CN204289717U - Dual polarization oblique wave beam waveguide slot array antenna - Google Patents
Dual polarization oblique wave beam waveguide slot array antenna Download PDFInfo
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- CN204289717U CN204289717U CN201420676652.2U CN201420676652U CN204289717U CN 204289717 U CN204289717 U CN 204289717U CN 201420676652 U CN201420676652 U CN 201420676652U CN 204289717 U CN204289717 U CN 204289717U
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Abstract
The utility model relates to dual polarization oblique wave beam waveguide slot array antenna.Comprise more than one cell array antenna, cell array antenna is made up of horizontal polarization linear array and perpendicular polarization linear array; Horizontal polarization linear array is parallel with perpendicular polarization linear array to be staggeredly placed, and horizontal polarization linear array is positioned at upper strata, and perpendicular polarization linear array is positioned at lower floor; Horizontal polarization single ridged waveguides has broadside V-shaped radiating slot, and perpendicular polarization single ridged waveguides has broadside U-shaped radiating slot; Feed part adopts ridge waveguide form, and effectively ensure that entire physical bandwidth, make antenna while realizing beam tilt, the coupling bandwidth of antenna and radiation efficiency are ensured.Feeder network is by suitable phase compensation, and whole antenna can realize good Circular polarization ratio characteristic in frequency band, realizes 45 °, fixed beam tilt angle simultaneously.Described antenna is little with the Waveguide slot antenna phase specific volume of similar frequency bands, and section is low, adopts screw fastening mounting means, effectively reduces costs.
Description
Technical field
The utility model belongs to plate aerial technical field, is specifically related to a kind of dual polarization oblique wave beam waveguide slot array antenna.
Background technology
Plate aerial is widely used in the moving communicating fields such as airborne, carrier-borne, vehicle-mounted, for meeting the aesthetics requirement of mobile vehicle to the requirement of windage and vehicle-mounted outward appearance, requires the low section of plate aerial, miniaturization.Low section plate aerial way of realization has all-wave guide structure and microstrip array two kinds, at Ku wave band, all-wave guide structure efficiency is high, the loss of micro-strip array antenna is larger, especially structure the formation and paster input impedance comparatively large (200 Ω) time, when microstrip line is very narrow, loss is larger, manufacturing cost is higher, therefore microstrip array structure is unfavorable for adopting; Signal many employings linear polarization load mode on geostationary satellite, existing horizontal polarization also has perpendicular polarization, because the satellite longitude and latitude in overhead, equator is general not identical with reception ground longitude and latitude, so the level that sends of satellite or vertically polarized wave arrive and receive after-polarization direction, ground and can change, dual polarization oblique wave beam antenna will realize polarization tracking, the beam position of two polarization must be basically identical, the amplitude of such guarantee two polarization reception is basically identical, can by the circuit realiration polarization tracking of rear end.
Utility model content
In view of the above problems, the utility model proposes the dual polarization oblique wave beam waveguide slot array antenna of a kind of broadband, low section, small size.
Concrete technical scheme is as follows:
Dual polarization oblique wave beam waveguide slot array antenna comprises more than one cell array antenna; Described cell array antenna is made up of horizontal polarization linear array and perpendicular polarization linear array; Described horizontal polarization linear array comprises horizontal polarization single ridged waveguides 1 and the horizontal polarization feeder network 11 of two parallel placements, and perpendicular polarization linear array comprises perpendicular polarization single ridged waveguides 2 and the perpendicular polarization feeder network 12 of two parallel placements; Described horizontal polarization linear array is parallel with perpendicular polarization linear array to be staggeredly placed, and two horizontal polarization single ridged waveguides 1 are positioned at upper strata, and two perpendicular polarization single ridged waveguides 2 are positioned at lower floor, forms dual-polarization cells array antenna; Described horizontal polarization single ridged waveguides 1 has broadside V-shaped radiating slot 3, and adjacent V-shaped radiating slot 3 equidistantly arranges; Perpendicular polarization single ridged waveguides 2 has broadside U-shaped radiating slot 4, and adjacent U-shaped radiating slot 4 equidistantly arranges; Described cell array antenna can realize fixed beam tilt angle, and beam tilt angle and unit interval have nothing to do; Described fixed beam tilt angle is 45 °.
Advantageous Effects of the present utility model embodies in the following areas:
1. the utility model utilizes two kinds of ridge waveguide slot antenna radiating elements to realize low section, dual polarization, realizes the all-wave guide structure plate aerial that fixed beam tilt angle is 45 ° simultaneously.
All-wave guide structure mainly contains rectangular waveguide and ridge waveguide two kinds.Realize the dual polarization Waveguide slot antenna of the fixed beam tilt of following the tracks of needed for geostationary satellite, traditional method generally adopts the narrow side seam gap of rectangular waveguide and waveguide broadside longitudinal joint two kinds of gaps to realize dual polarization, but row ripple battle array greatest irradiation direction, conventional waveguide gap is
, grating lobe suppression condition meets
, this kind of conventional waveguide slot antenna, its beam tilt angle is relevant with unit interval, for suppressing graing lobe, must select d<lg/2, namely wave beam swings to the situation of feed end, select lg/l smaller, namely cut-off wavelength is away from the situation of operation wavelength, for preventing high frequency TE simultaneously
20mould enters, and therefore this numerical value of lg/l is also limited, generally can not more than 1.25, and at this moment pointing to angle, to depart from normal direction more, and unit interval is less, and depart from 45 °, unit interval is about 0.33l
0, for the biased seam of perpendicular polarization, the length of seam resonance is greater than unit interval, and the direction of only departing from is inconsistent just can not interfere.The reduction of this olo, makes the bore in same number of gap reduce, and brings certain difficulty to design.The utility model proposes a kind of oblique wave bundle dual polarization Waveguide slot plate aerial of single ridged waveguides form, orientation angle is only relevant to free space wavelength and guide wavelength, has nothing to do with unit interval.Generally, with during scanning maximum angle, the selection of unit interval does not only occur that the unit interval of graing lobe limits relevant, the directional diagram of slot element is made to point to also run-off the straight according to certain methods especially, so can also continue to increase unit interval, the angle only needing the zero point of element pattern and graing lobe to occur is basically identical just effectively can suppress graing lobe.
Radiating guide cross section described in the utility model is the single ridge waveguide structure of spill.Plate aerial radiating element adopts the ridge waveguide slot antenna of two kinds of forms to realize dual polarization, and two kinds of ridge waveguides are staggeredly placed up and down.Radiating guide horizontal positioned, perpendicular polarization adopts the biased seam of ridge waveguide broadside, and horizontal polarization adopts the broadside V-shaped radiating slot of inverted ridge waveguide.Dual polarization can follow the tracks of inclined polarization, and require that two beam positions that polarize are basically identical, therefore antenna described in the utility model is presented from same direction end.The oblique beam pointing-angle of antenna described in the utility model and unit interval have nothing to do, and under avoiding the prerequisite of graing lobe, preferably suitable ridge waveguide size, makes
when being 45 °, 45 °, controlling antenna wave beam to point angle can being realized, add design flexibility, in fact this time, cut-off wavelength and guide wavelength are all 1.414 times of free space wavelength, from waveguide bandwidth, be sitting at the centre of transmission bandwidth, good bandwidth performance can be obtained.
2 two kinds of ridge waveguide slot antenna radiating elements
Ridge waveguide broadside described in the utility model is biased the gap of seam according to traditional in-line two ends fillet, be difficult to take into account the resonance length of biased seam and little unit interval, in order to ensure the resonance of biased seam, and consider the oblique 45 ° of requirements to spacing of wave beam, the utility model proposes a kind of biased seam form newly, gap bending two ends is come in U-shaped, i.e. U-shaped radiating slot 4; The radiating element of ridge waveguide broadside V-shaped radiating slot antenna has good cross polarization suppression characteristic in frequency band.The number of unit of two kinds of radiating elements of antenna rows ripple battle array described in the utility model is all relevant to the electric conductivity value (size of emittance) of single seam, require that gap is at intermediate frequency resonance, the energy entering load is minimum, two side frequencys are slightly larger, but also will in tolerance interval, while guarantee antenna radiation efficiency, ripple transmission means is made to be traveling-wave mode.One end termination feeder network, other end termination ridge waveguide turns coaxial converter, external 50 ohm of matched loads.
3 ridge waveguide feeder networks
The feeder network employing of antenna described in the utility model and the ridge waveguide of aerial radiation waveguide same size, adopt some deciles and not decile H-T ridge waveguide power splitter form feeder network, by ridge waveguide torque shape waveguide transformer, antenna delivery outlet is made to be rectangular waveguide.In order to reduce the section of antenna and reduce difficulty of processing, the utility model has done 2 kinds of different ridge waveguide feeder networks, as shown in Figure 6 and Figure 7, this feeder network shown in Fig. 7, consider and aerial array rational deployment, the feeder network of perpendicular polarization linear array can transit directly to the lower floor of radiating element by ridge waveguide 2 90 ° of bendings, feedback directly can only be held in the networking of horizontal polarization linear array, by I-shaped coupling slot coupling feed way make feeder line networking progressively layout to one deck below, therefore its section size is larger, take up space also large, and form decile and the not decile power splitter of this feeder network, add inductive iris in the side of ridge waveguide H face T-shaped head, control merit proportion by subtraction, gap between diaphragm and ridge waveguide metal ridge is less, when particularly merit is divided larger, gap does not reach minimum process size, manufacture realizability not strong.Fig. 6 is the another kind of feeder network that the utility model proposes, and ridge warp architecture upwards and V-shaped radiating slot antenna element end are presented, and present after the 180 ° of bendings of downward ridge with longitudinal biasing slot antenna element end; Ridge upwards requires certain space in BENDING PROCESS, can not directly bend, method described in the utility model can ensure that ridge waveguide bends the height adjustable of the outlet after 180 degree, can ensure that two kinds of network layer polarized are nested, and it is less to take up space, reduce favourable to antenna total height; And form decile and the not decile power splitter of this feeder network, be add inductive iris in the both sides of ridge waveguide H face T-shaped head, control merit proportion by subtraction, the gap between diaphragm and ridge waveguide metal ridge is relatively large, and manufacturability is strong.Feeder network is by suitable phase compensation, and whole antenna can realize good Circular polarization ratio characteristic in frequency band.
4. the vacuum brazing technique that conventional waveguide slot antenna adopts abandoned by antenna described in the utility model, directly adopts the mode of screw fastening, greatly reduces manufacturing cost.Antenna described in the utility model can have multiple expanded application, such as adopt four pieces of plate compound modes that two length two are short, the bore of antenna reduces, same sub-block (10) is adopted to form whole antenna, can reduce the difficulty that mould is produced, front and rear panel mixer and LNA control the polarization of wave beam scanner uni and switch, ° scanning of oblique wave bundle ± 25, greatly reduce whole antenna height, realize the high-gain of 38dB12.7GHz simultaneously; Two last comprise networks that polarize are identical, and the phase place that three-in-one and two-in-one network adjusts two polarization feeder networks is consistent, obtains good circular polarization performance, two outlet relative positions are consistent simultaneously, built-in LNA pattern, all make the space of antenna compacter, LNA kind is single.
Accompanying drawing explanation
Fig. 1 is the utility model structural representation.
Fig. 2 be Fig. 1 look up structural representation.
Fig. 3 is the front view of Fig. 1.
Fig. 4 is the structural representation of horizontal polarization linear array.
Fig. 5 is the partial enlarged drawing of Fig. 4.
Fig. 6 is feed end partial enlarged drawing in Fig. 4.
Fig. 7 is horizontal polarization linear array different modes group battle array structural representation.
Fig. 8 is the structural representation of perpendicular polarization linear array.
Fig. 9 is the partial enlarged drawing of Fig. 8.
Figure 10 is the array antenna schematic diagram of the utility model dual-polarization cells linear array composition.
Figure 11 is the feeder network of array antenna in Figure 10.
Figure 12 is the schematic rear view of array antenna in Figure 10.
Figure 13 is array antenna standing wave pattern.
Figure 14 is horizontal polarization directions figure.
Figure 15 is vertical polarization directions figure.
Figure 16 is array antenna two kinds of polarization isolation figure.
Figure 17 is array antenna Circular polarization ratio performance plot.
Sequence number in Fig. 1-12: horizontal polarization single ridged waveguides 1, perpendicular polarization single ridged waveguides 2, V-shaped radiating slot 3, U-shaped radiating slot 4, horizontal polarization ridge waveguide turns coaxial converter 5, perpendicular polarization ridge waveguide turns coaxial converter 6, curved ridges waveguide 7, curved ridge waveguide 8, perpendicular polarization feed waveguide 9, horizontal polarization feed waveguide 10, horizontal polarization feeder network 11, perpendicular polarization feeder network 12, I-shaped coupling slot 13, not decile power splitter 14, horizontal polarization outlet waveguide 15, perpendicular polarization outlet waveguide 16, ridge waveguide torque shape waveguide transformer 17.
Embodiment
Below in conjunction with accompanying drawing, by embodiment, the utility model is further described.
Embodiment 1
See Fig. 1, Fig. 2 and Fig. 3, dual polarization oblique wave beam waveguide slot array antenna comprises a cell array antenna, and each cell array antenna is made up of horizontal polarization linear array and perpendicular polarization linear array.
See Fig. 4, horizontal polarization linear array comprises two parallel horizontal polarization single ridged waveguides 1.Horizontal polarization single ridged waveguides 1 has broadside V-shaped radiating slot 3, and adjacent V-shaped radiating slot 3 equidistantly arranges; One end termination horizontal polarization ridge waveguide of every root horizontal polarization single ridged waveguides turns coaxial converter 5, with 50 ohm of SMA load matched; The other end is connected with horizontal polarization feeder network 11 by curved ridges waveguide 7, carries out feed by horizontal polarization feed waveguide 10, and composition horizontal polarization linear array, is shown in Fig. 5 and Fig. 6 respectively.
Fig. 5 is that horizontal polarization ridge waveguide turns coaxial converter.Horizontal polarization ridge waveguide turns the below that coaxial converter 5 is positioned at horizontal polarization single ridged waveguides 1 one end, and perpendicular to horizontal polarization single ridged waveguides 1.It is realize ridge waveguide to same transformation of axis by the mode of probe coupling that horizontal polarization ridge waveguide turns coaxial converter 5.
See Fig. 6 and Fig. 7, be two kinds of different feeder networks of horizontal polarization linear array shown in two figure.The horizontal polarization feeder network 11 of Fig. 6 is realized by curved ridges waveguide 7 with the connected mode of horizontal polarization single ridged waveguides 1, and curved ridges waveguide 7 can ensure that ridge waveguide bends the height adjustable of the outlet after 180 °, by regulating the height of curved ridges waveguide, can ensure that two kinds of feeder networks polarized are nested layer by layer, and it is less to take up space, reduce favourable to antenna total height; And form decile and the not decile power splitter of this feeder network, be add inductive iris in the both sides of ridge waveguide H face T-shaped head, control merit proportion by subtraction, the gap between diaphragm and ridge waveguide metal ridge is relatively large, and minimum clearance controls at 1mm, and manufacturability is strong.The horizontal polarization feeder network 11 of Fig. 7 is presented directly to horizontal polarization ridge waveguide 1 end, in order to reduce the bore of array, utilize I-shaped coupling slot 13 that the feeder network of two horizontal polarization linear arrays is transitioned into lower one deck, and form decile and the not decile power splitter of this feeder network, add inductive iris in the side of ridge waveguide H face T-shaped head, control merit proportion by subtraction, gap between diaphragm and ridge waveguide metal ridge is less, when particularly merit is divided larger, gap does not reach minimum process size, and machining realizability is not strong.Summary, the feeder network shown in Fig. 6 is obviously better than the feeder network shown in Fig. 7.
See Fig. 8 and Fig. 9, perpendicular polarization linear array comprises two parallel perpendicular polarization single ridged waveguides 2.Perpendicular polarization single ridged waveguides 2 has broadside U-shaped radiating slot 4, and adjacent U-shaped radiating slot 4 equidistantly arranges; One end termination perpendicular polarization ridge waveguide of two perpendicular polarization single ridged waveguides 2 turns coaxial converter 6, and the other end is connected with perpendicular polarization feeder network 12 by curved ridge waveguide 8, carries out feed by perpendicular polarization feed waveguide 9, composition perpendicular polarization linear array.Perpendicular polarization single ridged waveguides 2 turns the conversion of coaxial converter 6 by perpendicular polarization ridge waveguide, makes the outlet of converter be positioned at the bottom of single ridged waveguides, and external SMA matched load is hidden in below perpendicular polarization single ridged waveguides.Curved ridge waveguide 8 bends by realizing ridge waveguide 180 ° to single ridged waveguides twice 90 ° of bendings, after twice 90 ° of bendings, the ridge of single ridged waveguides presents the mode of placing back-to-back, curved ridge waveguide 8 one end termination perpendicular polarization single ridged waveguides 2, other end termination perpendicular polarization feeder network 12, perpendicular polarization feeder network 12 is drawn by perpendicular polarization feed waveguide 9.
Horizontal polarization feed waveguide 10 and perpendicular polarization feed waveguide about 9 correspondence are positioned at described cell array antenna the same side, see Fig. 2; Horizontal polarization feed waveguide 10 and perpendicular polarization feed waveguide 9 are the single ridged waveguides that cross section is spill.
Two horizontal polarization single ridged waveguides 1 and two perpendicular polarization single ridged waveguides 2 levels are staggered formation double polarization array antenna; Realize fixed beam tilt angle, fixed beam tilt angle is 45 °, and beam tilt angle and unit interval have nothing to do.
Preferably suitable waveguide dimensions, when
when being 45 °, antenna realizes 45 ° of beam pointing-angle.L
0=c/f
0,
c=3.0 × 10
8, be the light velocity of free space, f
0centered by frequency.This routine f
0=12GHz, single ridged waveguides preferred size is broadside 0.19935
, narrow limit 0.14239
, metal ridge height 0.11961
, metal ridge width 0.062563
.The single ridged waveguides size of feeder network is identical with radiation single ridged waveguides sectional dimension.
Embodiment 2
See Figure 10, Figure 11 and Figure 12, dual polarization oblique wave beam waveguide slot panel antenna is composed in parallel by six cell array antennas.Wherein the feed end of the horizontal polarization single ridged waveguides 1 of six horizontal polarization linear arrays is by the feeder network synthesis shown in Figure 11, the curved ridges waveguide 7 that the direct termination of the feeder network shown in Figure 11 is connected with every root single ridged waveguides.Feeder network shown in Figure 11 by some horizontal polarization feeder networks 11 and not decile power splitter 14 form, horizontal polarization feeder network 11 plays decile power splitter, whole network is divided into 12 deciles power, the main transmission waveguide of whole network is the single ridged waveguides measure-alike with horizontal polarization single ridged waveguides 1, and single ridged waveguides is converted to half high waveguide by ridge waveguide torque shape waveguide transformer 17 and arrives horizontal polarization outlet waveguide 15.What wherein ridge waveguide torque shape waveguide transformer 17 adopted is become step impedance transformer to realize, and half high waveguide dimensions is 17.2mm*4.1mm.
The feeder network of six perpendicular polarization linear array group battle arrays adopts the feeder network shown in Figure 11 equally, simplify design difficulty, the curved ridge waveguide 8 of feed end termination of the perpendicular polarization single ridged waveguides 2 of each perpendicular polarization linear array, curved ridge waveguide 8 is directly connected with feeder network shown in Figure 11, perpendicular polarization outlet waveguide 16 is also half high waveguide, is of a size of 17.2mm*4.1mm.
The superiors of the present embodiment are horizontal polarization linear arrays, and the feeder network of horizontal polarization linear array is at orlop, and perpendicular polarization linear array and feeder network thereof are in intermediate layer, and half high outlet waveguide of two kinds of polarization, in same level, facilitates external LNB.
Described antenna array and feeder network all use the mounting means of screw fastening, select M2 screw to assemble, compared with the vacuum brazing technique of conventional waveguide slot antenna, greatly reduce processing cost.
The single ridged waveguides size of the present embodiment is identical with embodiment 1, Figure 13 shows that the standing wave curve chart of this routine two kinds, described antenna polarization linear array, Figure 14 is this routine horizontal polarization directions figure, Figure 15 is this routine vertical polarization directions figure, Figure 16 is the isolation between two kinds of polarization, Figure 17 be this routine feeder network by suitable phase compensation, the Circular polarization ratio performance plot realized in frequency band.
With this routine described antenna for unit, adopt 10 pieces of antennas to form a new dual-polarized array, the high-gain dual polarization oblique wave bundle array antenna of 38dB12.7GHz can be realized; Antenna described in the utility model, compared with conventional waveguide slot antenna, dual polarization feeder network is by suitable phase compensation, whole antenna can realize good Circular polarization ratio characteristic in frequency band, beam tilt angle and unit interval have nothing to do, ° scanning of oblique wave bundle ± 25 can reduce antenna section, and full screw mounting means reduces manufacturing cost, is convenient to batch and becomes to produce mould molding.
Above said content is dual polarization oblique wave beam waveguide slot array antenna embodiment described in the utility model; be not limited to the utility model; without departing from the concept of the premise utility; some simple deductions and replacement etc. can also be done, be all included within utility model protection scope that claims of the present utility model determine.
Claims (5)
1. dual polarization oblique wave beam waveguide slot array antenna, is characterized in that: comprise more than one cell array antenna, and described cell array antenna is made up of horizontal polarization linear array and perpendicular polarization linear array;
Described horizontal polarization linear array comprises horizontal polarization single ridged waveguides (1) and the horizontal polarization feeder network (11) of two parallel placements, and perpendicular polarization linear array comprises perpendicular polarization single ridged waveguides (2) and the perpendicular polarization feeder network (12) of two parallel placements; Described horizontal polarization linear array is parallel with perpendicular polarization linear array to be staggeredly placed, and two horizontal polarization single ridged waveguides (1) are positioned at upper strata, and two perpendicular polarization single ridged waveguides (2) are positioned at lower floor, forms dual-polarization cells array antenna; Described horizontal polarization single ridged waveguides (1) has broadside V-shaped radiating slot (3), and adjacent V-shaped radiating slot (3) equidistantly arranges; Perpendicular polarization single ridged waveguides (2) has broadside U-shaped radiating slot (4), and adjacent U-shaped radiating slot (4) equidistantly arranges;
Described cell array antenna can realize fixed beam tilt angle, and beam tilt angle and unit interval have nothing to do; Described fixed beam tilt angle is 45 °.
2. dual polarization oblique wave beam waveguide slot array antenna according to claim 1, is characterized in that: horizontal polarization single ridged waveguides (1) is connected by curved ridges waveguide (7) with horizontal polarization feeder network (11); Perpendicular polarization single ridged waveguides (2) is connected by curved ridge waveguide (8) with perpendicular polarization feeder network (12);
Two horizontal polarization single ridged waveguides (1) one end termination curved ridges waveguide (7), arrive horizontal polarization feeder network (11), other end termination horizontal polarization ridge waveguide turns coaxial converter (5), carries out feed by horizontal polarization feed waveguide (10); Two perpendicular polarization single ridged waveguides (2) the curved ridge waveguide of one end termination (8), arrive perpendicular polarization feeder network (12), other end termination perpendicular polarization ridge waveguide turns coaxial converter (6), carries out feed by perpendicular polarization feed waveguide (9), final forming unit array antenna; Described horizontal polarization feed waveguide (10) and perpendicular polarization feed waveguide (9) are staggered is up and down positioned at described cell array antenna the same side.
3. dual polarization oblique wave beam waveguide slot array antenna according to claim 2, it is characterized in that: described horizontal polarization ridge waveguide turns the positive bottom that coaxial converter (5) is positioned at horizontal polarization single ridged waveguides (1) one end, and perpendicular to horizontal polarization single ridged waveguides (2); One end of described perpendicular polarization single ridged waveguides (2) to bottom bend by twice 90 degree of bendings, is made perpendicular polarization ridge waveguide turn coaxial converter (6) and is parallel to perpendicular polarization single ridged waveguides (1).
4. dual polarization oblique wave beam waveguide slot array antenna according to claim 2, is characterized in that: described horizontal polarization feed waveguide (10) and perpendicular polarization feed waveguide (9) are the single ridged waveguides that cross section is spill.
5. dual polarization oblique wave beam waveguide slot array antenna according to claim 1 and 2, is characterized in that: compose in parallel a large flat array antenna by six cell array antennas; Wherein the feed end parallel connection of six horizontal polarization linear arrays forms a feeder network, and is connected to horizontal polarization outlet waveguide by ridge waveguide torque shape waveguide transformer (17); The feed end parallel connection of six perpendicular polarization linear arrays forms a feeder network, is connected to perpendicular polarization equally exports waveguide by ridge waveguide torque shape waveguide transformer.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201420676652.2U CN204289717U (en) | 2014-11-13 | 2014-11-13 | Dual polarization oblique wave beam waveguide slot array antenna |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201420676652.2U CN204289717U (en) | 2014-11-13 | 2014-11-13 | Dual polarization oblique wave beam waveguide slot array antenna |
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| CN204289717U true CN204289717U (en) | 2015-04-22 |
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| CN201420676652.2U Withdrawn - After Issue CN204289717U (en) | 2014-11-13 | 2014-11-13 | Dual polarization oblique wave beam waveguide slot array antenna |
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Cited By (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104332714A (en) * | 2014-11-13 | 2015-02-04 | 安徽四创电子股份有限公司 | Dual-polarized oblique beam waveguide slot array antenna |
| CN105846114A (en) * | 2016-04-01 | 2016-08-10 | 中国电子科技集团公司第三十八研究所 | Dual-waveband common-caliber antenna |
| CN112002998A (en) * | 2020-07-15 | 2020-11-27 | 中国人民解放军国防科技大学 | One-dimensional phase-scanning distributed digital all-solid-state active dual-polarization waveguide slot array antenna |
| CN112448173A (en) * | 2019-09-02 | 2021-03-05 | 诺基亚通信公司 | Polarized antenna array |
| CN114583459A (en) * | 2022-04-06 | 2022-06-03 | 中车青岛四方机车车辆股份有限公司 | Multilayer gap waveguide slot array antenna |
| CN115036701A (en) * | 2022-07-15 | 2022-09-09 | 上海几何伙伴智能驾驶有限公司 | Vehicle-mounted radar antenna unit based on non-radiation side feed-turn waveguide structure |
| CN117913531A (en) * | 2024-03-20 | 2024-04-19 | 成都华兴大地科技有限公司 | Ku and Ka frequency band co-polarization co-aperture one-dimensional scanning phased array antenna |
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2014
- 2014-11-13 CN CN201420676652.2U patent/CN204289717U/en not_active Withdrawn - After Issue
Cited By (13)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104332714B (en) * | 2014-11-13 | 2017-05-03 | 安徽四创电子股份有限公司 | Dual-polarized oblique beam waveguide slot array antenna |
| CN104332714A (en) * | 2014-11-13 | 2015-02-04 | 安徽四创电子股份有限公司 | Dual-polarized oblique beam waveguide slot array antenna |
| CN105846114A (en) * | 2016-04-01 | 2016-08-10 | 中国电子科技集团公司第三十八研究所 | Dual-waveband common-caliber antenna |
| CN105846114B (en) * | 2016-04-01 | 2020-03-06 | 中国电子科技集团公司第三十八研究所 | Dual-band common-caliber antenna |
| CN112448173A (en) * | 2019-09-02 | 2021-03-05 | 诺基亚通信公司 | Polarized antenna array |
| CN112002998B (en) * | 2020-07-15 | 2022-09-06 | 中国人民解放军国防科技大学 | One-dimensional phase-scanning distributed digital all-solid-state active dual-polarization waveguide slot array antenna |
| CN112002998A (en) * | 2020-07-15 | 2020-11-27 | 中国人民解放军国防科技大学 | One-dimensional phase-scanning distributed digital all-solid-state active dual-polarization waveguide slot array antenna |
| CN114583459A (en) * | 2022-04-06 | 2022-06-03 | 中车青岛四方机车车辆股份有限公司 | Multilayer gap waveguide slot array antenna |
| CN114583459B (en) * | 2022-04-06 | 2023-10-13 | 中车青岛四方机车车辆股份有限公司 | Multi-layer gap waveguide slot array antenna |
| CN115036701A (en) * | 2022-07-15 | 2022-09-09 | 上海几何伙伴智能驾驶有限公司 | Vehicle-mounted radar antenna unit based on non-radiation side feed-turn waveguide structure |
| CN115036701B (en) * | 2022-07-15 | 2023-08-22 | 上海几何伙伴智能驾驶有限公司 | Vehicle-mounted radar antenna unit based on non-radiation side-fed waveguide structure |
| CN117913531A (en) * | 2024-03-20 | 2024-04-19 | 成都华兴大地科技有限公司 | Ku and Ka frequency band co-polarization co-aperture one-dimensional scanning phased array antenna |
| CN117913531B (en) * | 2024-03-20 | 2024-05-17 | 成都华兴大地科技有限公司 | Ku and Ka frequency band co-polarization co-aperture one-dimensional scanning phased array antenna |
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