easily optimize the efficiency of the transition in which the slots participate.
- each slot of said plurality of slots is at a distance, with respect to the reflector, between 0.3 * ⁇ d and 0.5 * ⁇ d , with ⁇ d the wavelength in the superimposed layers of type guide parallel planes, the operating frequency of the antenna.
- the distance of each slot relative to the reflector is a parameter on which it is possible to play, for each slot, to easily optimize the efficiency of the transition in which the slots participate.
- the gap between two adjacent slots of said plurality of slots is between 0.02 * ⁇ d and 0.1 * ⁇ d , with ⁇ d the wavelength in the layers superimposed guide type plan parallel to the operating frequency of the antenna.
- the distance between two adjacent slots is a parameter on which it is possible to play, for each slot, to easily optimize the efficiency of the transition in which the slots participate.
- said feed portion comprises at least two sources intertwined with each other physically or electrically.
- said supply portion comprises at least one source and a first means of mechanical displacement of said at least one source, in a plane parallel to the superimposed layers of guide type with parallel planes.
- said feed portion comprises at least two sources and means for selectively feeding said at least two sources.
- an antenna system comprising a multilayer antenna according to one of the aforementioned embodiments, and a second means of mechanical displacement of said antenna.
- the multilayer antenna radiates essentially in a plane (see figure 18 ), that the second moving means can move.
- an antenna system comprising a multilayer antenna according to one of the aforementioned embodiments (that is to say comprising: a first power supply portion generating a first wave, a radiating portion, and a guide portion for guiding said first wave from the first supply portion to the radiating portion, said guide portion comprising at least two parallel plane guide type superimposed layers, and, for each pair of adjacent layers, first transition means between said adjacent layers, comprising a first reflector cooperating with a first slot coupling means).
- the antenna system includes a second power supply generating a second wave.
- Said guide part also makes it possible to guide said second wave from the second feed portion to the radiating portion, said guide portion further comprising, for each pair of adjacent layers, second transition means between said adjacent layers, comprising a second reflector cooperating with a second slot coupling means, said second transition means being offset by 90 ° with respect to said first transition means.
- the first slot coupling means comprises a plurality of first slots, each first slot having an elongate shape along at least one axis, said plurality first slots being arranged on at least one row and together forming a pattern which extends along the first reflector and has a shape depending on the shape of the first reflector.
- the second slot coupling means comprises a plurality of second slots, each second slot having an elongate shape in at least one axis, said plurality second slots being arranged on at least one row and together forming a pattern which extends along the second reflector and has a shape depending on the shape of the second reflector.
- a two-layer antenna 30 according to a particular embodiment of the invention.
- Such an antenna can for example be used in radars, for automotive applications.
- the two substrate layers are coupled by an optical transition means comprising a parabolic reflector R1 and a plurality of coupling slots 10 made in the common metal plate M.2.
- the parabolic reflector R1 extends from the metal plate M.1 to the metal plate M.3.
- Other reflector profiles canonical or arbitrary optimized) may be used (see below description of the figure 6 ).
- each coupling slot 10 has a rectangular shape and extends along an axis substantially parallel to the reflector.
- the plurality of coupling slots 10 are arranged on a row and together form a parabolic pattern that extends along the parabolic reflector.
- the pattern formed together by the coupling slots is for example the locus formed by the geometric centers of the slots (as for example that given by the equation number 2 given below, this equation is not limiting).
- the Figure 17A has a rectangular slot 170 (that is to say a slot comprising a main body having a rectangular shape and thus elongated along an axis).
- the Figure 17B has a slot 171 comprising a main body having an elongate shape along an axis. This slot 171 is different from that of the Figure 17A in that its ends are rounded.
- the figure 17C has an H slot (also referred to as a dog bone slit 172 including a main body 172a having an elongate shape along an axis, and two split ends 172b, 172c. split allows to reduce the physical length of the slot (compactness objective of the antenna) but not its electrical length. Typically, the length l f of each split end 172b, 172c is largely greater than the length L f of the main body 172a (for example in a ratio 3 to 4). In a variant (not shown), the split ends of the H slot are rounded.
- the figure 17D has a simple cross slot 173. It comprises a main body comprising a first branch 173a, 173b having an elongated shape along a first axis and a second branch 173c, 173d having an elongate shape along a second axis substantially perpendicular to the first axis.
- the ends of the simple cross slot are rounded.
- the figure 17E has a Jerusalem cross slot 174. It comprises a main body comprising a first branch 174a, 174b having an elongate shape along a first axis and a second branch 174c, 174d having an elongate shape along a second axis substantially perpendicular to the first axis.
- Each end 174e, 174f, 174g, 174h of branch is split. This makes it possible to reduce the physical length of the slot (objective of compactness of the antenna) but not its electrical length. Typically, the length of each split end is much greater than the length of the leg (of the main body) at the end of which is is located (for example in a ratio 3 to 4). In a variant (not shown), the ends of the Jerusalem cross slot are rounded.
- the antenna 30 also includes a power supply portion comprising a source S1 placed in the Sub.1 substrate layer.
- a source S1 placed in the Sub.1 substrate layer.
- the antenna also includes a radiating portion which is formed on the substrate layer Sub.2 and which comprises a plurality of radiating slots 11 made in the upper metal plate M.3.
- BFN substrate for "Beam Forming Network” in English.
- This BFN substrate allows the shaping of the beam by excitation or not of the source or sources, for example by means of active components (diodes or EMS components for example).
- this antenna is as follows: the energy of the wave generated by the source S1 is guided by the first layer with parallel planes (metal plates M.1, M.2 and substrate layer Sub.1). Thanks to the optical transition means (reflector R1 and plurality of coupling slots 10), this energy is transferred to the second layer with parallel planes (metal plates M.2, M.3 and Sub.2 substrate layer), where finally it is radiated by the radiating part (plurality of radiating slots 11).
- the source S1 and the radiating part 11 are placed along and immediately after the focal plane of the parabolic reflector (that is to say at the focal length) , even if, particularly for the radiating part, other positions are possible (in particular to reduce the surface of the antenna) by conveniently checking the phase front of the wave reflected by the parabolic reflector.
- the focal length is referenced F on the figure 3 .
- the feeding part is now presented in more detail. It is located at the focal plane F (or in the vicinity of this focal plane) of the reflector R1 of the transition means. It comprises either a single source (case of source S1 on the figure 3 ) or several sources.
- the source or sources can generate a TEM wave (for "Transverse Electromagnetic” in English), a wave TE (for "Transverse Electric” in English) or both.
- the TEM wave has an electric field oriented along the Z axis, while the TE wave has an electric field along the Y axis.
- the TEM mode is more particularly described below.
- the elementary source (s) are sectoral horns H ("integrated H-plane sectoral horn" in English).
- H integrated H-plane sectoral horn
- Such a horn shape is particularly advantageous in the case where several sources are used to generate one or more beams and thus be able to perform the reconfiguration of beams.
- other well-known source shapes can be used (monopole networks, interleaved Perot-Fabry sources, etc.).
- an advantageous solution in terms of size and efficiency of illumination of the reflector R1 is to perform a physical interleaving of sources.
- the figure 9 is a sectional view of a two-layer antenna according to a particular embodiment of the invention, showing a set of physically interlaced sources on two levels.
- nine sources are used. They are distributed as follows (following the order from left to right, on the figure 9 ): on the first level, the sources S9, S7, S1, S3 and S5; and on the second level, sources S8, S6, S2 and S4. Compared to the sources of the first level, the sources of the second level are shifted to the right by half a length of horn opening.
- the figure 6 presents different possible profiles for the reflector R1 included in the transition means between the first layer with parallel planes (metal plates M.1, M.2 and substrate layer Sub.1) and the second layer with parallel planes (metal plates M .2, M.3 and substrate layer Sub.2).
- These different profiles are a hyperbolic profile 63, an elliptical profile 62, a parabolic profile 61 and a circular profile 64.
- Other optimized arbitrary shapes can obviously be used.
- the profile of the reflector depends on the wave profile that must arrive in the second layer with parallel planes, according to the optical laws.
- the profile most often used for the "pillbox" type antennas is the parabolic profile 61. In fact, in this case, the energy coming from the focal point F2 will be reflected, in the second layer with parallel planes, as a planar wave. and concentrated and directed to the radiating portion which is usually a planar network.
- the pattern that together form the coupling slots has a shape identical (or substantially identical) to that of the reflector along which they are located.
- the figure 7 is a schematic view of a plurality of coupling slots 10 cooperating with a parabolic reflector R1, in a first particular embodiment of the transition means between two adjacent layers, for operation in single polarization.
- each coupling slot 10 has a rectangular shape along an axis substantially parallel to the reflector.
- the plurality of slots coupling 10 are arranged on a row and together form a parabolic pattern that extends along the parabolic reflector.
- Other forms of non-necessarily rectangular slots may be used (see description of Figures 17A to 17C ).
- optical transition means in terms of energy transfer to the second layer with parallel planes, and cancellation of the reflected wave coming back from the reflector towards the source
- performance of these optical transition means can be increased by varying the dimensions ( length l si and width w si ) and the position (r si ) of each i th coupling slot.
- ⁇ d is the wavelength in the dielectric (that is, in the superimposed layers of the guide type with parallel planes) at the operating frequency of the antenna.
- the number of slots is chosen so that the space ⁇ si between two adjacent slots obeys the condition: 0.02 * ⁇ d ⁇ if ⁇ 0.1 * ⁇ d .
- the symmetry of the structure along the xz plane is also preserved.
- a non-symmetrical distribution of the slots is also possible depending on the type of beam to be radiated by the antenna.
- the use of such a coupling means comprising a plurality of coupling slots makes it possible to suppress the reflections of the wave during its interaction with the coupling means.
- the power transfer is optimized (over a wide angular and frequency range) between the first and second layers.
- the figure 8 is a schematic view of a plurality of slots cooperating with a parabolic reflector, in a second particular embodiment of the transition means between two adjacent layers, for dual polarization operation.
- the mode used is the TEM mode in which the electric field is oriented along the axis Z.
- the same considerations as those made above for the transition means can be repeated for a mode TE in which the electric field is oriented along the Y axis.
- the only variation of the optical transition means would be a rotation of substantially 90 ° of the coupling slots made in the metal plate M.2 common to the two layers with parallel planes (d other angles of rotation could be chosen, for example a cross turned 45 °).
- each coupling slot is a cross slot 80 (see the description of the Figures 17D and 17E ), corresponding to the combination of two perpendicular slits.
- the two slots combined to form a cross are identical, but they may also be different.
- each cross slot is replaced by two perpendicular slots spaced from each other.
- next-generation automotive radars must be compatible with both SRR (Short Radar Range, Wide Beam) and LRR (Long Range Radar, Narrow Beam) modes using a single antenna.
- SRR Short Radar Range, Wide Beam
- LRR Long Range Radar, Narrow Beam
- one solution is to add, in phase or not , a plurality of narrow beams of the LRR type to cover the angular range associated with the SRR mode, in particular because a wide beam SRR is a combination of narrow beams LRR.
- FIG. 10 presents four radiation patterns 101 to 104 obtained with the antenna of the figure 9 for four different power configurations (each power configuration corresponding to the activation of three nearby sources, respectively S6 / S1 / S2, S1 / S2 / S3, S2 / S3 / S4 and S3 / S4 / S5).
- the beam obtained has a beamwidth of 14 ° (against 6 ° for a single source) and a side lobe level SLL of less than -20 dB. It is possible to scan from one configuration to another (just as it is possible to scan by activating the sources one by one).
- the basic concept illustrated on the figure 10 can be generalized to beam shaping.
- another solution is to feed the sources of the figure 9 successively, to modify the shape of the beam and thus be able to widen the angular range of the antenna for the same beam. It is also possible according to this technique to create two different beams and pointing in two different directions.
- the electronic solution described above finds its application particularly when a large scanning speed is necessary. But in some applications, such as inter-vehicle or base-station telecommunications, slow scan speeds are accepted and it is then possible to use a mechanical solution to perform beam reconfiguration or 2D scanning.
- SRR and LRR modes require different performance also in the elevation plane. In this case, no scanning is required, but the beamwidth in LRR mode is typically (but not necessarily) half that in SRR mode.
- the beam width in the elevation plane is a function of the size of the antenna along the X axis, this means that the beam size in LRR mode should be twice that in SRR mode. In terms of reconfiguration, this means being able to increase or reduce the size along the X axis, automatically. From an antenna point of view, this can be done in several ways, for example by using diodes shunts along the opening (see figure 11 ), discrimination polarizations (see figure 12 ) or multiple antennas in SRR mode (for example two juxtaposed antennas, without angular offset between them).
- the first two solutions are detailed below, in the case of a radiating part comprising a network of radiating slots, but it is clear that these solutions can be used in other configurations.
- the radiating part is considered, the feeding and guiding parts are for example those already described above.
- the figure 11 shows the integration of shunt diodes 112 (or alternative shunts), under the radiating part (along a line cutting in half the zone of the radiating part where the radiating slots 11 are located), making it possible to connect connections 111 and 113 made on the metallized plates M.3 and M.2. These diodes are activated (activation means not shown on the figure 11 ), for operation in the SRR mode, to halve the radiating portion by shorting or absorbing the incoming energy.
- shunt diodes 112 or alternative shunts
- the radiating part is designed to respond to different polarizations for the LLR and SRR modes. This is done using two kinds of radiating slots: single slots 121 (along one axis) and cross slots 122 (along two perpendicular axes).
- the former may radiate only if powered with an electric field along the Z axis (TEM).
- the latter can radiate like the first but also if fed with an electric field along the Y axis (TE).
- the cross slots operate in both the LRR and SRR modes, while the single slots only in the LRR mode.
- the transition means reflector and coupling slots
- This solution does not require any control electronics, the discrimination being carried out from a radiation point of view.
- Telecommunication applications usually require 3D scanning within a predefined cone.
- the antenna system must be able to scan the beam 360 ° in one plane, and in a smaller angular range in the other plane.
- the mechanical solution for 3D scanning is based on one or the other of the 2D scanning solutions proposed above (one mechanical and the other electronic). Indeed, these can be adopted to cover the most weak (scanning in a foreground (referenced P or P 'on the figure 18 ). For example, by adding a means of mechanical displacement of the whole of the antenna in the xy plane (plane parallel to the superimposed layers of guide type with parallel planes), a rotation of the main radiation plane (plane P or P) is obtained. ' figure 18 ) in which the antenna radiates mainly.
- FIG. 13 is a top view of an antenna system 130, comprising a multilayer antenna according to one embodiment of the invention (two or more layers) as described above.
- this antenna comprises a first supply portion (generating a first wave), a radiating portion and a guide portion.
- the guide portion guides the first wave from the first supply portion to the radiating portion.
- the guide portion comprises at least two superposed layers of guide type with parallel planes, and, for each pair of adjacent layers, first transition means between the adjacent layers, comprising a first reflector cooperating with a plurality of first coupling slots (the characteristics of such a plurality of coupling slots have already been discussed in detail above).
- the antenna system of the figure 13 further comprises a second power supply, generating a second wave.
- the guide portion also guides the second wave from the second supply portion to the radiating portion.
- the guide portion further comprises, for each pair of adjacent layers, second transition means between the adjacent layers, comprising a second reflector cooperating with a plurality of second slots (the characteristics of such a plurality of coupling slots have already been discussed in detail above). These second transition means are offset by 90 ° with respect to the first transition means.
- the parabolic reflectors P.1 and P.2 feed the radiating part, and control for example the direction of the beam in the planes YZ (plane P on the figure 18 ) and XZ respectively.
- each of the first and second feed parts comprises several interleaved sources (as on the figure 5 for example).
- the beam can be pointed in any direction of the upper space.
- the direction of the maximum radiation of the antenna structure can be found in any direction of the half-space above the radiating portion ( in the direction of the positive Z's).
- leak wave structures can be used. Their limitation is the beam frequency squinting. But for a low bandwidth ( ⁇ 10%), a determined beam operation is possible and the antenna structure is planar, low cost, light and is suitable for 3D electronic scanning with low losses compared to other solutions such as phased networks.
- the Gregorian or Cassegrain type double reflector systems make it possible to reduce the axial size of the optical transition system and to increase the performance with respect to the scanning capacity in the YZ plane.
- the use of a plane mirror simply makes it possible to fold again the antenna (third layer) to reduce even more the bulk. Indeed, the plane mirror reflects the plane wave sent by the parabolic reflector (first optical transition means) without affecting its nature.
- one of the first and second optical transition means is embodied according to the invention (i.e. with a plurality of coupling slots) and the other is realized in a conventional manner (i.e. say with a single coupling slot).
Landscapes
- Aerials With Secondary Devices (AREA)
- Variable-Direction Aerials And Aerial Arrays (AREA)
- Waveguide Aerials (AREA)
- Radar Systems Or Details Thereof (AREA)
Claims (13)
- Mehrschichtige Antenne (30; 140; 150; 160), umfassend:- einen Einspeisungsteil, der eine Welle erzeugt,- einen Abstrahlungsteil,- einen Führungsteil, der ermöglicht, die Welle von dem Einspeisungsteil bis zu dem Abstrahlungsteil zu leiten, wobei der Führungsteil aufweist:wobei die Antenne dadurch gekennzeichnet ist, dass für mindestens ein Paar benachbarter Schichten, für das der Führungsteil einen Reflektor von nichtplanarer Form aufweist, das Schlitzverbindungsmittel mehrere Schlitze (10; 10a', 10b'; 10a", 10b"; 10a"', 10b"') aufweist, wobei jeder Schlitz einen Hauptkörper aufweist, der eine längliche Form entlang mindestens einer Achse besitzt, wobei die mehreren Schlitze auf mindestens einer Reihe angeordnet sind und zusammen ein Muster bilden, das sich entlang des Reflektors erstreckt und eine Form besitzt, die von der Form des Reflektors abhängig ist.* mindestens zwei übereinanderliegende Schichten vom Typ der Leiterschichten mit parallelen Ebenen und* für jedes Paar benachbarter Schichten Übergangsmittel zwischen den benachbarten Schichten, umfassend einen Reflektor (R1; R1', R2'; R1", R2"; R1'", R2"'), der mit einem Schlitzverbindungsmittel zusammenwirkt,
- Antenne nach Anspruch 1, dadurch gekennzeichnet, dass jeder Schlitz einen Hauptkörper aufweist, der eine längliche Form entlang mindestens einer Achse besitzt, die im Wesentlichen parallel oder senkrecht zum Reflektor ist.
- Antenne nach einem der Ansprüche 1 und 2, dadurch gekennzeichnet, dass mindestens einige Schlitze (170; 171; 172) einen Hauptkörper aufweisen, der eine längliche Form entlang einer einzigen Achse besitzt.
- Antenne nach einem der Ansprüche 1 und 2, dadurch gekennzeichnet, dass mindestens einige Schlitze (173; 174) einen Hauptkörper aufweisen, der eine Kreuzform besitzt, wobei der Hauptkörper einen ersten Zweig, der eine längliche Form entlang einer ersten Achse besitzt, und einen zweiten Zweig aufweist, der eine längliche Form entlang einer zweiten Achse besitzt, die im Wesentlichen senkrecht zu der ersten Achse ist.
- Antenne nach einem der Ansprüche 1 und 4, dadurch gekennzeichnet, dass die Form des Musters, das die mehreren Schlitze zusammen bilden, eine Form aufweist, die im Wesentlichen gleich jener des Reflektors ist.
- Antenne nach einem der Ansprüche 1 bis 5, dadurch gekennzeichnet, dass jeder Schlitz der mehreren Schlitze aufweist:- eine Länge (lsi), die zwischen 0,25*λd und 0,5*λd beträgt, und- eine Breite (wsi), die zwischen 0,1*λd und 0,2*λd beträgt,wobei λd die Wellenlänge in den übereinanderliegenden Schichten vom Typ der Leiterschichten mit parallelen Ebenen bei der Betriebsfrequenz der Antenne ist.
- Antenne nach einem der Ansprüche 1 bis 6, dadurch gekennzeichnet, dass jeder Schlitz der mehreren Schlitze in einem Abstand (Δsi) zu dem Reflektor ist, der zwischen 0,3*λd und 0,5*λd beträgt, wobei λd die Wellenlänge in den übereinanderliegenden Schichten vom Typ der Leiterschichten mit parallelen Ebenen bei der Betriebsfrequenz der Antenne ist.
- Antenne nach einem der Ansprüche 1 bis 7, dadurch gekennzeichnet, dass die Differenz (δsi) zwischen zwei benachbarten Schlitzen der mehreren Schlitze zwischen 0,02*λd und 0,1*λd beträgt, wobei λd die Wellenlänge in den übereinanderliegenden Schichten vom Typ der Leiterschichten mit parallelen Ebenen bei der Betriebsfrequenz der Antenne ist.
- Antenne nach einem der Ansprüche 1 bis 8, dadurch gekennzeichnet, dass der Einspeisungsteil mindestens zwei Quellen (51 bis 55; S1 bis S9) aufweist, die physisch und elektrisch miteinander verflochten sind.
- Antenne nach einem der Ansprüche 1 bis 8, dadurch gekennzeichnet, dass der Einspeisungsteil mindestens eine Quelle (S1) und ein erstes mechanisches Verschiebungsmittel der mindestens einen Quelle in einer Ebene aufweist, die parallel zu den übereinander liegenden Schichten vom Typ der Leiterschichten mit parallelen Ebenen ist.
- Antenne nach einem der Ansprüche 1 bis 10, dadurch gekennzeichnet, dass der Einspeisungsteil mindestens zwei Quellen (51 bis 55; S1 bis S9) und Mittel zum selektiven Speisen der mindestens zwei Quellen aufweist.
- Antennensystem, dadurch gekennzeichnet, dass es eine Antenne (30; 140; 150; 160) nach einem der Ansprüche 1 bis 10 und ein zweites mechanisches Verschiebungsmittel der Antenne aufweist.
- Antennensystem (130), dadurch gekennzeichnet, dass es aufweist:- eine mehrschichtige Antenne nach einem der Ansprüche 1 bis 10, umfassend:dadurch, dass es ferner einen zweiten Einspeisungsteil aufweist, der eine zweite Welle erzeugt,* einen ersten Einspeisungsteil, der eine erste Welle erzeugt,* einen Abstrahlungsteil,* einen Führungsteil, der ermöglicht, die erste Welle von dem ersten Einspeisungsteil bis zu dem Abstrahlungsteil zu leiten, wobei der Führungsteil mindestens zwei übereinander liegende Schichten vom Typ der Leiterschichten mit parallelen Ebenen und für jedes Paar benachbarter Schichten erste Übergangsmittel zwischen den benachbarten Schichten, umfassend einen ersten Reflektor (P.1), der mit einem ersten Schlitzverbindungsmittel zusammenwirkt, aufweist,
dadurch, dass der Führungsteil ebenfalls ermöglicht, die zweite Welle von dem zweiten Einspeisungsteil bis zu dem Abstrahlungsteil zu leiten, wobei der Führungsteil ferner für jedes Paar benachbarter Schichten zweite Übergangsmittel zwischen den benachbarten Schichten aufweist, umfassend einen zweiten Reflektor (P.2), der mit einem zweiten Schlitzverbindungsmittel zusammenwirkt, wobei die zweiten Übergangsmittel um 90° gegenüber den ersten Übergangsmitteln versetzt sind,
dadurch, dass für mindestens ein Paar benachbarter Schichten, für das der Führungsteil einen Reflektor von nichtplanarer Form aufweist, das erste Schlitzverbindungsmittel mehrere erste Schlitze aufweist, wobei jeder erste Schlitz eine längliche Form entlang mindestens einer Achse besitzt, wobei die mehreren ersten Schlitze auf mindestens einer Reihe angeordnet sind und zusammen ein Muster bilden, das sich entlang des ersten Reflektors erstreckt und eine Form besitzt, die von der Form des ersten Reflektors abhängig ist,
und dadurch, dass für mindestens ein Paar benachbarter Schichten, für das der Führungsteil einen Reflektor von nichtplanarer Form aufweist, das zweite Schlitzverbindungsmittel mehrere zweite Schlitze aufweist, wobei jeder zweite Schlitz eine längliche Form entlang mindestens einer Achse besitzt, wobei die mehreren zweiten Schlitze auf mindestens einer Reihe angeordnet sind und zusammen ein Muster bilden, das sich entlang des zweiten Reflektors erstreckt und eine Form besitzt, die von der Form des zweiten Reflektors abhängig ist.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
FR0952158A FR2944153B1 (fr) | 2009-04-02 | 2009-04-02 | Antenne multicouche a plans paralleles, de type pillbox, et systeme d'antenne correspondant |
PCT/EP2010/054060 WO2010112443A1 (fr) | 2009-04-02 | 2010-03-29 | Antenne multicouche a plans paralleles, de type pillbox, et systeme d'antenne correspondant |
Publications (2)
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EP2415120A1 EP2415120A1 (de) | 2012-02-08 |
EP2415120B1 true EP2415120B1 (de) | 2019-03-06 |
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EP10711224.5A Not-in-force EP2415120B1 (de) | 2009-04-02 | 2010-03-29 | Mehrschichtige pillbox-antenne mit parallelen ebenen und entsprechendes antennensystem |
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US (1) | US9246232B2 (de) |
EP (1) | EP2415120B1 (de) |
JP (1) | JP5913092B2 (de) |
FR (1) | FR2944153B1 (de) |
WO (1) | WO2010112443A1 (de) |
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JP5913092B2 (ja) | 2016-04-27 |
WO2010112443A1 (fr) | 2010-10-07 |
US20120092224A1 (en) | 2012-04-19 |
EP2415120A1 (de) | 2012-02-08 |
FR2944153A1 (fr) | 2010-10-08 |
JP2012523149A (ja) | 2012-09-27 |
FR2944153B1 (fr) | 2013-04-19 |
US9246232B2 (en) | 2016-01-26 |
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