The disclosed invention generally relates to antennas and more specifically to surface mounted notch radiators with folded PWB baluns.
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, which includes the flared notch antenna and cross notch antenna as some variations. 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 a notch antenna, the radiation pattern is determined by the size and shape of the notch or slot in the radiating surface.
Connectors 154 are transmission line conductors that extend across the bases of two adjacent tapers 110 to form a balun. The balun converts unbalanced signals from antenna drive circuit to balanced signals that may be propagated through first and second antenna elements as electro-magnetic energy. The posts 140 feature recessed edges below the top of the posts 140, where these recessed edges may form a balun slot between adjacent posts 140. Each column 120 may be configured with a portion of feed circuit 152, which may be a TRIMM card. The TRIMM cards may include ports that connect with the array base when the columns 120 are secured within the array base.
A Slat circuit board describes an electronics packaging configuration where adjacent circuit boards are arranged vertically (on an edge) and side by side instead of stacked on top of each other like planar or panel architectures. Receive integrated multichannel modules (RIMM) and transmit/receive integrated multichannel modules (TRIMM) are both slat configurations in which radar receive or transmit/receive electronics are respectively packaged on the vertically oriented circuit boards. This way, broadband tapered notches are easily integrated into the leading edges of these circuit boards.
Notch radiators are less suited for panel electronics architectures where the conductive bodies of the notch and the balun are implemented as separate surface mounted structures extending perpendicularly from the front and back faces, respectively, of the panel containing the transmission line feed circuits. This configuration is shown in
In some embodiments, the disclosed invention is an antenna notch radiator apparatus. The notch radiator apparatus includes: a planar circuit board having a plurality of different planar layers; a balun cavity formed between two ground layers of the planar circuit board that are separated by a laminated layer; a conductive notch formed horizontally in a plane parallel to the planar circuit board by two three dimensional (3D) structures formed on a top surface of the circuit board; a stripline signal feed folded within planar circuit board layers; and a plated hole formed vertically in a plane perpendicular to the planar circuit board and extending from the stripline signal feed, wherein the stripline signal feed electromagnetically transfer radio frequency (RF) energy into or out of the antenna notch radiator apparatus.
In some embodiments, the disclosed invention is a dual polarization antenna that includes: a planar circuit board having a plurality of different planar layers, wherein the planar circuit board includes a stripline layer and a folded balun layer in which, feed circuits for the orthogonal polarizations are formed; a plurality of dual polarization notches formed horizontally in a plane parallel to the planar circuit board; and a plurality of folded balun cavities form within an internal balun layer of the planar circuit board to feed the orthogonal polarizations.
In some embodiments, the disclosed invention further includes a second balun cavity formed between said two ground layers of the planar circuit board and a second notch formed by second two 3D structures mounted on the top surface of the circuit board to provide dual polarized excitation of the two notches. The two 3D structures may be surface mounted on the top surface of the circuit board and may be rectangular, curved-shaped or elliptical-shaped.
In some embodiments, the disclosed invention may further include a dielectric face sheet formed on top of the two 3D structures, is bonded to the top of the two 3D structures to increase the structural rigidity of the antenna notch radiator apparatus.
A more complete appreciation of the disclosed invention, and many of the attendant features and aspects thereof, will become more readily apparent as the disclosed invention becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings in which like reference symbols indicate like components.
According to some embodiments of the disclosed invention, a notch radiator is implemented using a low cost assembly method that is naturally suited for planar panel architectures and which frees up considerable space on the panel.
In some embodiments, the disclosed invention folds the notch balun horizontally into the panel dielectric layer stack up. This is done in a way that requires only one thin laminate layer, creates no routing keep-out zones for manifold feed layers within the panel, and requires no surface area on the back side of the panel. In some embodiments, the taper notch is implemented as a simple rectangular cube shape that reduces fabrication complexity/cost.
These components feed a tapered notch that is made from low-complexity, surface mountable, conductive 3D structures 302a and 302b. This configuration eliminates the requirement for a surface mounted balun cavity on the underside of the panel thus freeing up surface area for other components, and it removes the folded balun from the 3D notch body thus reducing its physical complexity and fabrication cost.
The horizontal extents of balun cavity 304 are controlled by the placement of grounding vias 310 connecting between ground planes. In some embodiments, the balun cavity 304 is an extension of the slotline taper mouth 320 that feeds vertically from above into the horizontal balun cavity through an etched slot 308 in the uppermost ground plane layer. Since the taper notch is located above the top ground plane 316 surface of the circuit board and the balun cavity 304 is located below the top ground plane surface of the circuit board, energy passing from the taper notch to the balun cavity 304 passes through the top ground plane surface by means of a slot opening in the ground plane. That is, one transmission line (the balun) is connected to another (the taper) through the slot in the ground plane.
As shown, a horizontal stripline feed 314 is also part of the multilayer panel stack up, formed below the balun cavity layer. This horizontal stripline feed 314 forms a transmission line that either feeds RF energy to or accepts RF energy from the radiator. The balun circuit facilitates the efficient transfer of energy between this unbalanced stripline feed and the balanced slotline taper.
A plated hole 306 (e.g., a via contact) extends vertically from the stripline signal line 312 and crosses the balun gap to electromagnetically transfer RF energy into or out of the notch radiator. In some embodiments, an array of step notch radiators are used to form an antenna array for, for example, radar and/or commercial communications when fed with this configuration of panelized folded balun. In some embodiments, all feed circuits are contained within the panel and the taper notch is a low complexity conductive 3D body that is easily attached to the top flat face of the panel circuit board, using, for example, conventional circuit board surface mount assembly methods.
In some embodiments, the folded notch radiator can also be used for a dual polarization antenna, for example, a vertically polarized and a horizontally polarized antenna. For this purpose, in some embodiments, two folded baluns, for example, similar to those depicted in
By folding the balun 408 into the horizontal layers of the panel circuit board along with the stripline feed manifold 412 and grounding vias 410, the embodiments of the disclosed invention eliminate a surface mounted balun cavity from the back side of the panel circuit board freeing up surface area that can be used for the packaging of supporting electronics 414a and interfaces 416. This configuration also eliminates a balun cavity within the body of the taper notch allowing the 3D conductive taper 402 to be a simplified shape that can be manufactured easily and inexpensively as a hollow cavity 404, thereby freeing up surface area on the top of the panel circuit board 406 for the packaging of other supporting electronics 414b. The optional dielectric face sheet 418 can be bonded to the top surface of the conductive taper to increase the structural rigidity of the entire structure.
The embodiments of the disclosed invention simplify fabrication of panelized notch arrays (lowers cost) by eliminating the need for a folded balun structure inside the 3D volume of the step notches, enabling a simplified 3D shape that is easily fabricated. The embodiments also improve panel packaging efficiency by freeing up area on top and bottom surfaces of panel since there is no radiator structure requirements, such as a balun cavity, for back side of panel and the hollow taper body serves as a cover for surface mounted electronics on front side. The disclosed invention also extends the practical frequency band to lower frequencies, minimizes thickness of circuit board stack-up needed for radiator implementation, folds the radiator balun horizontally (not vertically) within circuit board panel layers, and provides built-in electromagnetic interference (EMI) shielding and out-of-band filtering.
In some embodiments, the disclosed invention utilizes the body of the conductive taper as both a protective cover and EMI shield for feed circuitry and electronics. This structure (body) of the conductive taper may also be as a mounting surface for an optional dielectric face sheet, in some embodiments. In some embodiments, both single-pol and dual-pol radiators may be formed according to the disclosed invention.
Taper shapes can take many forms based on radiator performance requirements and cost objectives. For example,
Conductive step tapered notches 602 form a hollow cavity large enough to accommodate electronics therein. Optionally and similar to
It will be recognized by those skilled in the art that various modifications may be made to the illustrated and other embodiments of the invention described above, without departing from the broad inventive scope thereof. It will be understood therefore that the invention is not limited to the particular embodiments or arrangements disclosed, but is rather intended to cover any changes, adaptations or modifications which are within the scope of the invention as defined by the appended claims and drawings.
This Patent Application claims the benefits of U.S. Provisional Patent Application Ser. No. 62/551,176, filed on Aug. 28, 2017 and entitled “Surface Mounted Notch Radiator with Folded PWB Balun,” the entire content of which is hereby expressly incorporated by reference.
Number | Date | Country | |
---|---|---|---|
62551176 | Aug 2017 | US |