CN212257690U - Reflect array antenna unit and reflect array antenna - Google Patents
Reflect array antenna unit and reflect array antenna Download PDFInfo
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- CN212257690U CN212257690U CN202021842935.1U CN202021842935U CN212257690U CN 212257690 U CN212257690 U CN 212257690U CN 202021842935 U CN202021842935 U CN 202021842935U CN 212257690 U CN212257690 U CN 212257690U
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Abstract
The application discloses a reflection array antenna unit and a reflection array antenna, wherein an upper dielectric substrate and a lower dielectric substrate of the reflection array antenna unit are connected in a pressing mode, a radiation patch is arranged at the corner of the top surface of the upper dielectric substrate, and a first coupling gap, a second coupling gap and a third coupling gap which are located below the radiation patch are formed in an upper foil plate; the lower dielectric substrate comprises metallized through holes, and the metallized through holes, the upper foil plate and the lower foil plate form a dielectric integrated waveguide together; the metallized through holes comprise first metallized through holes which are uniformly distributed on the periphery of the antenna unit and at least one side of the radiation patch; the three gaps and the radiation patch play the role of a resonator, and are mutually coupled and cross-coupled, so that the filter has a filtering characteristic and can effectively inhibit out-of-band interference; the reflective array antenna feeds power to each antenna unit in an air feeding mode, has the characteristics of low loss, low section and high gain, has good signal quality, and has the characteristics of miniaturization and integration.
Description
Technical Field
The present application relates to the field of antenna technology, and in particular, to a reflect array antenna unit and a reflect array antenna.
Background
Microstrip antenna is a form of antenna appearing in the seventies of the 20 th century, and as early as 1953, deschammps proposed a concept of making a microstrip antenna using the radiation principle of a microstrip line. Until the development of microstrip transmission theory models and photolithographic techniques for copper-clad dielectric substrates, the first practical microstrip antennas were developed by scholars such as Munson and Howell. After the seventies, microstrip antennas have evolved further, both theoretically and in the breadth and depth of application, and have shown great potential for practical use. Various new forms of microstrip antennas with new performance are continuously appeared, and the microstrip antennas are widely applied to military fields such as satellite communication, navigation remote measurement and remote control, weapon fuze and the like, and civil fields such as modern mobile communication, personal communication, medical devices, environmental protection and the like.
With the mobile communication coming into the 5G era, the communication frequency spectrum is higher and higher, the electromagnetic wave loss is increased, and in order to ensure the communication coverage radius, the microstrip array antenna in the prior art needs to increase the number of antenna units to improve the antenna gain, however, after the number of units is increased, a complex feed network needs to be designed.
For a long time in the future, 5G and 4G/3G and the like coexist and develop for a long time, the occupied space of the antenna is large, the available space is more tense, and potential electromagnetic interference and coupling exist among different frequency spectrums.
It can be seen that the prior art antenna has the following problems in structure and effect: (1) the antenna is large in size, extra loss is introduced by a complex feed network, the problem is particularly prominent in a high-frequency millimeter wave frequency band, and high gain is difficult to realize; (2) there is also potential electromagnetic interference and coupling between the different frequency spectra, resulting in poor signal quality.
SUMMERY OF THE UTILITY MODEL
The application provides a reflection array antenna unit and a reflection array antenna, which are used for solving the problems in the prior art, reducing the volume of the reflection array antenna unit, feeding each antenna unit in an air feeding mode, realizing no need of a feeding network and meeting the requirement of a high-gain antenna; the antenna has the out-of-band rejection characteristic of filtering, and effectively solves the problems of electromagnetic interference and coupling among different frequency spectrums.
The application provides a reflection array antenna unit, which comprises an upper-layer dielectric substrate, an upper foil plate, a lower-layer dielectric substrate and a lower foil plate which are rectangular and are sequentially connected from top to bottom; the upper medium substrate and the lower medium substrate are connected in a pressing mode, a radiation patch is arranged at the corner of the top surface of the upper medium substrate, and a first coupling gap, a second coupling gap and a third coupling gap which are located below the radiation patch are formed in the upper foil plate; the lower dielectric substrate comprises metallized through holes, and the metallized through holes, the upper foil plate and the lower foil plate form a dielectric integrated waveguide together; the metalized through holes comprise first metalized through holes which are uniformly distributed on the periphery of the antenna unit and at least one side of the radiation patch.
It may also be preferred that the metalized via further comprises a matching via located at a transition corner of the dielectric integrated waveguide.
It may also be preferred that at least one first metalized via at one end of the dielectric integrated waveguide is offset inwardly as a second metalized via.
It may also be preferred that the first coupling slot, the second coupling slot and the third coupling slot are aligned centrally and are arranged in parallel.
It may also be preferred that the first, second and third coupling slits are perpendicular to the dielectric integrated waveguide propagation direction.
Preferably, the upper dielectric substrate includes a first dielectric substrate and a second dielectric substrate, and the first dielectric substrate and the lower dielectric substrate are connected by pressing the second dielectric substrate.
According to the reflection array antenna unit, a first layer of dielectric substrate and a third layer of dielectric substrate are pressed into a whole through a second layer of dielectric substrate, and the reflection array antenna unit forms a plane microstrip structure formed by the three layers of dielectric substrates; the first coupling gap, the second coupling gap, the third coupling gap and the radiation patch are in corresponding structures to realize a resonance function, and coupling and cross coupling exist among the first coupling gap, the second coupling gap, the third coupling gap and the radiation patch, so that the radiation patch has a filtering characteristic; the upper foil plate, the third layer of dielectric substrate and the lower foil plate form a dielectric integrated waveguide (SIW), the first metalized through holes are used for realizing the SIW, the diameter and the hole spacing of the first metalized through holes are designed according to the working frequency and the processing technology, and the low-loss and high-efficiency transmission of waveguide main mode energy in the SIW is realized; the matched through holes at the corners of the SIW improve impedance matching and reduce energy transmission loss in the waveguide; the second metalized via hole meets the reflecting phase of the reflective array antenna unit required by design by controlling position parameters.
The application still provides a reflect array antenna, including empty irradiation source and reflect array antenna plane of presenting, reflect array antenna plane include at least two if the utility model discloses an aspect reflect array antenna unit to the adjacent limit of rectangle top surface is x, y axle, reflect array antenna unit constitutes the matrix structure along x, y axle direction align to grid, and empty main lobe directional reflect array antenna plane center of presenting the irradiation source.
The utility model provides a reflect array antenna designs according to reflection phase curve reflect array antenna mainbeam direction accomplishes reflect array antenna designs, reflect array antenna has the characteristic of low side lobe, keeps high gain and gain flat in the in-band operating frequency range, in both sides outband frequency range, reflect array antenna gain is weakened, and the gain is lower than the in-band frequency, realizes filtering performance.
The reflect array antenna unit, the manufacturing method thereof and the reflect array antenna can achieve the following beneficial effects:
the reflection array antenna unit has the advantages that a planar microstrip structure is formed by three layers of dielectric substrates, the three gaps and the radiation patch play a role of a resonator, the resonance function is realized, coupling and cross coupling exist among the three gaps, the reflection array antenna unit has a filtering characteristic, and out-of-band interference can be effectively inhibited; according to the manufacturing method of the reflect array antenna unit, the position of the second metallized through hole in the reflect array antenna unit is adjusted in a moving mode, and the unit reflecting phase required by the reflect array antenna is achieved; the reflection array antenna combines the characteristics of a parabolic antenna and a microstrip array antenna, feeds each antenna unit in an air feed mode without a feed network, and has the characteristics of low loss, low section and high gain; the reflection array antenna has the filtering characteristic of the reflection array antenna unit, has an out-of-band rejection function, can effectively solve the problem of out-of-band interference, solves the problems of potential electromagnetic interference and coupling existing among different frequency spectrums, is good in signal quality, achieves high gain, also has the filtering characteristic, has the characteristics of miniaturization and integration, and is wide in application prospect.
Drawings
The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:
fig. 1 is a perspective view of a structure of a reflect array antenna unit of the present application.
Fig. 2 is a schematic diagram of a radiating patch of a reflect array antenna unit according to the present application.
Fig. 3 is a top view of a dielectric integrated waveguide of a reflectarray antenna unit of the present application.
Fig. 4 is a schematic diagram of a reflectarray antenna according to the present application.
FIG. 5 shows the reflection phase of the reflectarray antenna unit of the present application at 94GHz according to the second metallized via location parameter LmGraph of the variation.
Fig. 6 shows the main polarization pattern of the reflectarray antenna of the present application at 94 GHz.
Fig. 7 is a crossed pattern at 94GHz for the reflectarray antenna of the present application.
Fig. 8 is a graph of the gain of the reflectarray antenna of the present application.
In the figure, 1 is a radiation patch, 2 is an upper dielectric plate, 201 is a first dielectric substrate, 202 is a second dielectric substrate, 3 is a first metalized via, 4 is an upper foil plate, 401 is a first coupling slit, 402 is a second coupling slit, 403 is a third coupling slit, 5 is a lower dielectric substrate, 6 is a lower foil plate, 7 is a matching via, 8 is a second metalized via, 10 is an air-feed radiation source, and 11 is a reflection array antenna plane.
Detailed Description
In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
The technical solutions provided by the embodiments of the present application are described in detail below with reference to the accompanying drawings.
Example 1
A reflection array antenna unit is shown in fig. 1 and fig. 2, and comprises a rectangular upper dielectric substrate 2, an upper foil plate 4, a lower dielectric substrate 5 and a lower foil plate 6 which are connected in sequence from top to bottom; the upper dielectric substrate 2 and the lower dielectric substrate 5 are connected in a pressing mode, a radiation patch 1 is arranged at the corner of the top surface of the upper dielectric substrate 2, and a first coupling gap 401, a second coupling gap 402 and a third coupling gap 403 which are located below the radiation patch 1 are formed in the upper foil plate 4; the lower dielectric substrate 5 comprises metallized through holes, and the metallized through holes, the upper foil plate and the lower foil plate form a dielectric integrated waveguide together; the metallized via holes comprise first metallized via holes 3 which are uniformly distributed on the periphery of the antenna unit and at least one side of the radiation patch 1.
The method for manufacturing the reflect array antenna unit of this embodiment may include the following steps,
bonding a radiation patch 1 at one angular position of the top surface of an upper-layer dielectric substrate 2;
arranging a first coupling gap 401, a second coupling gap 402 and a third coupling gap 403 below the radiation patch 1 on the upper foil plate 4;
uniformly distributing and arranging metallized through holes 3 for realizing dielectric integrated waveguide on the peripheral edge of the lower dielectric substrate 5 and the central line of the lower dielectric substrate on at least one side of the radiation patch 1;
the upper dielectric substrate 2, the upper foil plate 4, the lower dielectric substrate 5 and the lower foil plate 6 are connected in sequence from top to bottom.
Example 2
A reflectarray antenna unit similar to that of embodiment 1, except that the metallized vias further comprise matched vias 7 located at the transition corners of the dielectric integrated waveguide.
The reflect array antenna unit may further include at least one first metalized via 3 at one end of the dielectric integrated waveguide and offset inward as a second metalized via 8.
The reflectarray antenna unit may further include a first coupling slot 401, a second coupling slot 402, and a third coupling slot 403 that are aligned in a center and arranged in parallel.
The reflectarray antenna unit may further include a first coupling slot 401, a second coupling slot 402, and a third coupling slot 403, which are perpendicular to the propagation direction of the dielectric integrated waveguide.
The reflect array antenna unit may further include that the upper dielectric substrate 2 includes a first dielectric substrate 201 and a second dielectric substrate 202, and the first dielectric substrate 201 and the lower dielectric substrate 5 are connected by pressing the second dielectric substrate 202.
In the method for manufacturing the reflect array antenna unit, at least one first metalized via hole 3 located at one end of the dielectric integrated waveguide may be shifted inward to be a second metalized via hole 8, and the position of the second metalized via hole 8 may be adjusted according to the main beam direction of the reflect array antenna.
The method for manufacturing the reflect array antenna unit may further include adjusting the position of the second metalized via 8 to change the position according to the required reflection phase control, where the change L is a distance that the second metalized via 8 moves to the inner side of the lower dielectric substrate 5.
In the method for manufacturing the reflect array antenna unit, the metalized via hole may further include a matching via hole 7 located at a transition corner portion of the dielectric integrated waveguide.
In the method for manufacturing the reflectarray antenna unit, the first coupling slot 401, the second coupling slot 402, and the third coupling slot 403 may be aligned in the center and arranged in parallel.
In the method for manufacturing the reflect array antenna unit, the first coupling slot 401, the second coupling slot 402, and the third coupling slot 403 may be perpendicular to the propagation direction of the dielectric integrated waveguide.
The method for manufacturing the reflect array antenna unit may further include that the upper dielectric substrate 2 includes a first dielectric substrate 201 and a second dielectric substrate 202, and the first dielectric substrate 201 and the lower dielectric substrate 5 are connected by pressing the second dielectric substrate 202.
Example 3
A reflect array antenna unit similar to embodiment 1 or embodiment 2 except that the radiating patch 1 is square and is located at the upper right corner of the top surface of the upper dielectric substrate 2, and has a side length of 0.3 to 0.5 times the wavelength of the medium of the upper dielectric substrate 2 and a thickness of 0.035 mm. As shown in fig. 3, the first coupling slit 401 has a width of 0.04 to 0.05 times the wavelength of the medium of the lower dielectric substrate 5 and a length of 0.3 to 0.33 times the wavelength of the medium of the lower dielectric substrate 5. The width of the second coupling slit 402 is 0.04-0.05 times of the wavelength of the medium of the lower dielectric substrate 5, and the length is 0.34-0.36 times of the wavelength of the medium of the lower dielectric substrate 5. The width of the third coupling slit 403 is 0.04-0.05 times of the wavelength of the medium of the lower dielectric substrate 5, and the length is 0.25-0.29 times of the wavelength of the medium of the lower dielectric substrate 5. The upper foil plate 4 is a copper foil plate with the thickness of 0.035 mm. The lower foil plate 6 is a copper foil plate with the thickness of 0.035 mm. The first metalized via hole 3, the second metalized via hole 8 and the matching via hole 7 are all round holes. The first and second metalized vias 3, 8 are of equal diameter. The diameter of the matching via 7 is 0.9 times the diameter of the first metalized via 3. The second metallized via 8 is a movable via whose position is moved by controlling the position parameter L to satisfy the cell reflection phase required by the reflectarray antenna. The reflection array antenna unit is square, and the side length size is 0.5-0.7 times of the corresponding wavelength at the central frequency. The upper dielectric substrate 2, the second dielectric substrate 202, the upper foil plate 4, the lower dielectric substrate 5 and the lower foil plate 6 preferably have the same length and width dimensions.
In the reflective array antenna unit of the embodiment, the upper dielectric substrate 2 and the lower dielectric substrate 5 are laminated into a whole through the second dielectric substrate 202, and the reflective array antenna unit forms a planar microstrip structure formed by three dielectric substrates; the first coupling gap 401, the second coupling gap 402, the third coupling gap 403 and the radiation patch 1 are correspondingly structured to realize a resonance function, and coupling and cross coupling exist among the first coupling gap, the second coupling gap, the third coupling gap and the radiation patch 1, so that the radiation patch has a filtering characteristic; the upper foil plate 4, the lower layer dielectric substrate 5 and the lower foil plate 6 form a dielectric integrated waveguide (SIW), the first metalized through holes 3 are used for realizing the dielectric integrated waveguide (SIW), and the diameter and the hole spacing of the first metalized through holes 3 realize low-loss and high-efficiency transmission of waveguide main mode energy in the SIW according to the working frequency and the processing technology; the matched through hole 7 at the corner of the SIW improves impedance matching and reduces energy transmission loss in the waveguide; the second metalized via 8 may satisfy the required reflection phase of the reflectarray antenna unit by controlling the position parameter L.
One of the millimeter waves works in a W wave band, the first layer of dielectric substrate 201 is a Rogers duroid5880 substrate, the relative dielectric constant is 2.2, and the thickness is 0.127 mm; the lower dielectric substrate 5 adopts a Rogers RO3006 substrate, the relative dielectric constant is 6.15, and the thickness is 0.25 mm; the second layer dielectric substrate 202 adopts Rogers RO4450F prepreg, the relative dielectric constant is 3.52, and the thickness is 0.101 mm; the reflect array antenna unit works in W wave band with center frequency of 94GHz, and the side length of the reflect array antenna unit is PunitSide length of the radiation patch 1 is LpatchThe diameter of the first metallized via hole 3 is DviaThe hole pitch between the first metallized via holes 3 is SviaAfter theoretical calculation and simulation optimization, a group of preferable structural parameters are as follows: punit=2.12mm,Lpatch=0.81mm,Dvia=0.22mm,SviaThe lengths of the first coupling slot 401, the second coupling slot 402 and the third coupling slot 403 may be different from each other, and a connection line of center points of the three may preferably be located on a same straight line, the straight line is parallel to one side of the reflect array antenna unit, and the straight line is perpendicular to the three, that is, the centers of the three are preferably aligned and arranged in parallel; the widths of the three are preferably equal; the distance between the three parts can be 90% of the width value. For example, the widths of the first coupling slot 401, the second coupling slot 402 and the third coupling slot 403 may be all 0.1mm, the length of the first coupling slot 401 is 0.68mm, the length of the second coupling slot 402 is 0.74mm, the length of the third coupling slot 403 is 0.58mm, and the distance between the first coupling slot 401, the second coupling slot 402 and the third coupling slot 403 is 0.09 mm. The diameters of the matched through holes 7 are all 0.2 mm; fig. 5 is a reflection phase response curve obtained by changing the position parameter L of the second metalized via 8 at an operating frequency of 94GHz, and it can be seen that the reflection phase varies linearly with L and can satisfy a phase interval of 360 degrees, thereby supporting the construction of the high-gain reflective array antenna.
Example 4
A reflection array antenna comprises an empty feed irradiation source 10 and a reflection array antenna plane 11, wherein the reflection array antenna plane 11 comprises at least two reflection array antenna units of any one of the embodiments, adjacent edges of a rectangular top surface are used as x and y axes, the reflection array antenna units are uniformly arranged along the x and y axes to form a matrix structure, and a main lobe of the empty feed irradiation source 10 points to the center of the reflection array antenna plane 11.
The reflect array antenna of this embodiment designs the reflect array antenna main beam direction according to the reflection phase curve, accomplishes the reflect array antenna design, the reflect array antenna has the characteristic of low side lobe, keeps high gain and gain flat in the in-band operating frequency range, in the out-of-band frequency range of both sides, reflect array antenna gain is weakened, and the gain is lower than the in-band frequency, realizes filtering performance.
Wherein the air-fed radiation source 10 is optionally a horn antenna with a position coordinate of (x)f,0,zf) And the feed main lobe is directed at the center of the reflect-array antenna plane 11. The plane 11 of the reflectarray antenna is made ofWith novel filtered reflectarray antenna elements arranged periodically along the x and y axes, and with the position parameter L of the movable vias 90 in each elementmAccording to the main beam direction (theta) of the designed reflect array antenna0,And (6) adjusting. Where M is 1 to M, M being the number of antenna elements constituting the array antenna, LmIs the position parameter of the mth antenna element.
Specifically, based on the reflectarray antenna unit, a reflectarray antenna operating in the millimeter wave W band, as shown in fig. 4, the air-fed radiation source 10 is selected as a linearly polarized standard gain horn antenna with a position coordinate of (x)f,0,zf) (-33.6mm, 0, 145.7mm), and the feed main lobe is directed to the center of the reflect array antenna plane 11; the reflectarray antenna plane 11 is a circular aperture plane with 80 × 80 of the reflectarray antenna units, and the main beam direction of the reflectarray antennaAs shown in fig. 5, which is a reflection phase curve, the position parameter L of the second metalized via 90 of each of the reflect array antenna units in the reflect array antenna plane 11 can be calculatedmThereby completing the complete reflective array antenna design.
As shown in fig. 6 and 7, the reflectarray antenna has excellent high-gain characteristics, a gain of up to 41dB, and ideal cross-polarization performance, which is-60 dB lower than the main polarization; in addition, the reflectarray antenna also has a low sidelobe characteristic with a sidelobe level below-30 dB.
As shown in fig. 8, in the in-band operating frequency range, the reflectarray antenna maintains high gain and flat gain, and in the two side out-of-band frequency ranges, the reflectarray antenna has greatly reduced gain, which is 19dB lower than the in-band frequency, and the transition band is steep and exhibits good frequency selectivity, thereby realizing filtering performance.
Example 5
In the reflect array antenna of embodiment 4, as shown in fig. 4, it is further possible that the reflect array antenna plane 11 is a circular aperture plane.
Still further, the null-feed illumination source 10 may be a horn antenna.
Further, the position of the second metalized via 90 in the reflect array antenna unit may be adjusted according to the main beam direction of the reflect array antenna.
The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.
Claims (7)
1. A reflection array antenna unit comprises an upper dielectric substrate (2), an upper foil plate (4), a lower dielectric substrate (5) and a lower foil plate (6) which are rectangular and are sequentially connected from top to bottom; the antenna is characterized in that an upper dielectric substrate (2) and a lower dielectric substrate (5) are connected in a pressing mode, a radiation patch (1) is arranged at the corner of the top surface of the upper dielectric substrate (2), and a first coupling gap (401), a second coupling gap (402) and a third coupling gap (403) which are located below the radiation patch (1) are formed in an upper foil plate (4); the lower dielectric substrate (5) comprises metallized through holes, and the metallized through holes, the upper foil plate and the lower foil plate form a dielectric integrated waveguide together; the metallized through holes comprise first metallized through holes (3) which are uniformly distributed on the periphery of the antenna unit and at least one side of the radiation patch (1).
2. The reflectarray antenna unit of claim 1, characterized in that the metallized via further comprises a matched via (7) located at a transition in the dielectric integrated waveguide.
3. The reflectarray antenna unit of claim 1, characterized in that at least one first metalized via (3) at one end of the dielectric integrated waveguide is offset inward as a second metalized via (8).
4. The reflectarray antenna unit of claim 1, characterized in that the first coupling slot (401), the second coupling slot (402) and the third coupling slot (403) are aligned centrally and in parallel.
5. The reflectarray antenna unit of claim 1, characterized in that the first coupling slot (401), second coupling slot (402), and third coupling slot (403) are perpendicular to the dielectric integrated waveguide propagation direction.
6. The reflectarray antenna unit of claim 1, characterized in that the upper dielectric substrate (2) comprises a first dielectric substrate (201) and a second dielectric substrate (202), and the first dielectric substrate (201) is press-fit connected to the lower dielectric substrate (5) via the second dielectric substrate (202).
7. A reflectarray antenna comprising an empty-feed illumination source (10) and a reflectarray antenna plane (11), the reflectarray antenna plane (11) comprising at least two reflectarray antenna elements according to any of claims 1-6, with adjacent sides of the rectangular top surface being the x-and y-axes, the reflectarray antenna elements being arranged uniformly in the x-and y-axes to form a matrix structure, and the main lobe of the empty-feed illumination source (10) being directed toward the center of the reflectarray antenna plane (11).
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111952722A (en) * | 2020-08-28 | 2020-11-17 | 中国信息通信研究院 | Reflective array antenna unit, reflective array antenna and manufacturing method |
CN113346218A (en) * | 2021-04-25 | 2021-09-03 | 天津大学 | High-gain 5G gap coupling solar antenna based on SISL structure |
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2020
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111952722A (en) * | 2020-08-28 | 2020-11-17 | 中国信息通信研究院 | Reflective array antenna unit, reflective array antenna and manufacturing method |
CN113346218A (en) * | 2021-04-25 | 2021-09-03 | 天津大学 | High-gain 5G gap coupling solar antenna based on SISL structure |
CN113346218B (en) * | 2021-04-25 | 2022-05-31 | 天津大学 | High-gain 5G gap coupling solar antenna based on SISL structure |
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