This invention relates to resonators and resonator antennas. These may be radiofrequency (RF) devices, and the invention may be applicable to miniaturized antennas.
Dielectric resonator antennas (DRA) have been researched extensively since their first introduction in [1]. Undoubtedly, DRAs possess many favorable properties, such as their ease of excitation, naturally wide bandwidth (e.g., as compared to microstrip patch antennas), and reduced conductive loss at higher frequencies [2], [3]. Compared to other antenna types, such as microstrip patch antennas or printed circuit board (PCB) integrated dipole antennas, DRAs can be considered quite voluminous because of their much higher profile. Thus far, relatively sparse attention has been paid to the design of low-profile DRA.
For the limited studies on low-profile DRAs, the focus has been mainly on developing wideband techniques. For example, a high-gain, low-profile wideband DRA has been presented in [4]. In this design, the radiation pattern was found to be not very stable across the passband. In [5] a wideband, low-profile DRA with a lattice structure has been proposed, but the lattice structure and the employed dielectric materials make it inconvenient for practical applications. Wideband low profile DRAs commonly suffer from large lateral extent, if common low dielectric constant materials with dielectric constants of approximately 10 are utilized. This is a disadvantage over other PCB-based antennas, such as microstrip patch antennas, which feature compact size. Although it is possible to use high dielectric constant materials with dielectric constants of much larger than 10, those materials are quite generally expensive and are not available for standard PCB fabrication.
Another type of low-profile dielectric antenna, which is conceptually similar to DRA and microstrip patch antenna, is the dense dielectric patch antenna (DD patch antenna) [6]. It is a dielectric patch with a high dielectric constant, mounted on a supporting substrate. Its radiation is attributed mainly to the fields at the edge of the patch, similar to a conventional patch antenna. For DD patch antennas, a dielectric constant of much more than 10 is usually employed. DD patch antennas can be designed with wide bandwidths, but at a high fabrication cost and additional manufacturing effort because of their incompatibility with PCB processes due to the need for high dielectric constant materials.
Different kinds of wideband DD patch antennas have been reported in the literature. For example, a wideband DD patch antenna with metallized slots has been reported in [7], with a bandwidth of 20.3%. In [8] a millimeter-wave DD patch antenna has been reported with 23.5% impedance bandwidth, but its structure is relatively complex with a high profile of 0.3λ0 where λ0 is the wavelength in air at the center frequency. Another example is a multi-segment DD patch antenna fed by two slots, as reported in [9]. This design achieves a very wide bandwidth of 80%, but a more complex feeding circuit is needed with large slots, leading to a degradation of the front-to-back-ratio of the antenna. Furthermore, parasitic patches were deployed, giving rise to a large antenna footprint. Other examples include a differentially fed DD patch antenna [10] and a filtering DD patch antenna [11]. Although some of those designs exhibit remarkable bandwidths, at least one of the following two points has been observed:
Even though many wideband DRA designs exist, they often rely on reshaping all of the three dimensions of the DRA, such as inverted staired DRA, for instance. Thus, these techniques are not applicable for low-profile designs because of the much-reduced thickness of the DRA.
On the other hand, dual polarized antennas possess the advantage of stabilizing communication links by providing two orthogonally polarized communication channels. Using dual polarized antennas, fading effects can be mitigated. In practice however, dual polarized low profile wideband antennas are sparse and not manufacturing friendly. Common approaches typically use suspended antennas such as cross dipoles or patch antennas. By suspending the antennas above the ground plane, the necessary wide bandwidths can be achieved, at the cost of manufacturing complexity and increase of the antenna profile to a value between 0.15-0.25λ0, as measured at the center frequency of the antenna. Furthermore, those antennas typically require additional components such as baluns, phase shifters and power dividers in order to function as a dual polarized antenna and achieve high isolation between the two antenna polarizations. In the case of dipole antennas, baluns are required to excite the dipole antenna. For the case of patch antennas, phase shifters may be required for differential port excitation in order to provide high isolation for the two different antenna ports. The mentioned features make these antennas not very attractive for mass production, as well as portable devices. In particular, any additional circuitry adds to the manufacturing cost as well as to the design complexity and contributes to additional antenna losses, which reduce the efficiency of the antenna.
The following references are referred to throughout this specification, as indicated by the numbered brackets:
Accordingly, the present invention, in one aspect, is a substrate-integrated dielectric resonator, which contains a first substrate layer with a first dielectric constant, a plurality of first vias, and a plurality of second vias. Each first via includes a first via-hole extending through the first substrate layer, and a first dielectric material with a second dielectric constant contained within the first via-hole. Each second via has a second via-hole extending through the first substrate layer and filled with a second dielectric material that has a third dielectric constant.
In some embodiments, the plurality of first vias and the plurality of second vias as a whole are distributed substantially across an entire area of the first substrate layer.
In some embodiments, the plurality of the first vias and the plurality of the second vias are distributed equidistantly from each other, and all the first vias and the second vias have the same diameter.
In some embodiments, the plurality of the first vias and the plurality of the second vias are arranged in a square lattice, a rectangular lattice, a triangular lattice or in a random manner.
In some embodiments, the plurality of second vias includes at least one of the followings: a group of said second vias for controlling an input impedance of the substrate-integrated dielectric resonator; a group of said second vias for enhancing an input bandwidth of the substrate-integrated dielectric resonator; and a group of said second vias for moving an undesired resonator mode out of a passband of the substrate-integrated dielectric resonator.
In some embodiments, the second dielectric constant is larger than the first dielectric constant.
In some embodiments, the third dielectric constant is smaller than the first dielectric constant.
In some embodiments, the third dielectric constant is in the range of 1 to 3.
In some embodiments, the second dielectric constant is equal to or smaller than 20.
In some embodiments, the first dielectric constant is equal to or smaller than 10.2.
In some embodiments, the plurality of second vias includes two parallel rows of said second vias. Each of the two parallel rows have two or more said second vias.
According to another aspect of the invention, there is provided a dielectric resonator antenna that includes a substrate-integrated dielectric resonator, and a second substrate layer arranged on one side of a first substrate layer of the substrate-integrated dielectric resonator. The substrate-integrated dielectric resonator contains a first substrate layer with a first dielectric constant, a plurality of first vias, and a plurality of second vias. Each first via includes a first via-hole extending through the first substrate layer, and a first dielectric material with a second dielectric constant contained within the first via-hole. Each second via has a second via-hole extending through the first substrate layer and filled with a second dielectric material that has a third dielectric constant. The second substrate layer includes a first microstrip feedline and an antenna ground plane.
In some embodiments, the dielectric resonator antenna includes a third substrate layer interposed between the second substrate layer and the first substrate layer.
In some embodiments, at least one of the third substrate layer and the second substrate layer has a fourth dielectric constant which is smaller than a first dielectric constant of the first substrate layer of the substrate-integrated dielectric resonator.
In some embodiments, the third substrate layer further contains a coupling slot that has a longitudinal direction intersecting with that of the first microstrip feedline.
In some embodiments, the third substrate layer contains a second microstrip feedline. The first microstrip feedline and the second microstrip feedline are configured as two feeding ports of the dielectric resonator antenna.
In some embodiments, the second microstrip feedline is configured with a plurality of first feeding vias therethrough.
In some embodiments, the third substrate layer further contains a plurality of second feeding vias which are mirrored from the plurality of first feeding vias about a center of the third substrate layer. The plurality of second feeding vias is located outside of the second microstrip feedline.
According to a further aspect of the invention, there is provided a method of fabricating a substrate-integrated dielectric resonator. The method contains the steps of providing a first substrate layer with a first dielectric constant, forming a plurality of first vias on the first substrate layer, and controlling a resonator mode of the substrate-integrated dielectric resonator by forming a plurality of second vias in the substrate-integrated dielectric resonator. Each said first vias has a via-hole extending through the first substrate layer, and a first dielectric material with a second dielectric constant contained within the first via-hole. Each said second via has a second via-hole extending through the first substrate layer and filled with a second dielectric material that has a third dielectric constant.
In some embodiments, the substrate-integrated dielectric resonator is part of a dielectric resonator antenna.
One can see that embodiments of the invention provide a compact antenna without the need for using external, high dielectric-constant materials that are unavailable for standard PCB manufacturing. The whole antenna structure can be manufactured using standard PCB materials and manufacturing technologies. Due to their low profile and compact size, compact antennas according to embodiments of the invention can be easily integrated into portable devices. Therefore, the antennas are suitable for quick and easy batch manufacturing. In particular, the antennas are suitable for applications, where wide bandwidths and low profile are required.
Also, for antennas provided by embodiments of the invention, by skillfully arranging second vias (e.g. air vias) inside the DRA, the resonant frequencies of different modes can be controlled, and a wide impedance bandwidth with stable radiation performance can be achieved. In one exemplary embodiment, the antenna has a bandwidth of 47.5% and it can easily fully cover the bandwidth of most commercial applications including the 5 GHz Wi-Fi band.
In exemplary embodiments, the antenna could be configured with single polarization or dual polarizations. For dual-polarized antennas in some embodiments of the invention, no additional circuitry, such as baluns, phase shifters, power dividers, are needed. Rather, by configuring two orthogonal antenna feeds in two substrate layers in such antennas, no additional circuitry is required for dual port operation, and good isolation can be achieved between the different antenna ports.
The foregoing summary is neither intended to define the invention of the application, which is measured by the claims, nor is it intended to be limiting as to the scope of the invention in any way.
The foregoing and further features of the present invention will be apparent from the following description of embodiments which are provided by way of example only in connection with the accompanying figures, of which:
In the drawings, like numerals indicate like parts throughout the several embodiments described herein.
Referring now to
The coupling slot 30 is formed in another metal planar layer 32 of the third substrate layer 26, which adjoins the second substrate layer 24. The layer 32 functions as the antenna ground plane of the antenna 20. The coupling slot 30 has a length lslot and a width wslot. The coupling slot 30 passes through the center of the third substrate layer 26 in the horizontal plane mentioned above. As best seen in
The second substrate layer 24 is used as a supporting substrate for the first substrate layer 22. The second substrate layer 24 has a thickness ts and dielectric constant εrs. The dielectric constants εrs and εrf can be the same or different. The first substrate layer 22 is the DRA substrate in the antenna 20, and it has a thickness of td and a dielectric constant of εrd. In one example, εrd=10.2. The first substrate layer 22 has a side length a, while the second substrate layer 24 has a length lg and a width wg.
As mentioned above, the first substrate layer 22 have via-holes that extend through the first substrate layer 22. In particular, as can be seen from
The cylindrical holes 44 are either filled with barium strontium titanate (BST) nanoparticles in which case dielectric vias 34 are resulted therefrom, or filled with air in which air vias are resulted. The first substrate layer 22 therefore contains a plurality of first vias (i.e. the dielectric vias) and a plurality of second vias (i.e. the air vias). As best shown in
Next, an effective-media approach aiming at simplifying the design of the antenna 20 in
With reference to
Following the same procedure, the calculation can be repeated for the case of air vias but is not shown here for brevity. To accelerate computer simulation, the results obtained by this calculation are used to obtain an equivalent material in place of the real physical via structures inside the first substrate layer 22. For each equivalent material, both parallel and perpendicular components of the effective dielectric constant must be used to correctly represent the dielectric-via and air-via structures. The equivalent layer representation of the design is illustrated in
The following results will employ the equivalent media approach if not stated otherwise. For the final results, the real physical structure is always simulated and compared with the measured results. For simulation mentioned in the descriptions hereafter, the Ansys HFSS full-wave simulation tool was used to generate all the simulated results.
The working principle of the antenna 20 in
Next, the second group 38 of air vias in
The effect of the second group 38 of air vias can be understood by considering the quality factor of the DRA [14]. A successive increase in the number of air-via pairs will locally decrease the effective dielectric constant of the DRA. Also, radiation can escape more easily from these parts of the structure, increasing radiation loss and, therefore, reducing the overall quality factor. Furthermore, the air vias have a positive effect on the antenna matching, as seen from
It should be mentioned that the position of the second group 38 of air vias is not arbitrarily chosen. The three arrows in
Next, the third group 40 of air vias is analyzed. As shown in
The working principle of the third group 40 of air vias is illustrated in
The input impedance after introducing the third group 40 of air vias is shown in
Finally, the first group 36 of air vias can be used to further enhance the antenna impedance bandwidth. The first group 36 of air vias are placed near the upper and lower edges, where the horizontal E-field of the TE311 mode has local maxima, as illustrated in
The design procedure in the above exemplary design approach be concluded as follows. By skillfully placing air vias inside the dielectric via loaded DRA, the resonant modes can be manipulated, thereby improving the antenna impedance bandwidth and matching. The air-via positions have to be chosen carefully in order to achieve the effects of input impedance control, manipulation of the DRA quality factor, and shifting or removal of dielectric-resonator modes that have undesirable radiation patterns.
Next, the resonant modes of the structure of the first substrate layer 22 are checked.
Experimental results were obtained to verify the simulations. An antenna prototype (not shown) was built according to the antenna 20 in
One can see that in the prototype, both the feeding substrate (which corresponds to the third substrate layer 26 in
In one example of the manufacturing method to make the antenna prototype, a powder material is used to constitute the dielectric vias. In this case, a multitude of methods can be used to protect the dielectric vias from its environment and assure that the powder stays in place. For instance, a thin layer of silicone can be used. Other methods include a thin sheet of material attached to the DRA substrate, such as to prevent leakage of environmental effects on the powder. In other instances of the invention the powder is replaced by a solid, a liquid material or a paste material, which can be dried after being inserted into the via holes. Similar to the powder case, the dielectric via material is protected by different means from environment influences, as well as assuring mechanical persistence of the structure.
The measured and simulated reflection coefficients are shown in
The measured and simulated realized antenna gains are compared in
This also shows that, even though the loss tangent of the BST material constituting the dielectric vias may appear quite high at first glance, reasonable antenna efficiencies can still be obtained because of the averaging effect of the substrate and BST materials. Since the BST vias occupy roughly 60% of the dielectric-via unit cell volume, the effective loss tangent of the dielectric-via loaded material is approximately an average of the loss tangents of the two materials.
The measured and simulated radiation patterns at 4.5 and 6.5 GHz are shown in
—/81.9
—/9.27
The effect of changing the dielectric via diameter of the single-port wideband design is also analyzed, and its result is shown in
A comparison of the antenna 20 with existing low-profile DRAs and DD patch antennas is given in Table I above. As can be observed from the table, the antenna 20 possesses the widest bandwidth amongst all of the DRA designs. Since the antenna 20 deploys a relatively low dielectric constant material, its size is somewhat larger than those using other approaches, such as DD patch antennas or other DRAs with very high dielectric constant materials, as in [5]. However, the fact that the antenna 20 can be fully manufactured using the PCB technology makes it very attractive for practical applications, as most other designs rely on expensive, high dielectric constant materials, and/or special manufacturing techniques to realize the designs. It should be noted that, due to the limitation of the employed design approaches, some designs in Table I may not be easily extended to dual-polarized designs. For instance, the design in [9] requires multiple slots and a power divider to achieve good impedance matching. Furthermore, the antenna is not symmetric, and its width is much larger than its length, making it difficult to obtain a dual-polarized wideband antenna. The prototype of the antenna 20 achieves a wide measured impedance bandwidth of 47.5% and a maximum measured gain of 6.84 dBi. Furthermore, a small antenna footprint of 0.616×0.616λ20 with a low profile of 0.095λ0 is achieved, where λ0 is the wavelength in the air at the center frequency.
A basic guideline for the design of the antenna 20 is outlined as follows.
Since the antenna 20 described above is dependent on the choice of the via size, it should be pointed out that, for other via and unit-cell sizes, the required length and width of the different air-via sections may vary a bit. As a general rule, the ratio of dielectric via-diameter to unit-cell size, dvia/dcell, should be approximately chosen as dvia/dcell=0.87. For smaller ratios, the design frequency will shift upward, and larger ratios result in frequency shift to lower frequencies.
Turning to
Compared to the antenna in
One can see that Port 2 of the antenna 120 (i.e., second microstrip feedline 148) is added along the x-axis. The circuit is printed on the second substrate layer 124, which has a thickness of ts and a dielectric constant of εrs. The Port 1 and Port 2 feeding circuits, that are, the first microstrip feedline and the second microstrip feedline 148, form an orthogonal feed system, i.e., the resonant modes of the two ports are orthogonally excited with respect to each other. It has been proven in [15] that this feeding scheme can achieve high port isolation for dual-polarized patch antennas.
Furthermore, four dielectric vias 134 are inserted into the second microstrip feedline 148 to enhance the overlapping bandwidth of the two ports. The dielectric vias 134 (also called “feeding vias” herein) are mirrored about the center of the second substrate layer 124 in order to keep the structure symmetric. As shown in
It was found that, compared with the Port 1, Port 2 has a slightly higher resonance frequency. This may be due to the boundary condition introduced by the metallic planar feedline, leading to a reduced overlapping bandwidth of the dual-port design. Loading the Port 2 feeding substrate (i.e., the second substrate layer 124) with dielectric vias 134, the resonance frequency of the fundamental mode of Port 2 can be shifted downward, thus widening the overlapping bandwidth of the antenna 120. The effect of these vias is shown in
Similar to the antenna in
Next, the arrangement of the second group of air vias in
Finally, in the simulation of the antenna 120, it was found that the E-fields excited by the planar feed tend to have significant y-directed components. This may be related to the spurious excitation of a hybrid TE/TM mode with Ex and significant Ey components in the H-plane (y-z plane) of Port 2, leading to a considerable cross-polar level. It was found that these y-directed E-fields increase the H-plane cross-polarization of Port 2. This is analogous to the cylindrical DRA case; its HEM21δ mode is one of the contributors to the H-plane cross polarization of the antenna when using a probe-feed excitation [16]. By loading the DRA with air vias at appropriate positions, this mode can be shifted to a higher frequency, and subsequently, the cross polarization can be reduced.
The third group 140 of air-vias in
A comparison of the normalized H-plane cross-polarization level of Port 2 before and after introducing the third group 140 of air vias is given in
It should be mentioned that, as in the case of the antenna in
A prototype (not shown) of the antenna 120 was fabricated with the following dimensions: a=32.5 mm, wg=50 mm, lg=50 mm, lslot=9 mm, wslot=5 mm, lstub=4 mm, wstrip=2.7 mm, dvia=2 mm, dcell=2.3 mm, l1=7.8 mm, w1=5.7 mm, dvia,2=1.2 mm, dfeed=12.85 mm, dload=0.75 mm, ts=1 mm, εrs=2.65, tf=1 mm, εrf=2.65, td=4 mm, and εrd=10.2. Plastic screws were used to fix the DRA to obtain a reliable measurement. The simulated results of the actual implementation are used instead of the dielectric layer model.
The measured and simulated S-parameters of the prototype of the dual-polarized antenna are shown in
Port 1 is matched across 4.45-6.6 and 4.67-6.78 GHz in the measurement and simulation, respectively. For port 2, it is matched across 4.64-7.06 and 4.83-6.99 GHz in the measurement and simulation, respectively. The measured and simulated overlapping bandwidths (|S11,22|<−10 dB) of the two ports are 34.88% and 33.6%, respectively. Across the overlapping passband, both the measured and simulated isolations between the two ports are higher than 25 dB, which is high enough for practical applications.
In
The measured total antenna efficiencies for both ports are shown in
The measured and simulated radiation patterns at 5 and 6.6 GHz are shown in
A comparison between the antenna 120 and existing dual-polarized antennas is shown in Table II above. Since there are many dual-polarized wideband designs, this list
is by no means complete. Instead, it focuses on the reported low-profile antennas. It was found that most of the previously reported dual-polarized wideband antennas have either suspended crossed dipoles or suspended patch antennas [17]-[21]. All of these antennas typically share some of the following features. The designs employ more complex feeding schemes, such as differential feeding, or require baluns and phase shifters to obtain dual-polarized operation. In contrast, the design of the antenna 120 has a simple feeding scheme, yet providing high isolation between the two ports. Furthermore, patch or crossed-dipole antennas need to be located at a distance above the ground plane, i.e., a rather large air gap exists between the ground plane and radiator. Therefore, most of these designs exhibit a relatively higher profile compared to our dual-polarized DRA. Although PCB can be employed in many of those designs, their assembly is more delicate than the antenna 120 because the radiator and/or other components are placed at a distance above the ground plane. Some of the designs exhibit lower cross-polarization levels. This is not surprising because many of the designs employ a differential feed or a balun to feed the antenna. The design of the antenna 120, however, has a very simple feed design without the need for any additional circuitry to operate the antenna. Finally, many of the designs employ non-PCB components to guarantee good performance, which can lead to additional costs and difficulty in the fabrication.
One can see that the antenna 120 can be manufactured using standard PCB materials and does not require any additional circuitry for dual port operation. The antenna 120 can achieve a bandwidth of more than 34.8%, while maintaining a low profile of 0.094λ0. Furthermore, the antenna 120 is planar and does not need to be suspended above a ground plane.
The design guideline for antenna 120 is based on that of the antenna in
The exemplary embodiments are thus fully described. Although the description referred to particular embodiments, it will be clear to one skilled in the art that the invention may be practiced with variation of these specific details. Hence this invention should not be construed as limited to the embodiments set forth herein.
While the embodiments have been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only exemplary embodiments have been shown and described and do not limit the scope of the invention in any manner. It can be appreciated that any of the features described herein may be used with any embodiment. The illustrative embodiments are not exclusive of each other or of other embodiments not recited herein. Accordingly, the invention also provides embodiments that comprise combinations of one or more of the illustrative embodiments described above. Modifications and variations of the invention as herein set forth can be made without departing from the spirit and scope thereof, and, therefore, only such limitations should be imposed as are indicated by the appended claims.
In the preferred embodiments mentioned above, the dielectric resonator contains dielectric vias and air vias. However, one should understand that the air vias are just examples of possible implementations of the invention. From an electromagnetics point of view the material inside the air vias is not limited to only air, as there are many other choices. More specifically, air in the air vias can be replaced with any material in other variations of the inventions, provided that the dielectric constant of the material is sufficiently lower than the dielectric constant of the first substrate (e.g. first substrate 22 in
In the embodiments described, three groups of air vias are arranged in the DRA structure in certain patterns substrate as shown in
Likewise, the invention is not limited by the number of air vias or by the position of the air vias. In other implementations of the invention, the air via structures are arranged in a different manner, such that electromagnetic control of the DRA is achieved.
In some implementations described above, the second dielectric constant of the dielectric materials in the dielectric vias is 20, and the first dielectric constant of the DRA substrate is 10.2. The invention is not limited by the choice of the substrate with a first dielectric constant. The invention is also not limited by the choice of the material constituting the dielectric vias with a second dielectric constant, nor is it limited by the choice of the material with the third dielectric constant. Those skilled in the art should understand that different dielectric materials with different dielectric constants can be chosen for the substrate(s) and the via(s), as long as they can be proceeded by standard PCB manufacturing processes. In general, low dielectric constant substrates with dielectric constants of ˜2-3 are preferred for the support and feeding substrate. However, it is not a necessity and other substrates, with higher dielectric constants can be used instead.
The first microstrip feedline and the second microstrip feedline in
In the embodiments described above, a number of holes are implemented as dielectric vias, whereas other holes serve the function of air vias. The holes have a diameter of dvia and are placed in square lattice with periodicity dcell. In particular, a 14×14 grid of via hole is employed in the antennas shown in
Regarding dual-polarized antennas, the invention is not limited by the choice of the size and position of the dielectric filled perforated holes in the second port feeding network of the antenna. In other implementations the position of the vias may vary. In yet another implementation the vias are placed outside of the metal part of the feeding network. It is also understood by anyone familiar with the art of antenna design, that other excitation schemes for the antenna can be used and the structure is only one example of the design idea.
It should be noted that although in preferred embodiments mentioned above, air is used to fill into the air vias in the dielectric resonator, the invention is not limited to the use of air (e.g. that from atmosphere). Rather, a different gas including different gas mixtures can be used to fill the air vias, and air is only one example that is used to explain the invention. As skilled persons understand, when air is mentioned it means a mixture of nitrogen, oxygen, and minute amounts of other gases that surrounds the earth and forms its atmosphere. When there is a need, the air vias can also be encapsulated to prevent the gap from leaking from the air vias.
Number | Name | Date | Kind |
---|---|---|---|
6147647 | Tassoudji et al. | Nov 2000 | A |
6344833 | Lin et al. | Feb 2002 | B1 |
8519542 | Kim | Aug 2013 | B2 |
9343810 | Chen et al. | May 2016 | B2 |
10381735 | Miraftab | Aug 2019 | B2 |
10714823 | Balanis et al. | Jul 2020 | B2 |
10856408 | Leung | Dec 2020 | B1 |
11670859 | Leung | Jun 2023 | B1 |
20110248890 | Lee | Oct 2011 | A1 |
20220013915 | Han | Jan 2022 | A1 |
Entry |
---|
S. A. Long, M. McAllister, and L. C. Shen, “The resonant cylindrical dielectric cavity antenna,” IEEE Trans. Antennas Propag., vol. 31, No. 3, pp. 406-412, May 1983. |
A. Petosa, Dielectric resonator antenna handbook. Boston: Artech House, 2007. |
K. M. Luk and K. W. Leung, Ed., Dielectric resonator antennas. Baldock: Research Studies Press, 2003. |
Y. M. Pan and S. Y. Zheng, “A Low-Profile Stacked Dielectric Resonator Antenna With High-Gain and Wide Bandwidth,” IEEE Antennas Wireless Propag. Lett., vol. 15, pp. 68-71, 2016. |
X.-Y. Dong, W.-W. Yang, H. Tang, and J.-X. Chen, “Wideband low-profile dielectric resonator antenna with a lattice structure,” Electron. Lett., vol. 53, No. 19, pp. 1289-1290, Sep. 2017. |
H. W. Lai, K.-M. Luk, and K. W. Leung, “Dense Dielectric Patch Antenna-A New Kind of Low-Profile Antenna Element for Wireless Communications,” IEEE Trans. Antennas Propag., vol. 61, No. 8, pp. 4239-4245, Aug. 2013. |
S.-C. Tang, X.-Y. Wang, W.-W. Yang, and J.-X. Chen, “Wideband Low-Profile Dielectric Patch Antenna and Array With Anisotropic Property,” IEEE Trans. Antennas Propag., vol. 68, No. 5, pp. 4091-4096, May 2020. |
Y. Li and K.-M. Luk, “Wideband Perforated Dense Dielectric Patch Antenna Array for Millimeter-Wave Applications,” IEEE Trans. Antennas Propag., vol. 63, No. 8, pp. 3780-3786, Aug. 2015. |
H. Wu and J. Shi, “A Wideband Dual-Slot Coupled Multiple Dense Dielectric Patch Antenna,” IEEE Antennas Wireless Propag. Lett., vol. 19, No. 6, pp. 944-948, Jun. 2020. |
X.-Y. Wang, S.-C. Tang, L.-L. Yang, and J.-X. Chen, “Differential-Fed Dual-Polarized Dielectric Patch Antenna With Gain Enhancement Based on Higher Order Modes,” IEEE Antennas Wireless Propag. Lett., vol. 19, No. 3, pp. 502-506, Mar. 2020. |
X.-Y. Wang, S.-C. Tang, X.-F. Shi, and J.-X. Chen, “A Low-Profile Filtering Antenna Using Slotted Dense Dielectric Patch,” IEEE Antennas Wireless Propag. Lett., vol. 18, No. 3, pp. 502-506, Mar. 2019. |
H. I. Kremer, K. W. Leung and M. W.K. Lee, “Design of substrate integrated dielectric resonator antenna using dielectric vias,” IEEE Trans. Antennas Propag. (available in Early Access of IEEE Xplore). |
M. Mrnka, “An Effective Permittivity Tensor of Cylindrically Perforated Dielectrics,” IEEE Antennas Wireless Propag. Lett., vol. 17, No. 1, p. 4, 2018. |
Chowdhury, R. Kumar, and R. K. Chaudhary, “A new technique to enhance the impedance bandwidth of CDRA using drilling holes,” in 2016 11th International Conference on Industrial and Information Systems (ICIIS), Roorkee, India, Dec. 2016, pp. 259-262. |
M. W. K. Lee and Y. L. Chow, “Patch Antenna of Dual Polarization with Complementary Feeds:—a design for high isolation between the two ports and a radiation of low cross-polarization from each port,” in TENCON 2006-2006 IEEE Region 10 Conference, Hong Kong, Nov. 2006, pp. 1-3. |
H. Gajera, D. Guha, and C. Kumar, “New Technique of Dielectric Perturbation in Dielectric Resonator Antenna to Control the Higher Mode Leading to Reduced Cross-Polar Radiations,” IEEE Antennas Wireless Propag. Lett., vol. 16, pp. 445-448, 2017. |
Q. Li, S. W. Cheung, and C. Zhou, “A Low-Profile Dual-Polarized Patch Antenna With Stable Radiation Pattern Using Ground-Slot Groups and Metallic Ground Wall,” IEEE Trans. Antennas Propag., vol. 65, No. 10, pp. 5061-5068, Oct. 2017. |
J. Zhang, K. Yang, E. Eide, S. Yan, and G. A. E. Vandenbosch, “Simple Triple-Mode Dual-Polarized Dipole Antenna With Small Frequency Separation Ratio,” IEEE Antennas Wireless Propag. Lett., vol. 19, No. 2, pp. 262-266, Feb. 2020. |
Y. Zhang, Z. Song, W. Hong, and R. Mittra, “Wideband high-gain ±45° . dual-polarised stacked patch antenna array for Ku-band back-haul services,” IET Microw. Antennas Propag., vol. 14, No. 1, pp. 53-59, Jan. 2020. |
Shi-Gang Zhou, Peng-Khiang Tan, and Tan-Huat Chio, “Low-Profile, Wideband Dual-Polarized Antenna With High Isolation and Low Cross Polarization,” IEEE Antennas Wireless Propag. Lett., vol. 11, pp. 1032-1035, 2012. |
H. Zhu, Y. Qiu, and G. Wei, “A Broadband Dual-Polarized Antenna With Low Profile Using Nonuniform Metasurface,” IEEE Antennas Wireless Propag. Lett., vol. 18, No. 6, pp. 1134-1138, Jun. 2019. |
Design of Substrate-Integrated Dielectric Resonator Antenna With Dielectric Vias. / Kremer, Hauke Ingolf; Leung, Kwok Wa; Lee, Mike W. K. In: IEEE Transactions on Antennas and Propagation, vol. 69, No. 9, Sep. 2021, p. 5205-5214. |
Number | Date | Country | |
---|---|---|---|
20230318187 A1 | Oct 2023 | US |