This disclosure generally relates to antennas, and more particularly, to a low profile antenna and a method of constructing the same.
An antenna is a type of device that is adapted to transmit and/or receive electromagnetic energy. For electromagnetic energy in the microwave frequencies, numerous differing types of antenna structures have been developed. One particular type of microwave antenna is the microstrip or patch antenna. Characteristic aspects of the patch antenna may include its relatively narrow bandwidth and low physical depth profile. Another popular type of microwave antenna is the notch antenna of which the flared notch antenna and cross notch antenna are several variations of the same. The notch antenna possesses a characteristically broader bandwidth than the patch antenna, yet requires a depth profile that is at least approximately ¼ wavelength at the lowest desired operating frequency.
In one embodiment, a low profile antenna comprises a balanced transmission line, electronic circuitry, and a parasitic element. The electronic circuitry is coupled to an interconnecting end of the transmission line and operable to direct electromagnetic energy through the transmission line to a terminating end. The parasitic element has a surface that is disposed at a predetermined distance from the terminating end and normal to the central axis such that the surface of the parasitic element covers an opening formed by the terminating end.
In another embodiment, a method for constructing a low profile antenna comprises providing a low profile antenna, determining the desired operating parameters of the antenna, and matching the impedance of the transmission line to free space. The low profile antenna generally includes a balanced transmission line, electronic circuitry, and a parasitic element. The electronic circuitry is coupled to an interconnecting end of the transmission line and operable to direct electro-magnetic energy through the transmission line to a terminating end. The parasitic element has a surface that is disposed at a predetermined distance from the terminating end and normal to the central axis such that the surface covers an opening formed by the terminating end.
Certain embodiments may provide numerous technical advantages. A technical advantage of one embodiment may provide an antenna having a relatively low depth profile while having a relatively wide bandwidth of operation. While other prior art implementations such as notch antennas have a relatively wide bandwidth, they require a profile that is generally at least a ¼ wavelength at the lowest frequency of operation. Certain embodiments may provide an operating bandwidth that is comparable to and yet have a depth profile significantly less than notch antenna designs.
Although specific advantages have been enumerated above, various embodiments may include all, some, or none of the enumerated advantages. Additionally, other technical advantages may become readily apparent to one of ordinary skill in the art after review of the following figures and description.
A more complete understanding of embodiments of the disclosure will be apparent from the detailed description taken in conjunction with the accompanying drawings in which:
Embodiments of the invention now will be described more fully below with reference to the accompanying drawings. Reference numerals used throughout this document refer to like elements in the drawings.
In one embodiment, the parasitic element 26 may be a flat plate made of a conducting material such as metal. The parasitic element 26 has a surface 28 that is generally perpendicular to the central axis such and covers an opening formed by the terminating end. In another embodiment, the low profile antenna 10 may include a dielectric layer 30 that is disposed in between the terminating end 16 of the balanced transmission line 12 and surface 28 of the parasitic element 26.
The balanced transmission line 12 may be a slotline, twinline, parallel plate, or other type of balanced structure. In one embodiment, the transmission line 12 has a length that is significantly shorter than the wavelength (λ) of the desired frequency of operation. The length of the transmission line 12 is the distance from the interconnecting 14 to the terminating 16 end. In another embodiment, the length of the transmission line may be less than ¼ wavelength of the operating frequency of the low profile antenna 10. In yet another embodiment, the length of the transmission line may be as low as approximately 1/10 the operating frequency of the low profile antenna 10. In this manner, a low profile antenna 10 may be constructed having a relatively low profile compared to known antenna designs with similar functionality. Therefore, tuning of the low profile antenna 10 is not accomplished by the transmission line 12; rather, tuning of the antenna is accomplished using the one or more parasitic elements 26 as will be described in detail below.
Certain embodiments may provide coupling of the terminating end 16 of a balanced transmission line 12 to free space using the parasitic element 26. Stated another way, the parasitic element 26 may be operable to match the impedance (Z) of the balanced transmission line 12 to free space. It is known that relatively efficient coupling of an antenna to free space occurs when the output impedance of the antenna is approximately 377 ohms, the characteristic impedance of free space. To accomplish this, particular physical characteristics of the parasitic element 26 or dielectric layer 30 may be selected in order to manipulate the output impedance of the low profile antenna 10. In one embodiment, a width W of the parasitic element 26 may be selected in order to manipulate the output impedance of the low profile antenna 10. In another embodiment, the dielectric layer 30 may be selected to have a predetermined depth D1. In this manner, the parasitic element 26 may be disposed a predetermined distance from the terminating end 16 that is essentially equal to depth D1.
In another embodiment, the dielectric layer 30 may be made of a material having a predetermined dielectric constant selected to manipulate the output impedance of the low profile antenna 10. In yet another embodiment, the dielectric layer 30 may be an open gap such that the dielectric layer 30 is made of air. Given the insulative aspects of the dielectric layer 30, the parasitic element 26 has no direct coupling to the electronic circuitry 18 through the transmission line 12. Thus, the dielectric layer 30 may serve a dual purpose of providing structural support for the parasitic element 26 relative to the transmission line 12 as well as to provide another approach of manipulating the output impedance of the low profile antenna 10.
The parasitic element 26 is shown centrally disposed over the transmission line 12; however, this is not necessary. In fact, the parasitic element 26 may be offset relative to the transmission line 12 in order to further manipulate various operating parameters of the low profile antenna 10. The term “offset” is referred to as placement of the parasitic element 26 over the transmission line 12 in such a manner that the transmission line 12 does not lie proximate the central portion of the parasitic element 26. Thus, the parasitic element 26 may be disposed in any manner such that the parasitic element 26 lies over the opening formed by the terminating end 16 of the balanced transmission line 12.
The low profile antenna 40 may be referred to as an array because multiple transmission lines 54 are associated with a corresponding multiple parasitic elements 48. The low profile antenna 40 generally comprises a manifold board 42, a plurality of metallic frames 44, one or more dielectric layers 46, and one or more parasitic elements 48. The metallic frames 44 may be configured to serve as one or more baluns as well as one or more transmission lines 54 (to be described below). The manifold board 42 may include circuitry that may be operable to convey an electrical signal from an unbalanced line to each of the one or more U-shaped members 56 functioning as baluns. The unbalanced signal may be provided by any typical unbalanced transmission line (not specifically shown) that may be, for example, a coaxial cable, unbalanced t-line feed, stripline, or a microstrip. In one embodiment, the low profile antenna 10 has a depth profile D2 that is relatively short as compared with other known antenna designs.
In this particular embodiment, two parasitic elements 48a and 48b are disposed over each of the U-shaped members 56 and 58. Thus, the low profile antenna 40 may have multiple parasitic elements 48a and 48b that serve to couple electromagnetic energy from the transmission line 54 to free space. Neither of the parasitic elements 48a and 48b have any direct coupling to the transmission line 54 or to each other. Isolation of the parasitic elements 48a and 48b is accomplished by two associated dielectric layers 46a and 46b. Dielectric layer 46a serves to separate parasitic element 48a from the balanced transmission line 54 by a predetermined distance D3. The second dielectric layer 46b serves to separate parasitic element 48b from parasitic element 48b by a second predetermined distance D4. In a similar manner to the low profile antenna 10 of
Once the desired operating parameters have been established, the impedance of the transmission line 12 or 54 is generally matched to free space over the desired bandwidth of frequencies in act 104. It should be appreciated that the act of matching the transmission line 12 or 54 to free space is not intended to provide a perfect match over the entire range of desired operating bandwidth. However, the terminology “matched” is intended to indicate a level of impedance matching over the desired range of operating frequencies sufficient to allow transmission and/or reception of electromagnetic energy from free space to the low profile antenna 10 or 40. The act of matching the transmission line 12 or 54 to free space may be accomplished by selecting one or more physical characteristics of the low profile antenna 10 or 40. The physical characteristics may include selecting the width of each of the one or more parasitic element 26 or 48, selecting a depth of the dielectric layer 30 or 46, selecting a dielectric constant of the material from which the dielectric layer 30 or 46 is formed, the number of parasitic elements 26 or 48 used, or the level of offset of the parasitic element 26 or 48 relative to the transmission line 12 or 54. It should be understood that other physical characteristics than those disclosed may be operable to modify the operating parameters of the low profile antenna 10 or 40. However, only several key physical characteristics have been disclosed for the purposes of brevity and clarity of disclosure.
Test results of an actual reduction to practice determine that the low profile antenna 40 may be designed having a frequency of operation in the range of 6 to 18 Giga-Hertz having a frequency bandwidth of 3:1. Additionally, the low profile antenna 40 may have an overall depth D2 of approximately 1/10 wavelength at the lowest operating frequency. The given operating parameters described above may be accomplished by implementing a quantity of two parasitic elements 48. Thus, it may be seen that a low profile antenna 40 may be realized having a relatively wide bandwidth in conjunction with a relatively low depth profile.
Although the present invention has been described with several embodiments, a myriad of changes, variations, alterations, transformations, and modifications may be suggested to one skilled in the art, and it is intended that the present invention encompass such changes, variations, alterations, transformation, and modifications as they fall within the scope of the appended claims.