As is known in the art, some monopulse radar systems utilize analog monopulse antenna systems comprising multi-layer printed circuit boards (PCBs). The multi-layer PCBs include substrate cores and layers which are bonded together. For example, such PCBs can have a six (6)-layer, (4) core multi-layer configuration. The PCBs also include external multiple radio frequency (RF) connectors (e.g. GPPO connectors) to allow coupling with a transceiver and other circuitry.
As is also known, as the number of layers in the PCB increases, the cost to fabricate monopulse antenna systems increases along with the volume they occupy. Additionally, multi-layer PCB monopulse antenna system designs typically include a series of conductive vias (or more simply “vias”). In such designs, some vias can extend through some layers and others can extend through all the layers of the PCB. Such designs increase manufacturing complexity and thus increase manufacturing time and expense. Further, such multi-layer PCB monopulse circuits often utilize external RF connectors which add to the cost and footprint of the monopulse antenna systems.
This Summary is provided to introduce a selection of concepts in simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key or essential features or combinations of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter.
Described herein is a substrate having a monopulse waveguide circuit integrated therein. A substrate integrated waveguide monopulse antenna allows for a monopulse antenna system in a single substrate layer configuration.
In one aspect, a substrate integrated waveguide monopulse antenna comprises, a substrate having first and second opposing surfaces, a plurality of antenna elements disposed on one of the substrate surfaces, and a plurality of conductive vias disposed through the substrate to form a plurality of hybrid couplers, and a plurality of output couplers. The hybrid couplers are arranged such that they are capable of providing signals to and receiving signals from the antenna elements. Further the hybrid couplers are arranged around a perimeter of a substrate and configured to form a radio frequency (RF) “wrap-around” monopulse circuit.
In embodiments, the plurality of output couplers are coupled to one or more outputs and the plurality of output couplers are capable of providing signals to/from one or more outputs of the substrate integrated waveguide monopulse antenna to/from the hybrid couplers. Thus, the plurality of output couplers provide a means for providing signals to/from the substrate integrated waveguide monopulse antenna.
In embodiments, the plurality of antenna elements are provided on the first surface of the substrate. In embodiments, the plurality of antenna elements are provided on the second surface of the substrate. In embodiments, the plurality of conductive via holes extend through said substrate and extend between the first and second surfaces of said substrate. The plurality of conductive via holes are also arranged to form a plurality of resonant cavities with at least one resonant cavity coupled to each of the antenna elements such that the resonant cavities are capable of providing RF signals to and/or receiving RF signals from the antenna elements. The conductive vias form the plurality of hybrid couplers within the substrate and in embodiments, two of the plurality of resonant cavities are coupled to at least one port of the plurality of hybrid couplers. In embodiments The plurality of output couplers are provided on the second surface of the substrate.
In embodiments, a first conductive material can be disposed on the first surface of said substrate and can correspond to a conductive layer disposed on the first surface of said substrate. The plurality of antenna elements can be provided as slot antenna elements formed in the first conductive layer. The plurality of slot antenna elements can include a plurality of dogbone couplers.
The plurality of output couplers can be slotted output couplers. The second conductor on the second surface of the substrate can correspond to a ground plane layer. Each output coupler can be coupled to at least one port of said plurality of hybrid couplers.
The substrate integrated waveguide monopulse antenna can further comprise a transceiver that has first and second opposing surface. At least a portion of the first surface of the transceiver can be configured to couple to at least one of the plurality of output couplers.
The second surface of the substrate can be configured to lie flat on the first surface of the transceiver when the at least said portion of the first surface of the transceiver is coupled to said at least one of the plurality of output couplers.
The transceiver can be disposed under the second surface of the substrate.
In another aspect, a substrate integrated waveguide monopulse antenna comprises a substrate, a first conductive layer, a second conductive layer, a plurality of conductive via holes, and a plurality of slotted output couplers. The substrate has first and second opposing surface. A first side of the substrate is configured to couple with a seeker antenna comprising a plurality of slot antennas. The seeker antenna can further comprise a dichroic lens and a dish. The first conductive layer is disposed on the first surface of said substrate and is configured to receive the plurality of slot antenna elements. A second conductive layer is disposed on the second surface of said substrate. A plurality of conductive via holes extend through the substrate and extend between the first and second conductive layers. The plurality of via holes are arranged to form a plurality of resonant cavities and a plurality of hybrid couplers. At least one resonant cavity is coupled to each of said slot antenna elements. The plurality of slotted output couplers are provided in the second conductive layer. Two of the plurality of resonant cavities are coupled to at least one port of said plurality of hybrid couplers. Each slotted output coupler can be coupled to at least one port of said plurality of hybrid couplers.
The substrate integrated waveguide monopulse antenna can further comprise a transceiver. The transceiver can have first and second opposing surfaces, and at least a portion of the first surface of the transceiver can be configured to couple to at least one of the plurality of slotted output couplers. The transceiver can be disposed under the second surface of the substrate.
The second surface of substrate can be configured to lie flat on the first surface of the transceiver when the at least said portion of the first surface of the transceiver is coupled to said at least one of the plurality of slotted output couplers.
In an additional aspect, a substrate integrated waveguide monopulse antenna comprises a substrate, a first conductive layer, a plurality of slot antenna elements, a second conductive layer, and a plurality of conductive via holes. The substrate has first and second opposing surfaces. The first conductive layer is disposed on the first surface of said substrate. The plurality of slot antenna elements is provided in the first conductive layer. The second conductive layer is disposed on the second surface of said substrate. The plurality of conductive via holes extend through the substrate and extend between the first and second conductive layers. The plurality of conductive via holes are also arranged to form a plurality of resonant cavities and a plurality of hybrid couplers. The plurality of conductive via holes are further arranged to couple at least one resonant cavity to at least one port of a hybrid coupler.
A plurality of slotted output couplers can be provided in the second conductive layer. The plurality of conductive via holes can be further arranged to couple at least one slotted output coupler to at least one other port of a hybrid coupler.
The substrate integrated waveguide monopulse antenna can also comprise a transceiver that includes first and second opposing surfaces. At least a portion of the first surface of the transceiver is configured to couple to at least one of the plurality of slotted output couplers. The transceiver can be disposed under the second surface of the substrate.
The second surface of substrate can be configured to lie flat on the first surface of the transceiver when the at least said portion of the first surface of the transceiver is coupled to said at least one of the plurality of slotted output couplers.
The foregoing and other objects, features and advantages will be apparent from the following more particular description of the embodiments, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the embodiments.
Described herein is a monopulse antenna system having a waveguide monopulse integrated into a substrate to provide a “substrate integrated waveguide monopulse antenna.” The system utilizes a “wrap-around” monopulse network and slotted output couplers to interface with a transceiver. It should be appreciated that to promote clarity in the description of the broad concepts, systems and techniques sought to be protected, the systems and techniques have been substantially described in the context of a configuration with slot antenna elements. It is, of course, recognized that the concepts, systems and techniques may operate with other types of antenna elements provided in a layer of the substrate.
Referring now to
It should be appreciated that to promote clarity in the description of the concepts disclosed herein,
In some embodiments, the opposing surfaces of the substrate 102 may have a rounded shape with various foci, radii, and diameters—e.g. circles, ovals, ellipses, to name a few. In other embodiments, the opposing surfaces of the substrate 102 may have polygonal shape with various sides, widths, lengths, and angles—e.g. triangle, square, rectangle, to name a few. In the illustrative embodiment of
Substrate integrated waveguide monopulse and antenna system 100 also includes one or more slot antenna elements 108 provided in a first conductive layer disposed over the first surface 102a of substrate 102. Each slot antenna element 108 corresponds to an antenna element provided from one or more holes, or slots formed in the substrate. In the illustrative embodiments of
Slot antennas 108 are configured, at a first time, to transmit a desired radiation pattern, or transmit beam, according to transmit signals provided to system 100 by a transceiver or other signal source. When transmitting, each slot antenna 108 emits at least a portion of the desired transmit signal in accordance with a transmit beam. Slot antennas 108 are further configured, at a second time, to provide a receive beam. The receive beam receives at least a portion (or an “echo”), of the transmit beam. For example, the receive beam may receive a portion of a transmit signal that has been reflected or otherwise redirected from an object (e.g. a target or other structure). After receiving the receive signal at the slot antennas 108, the signals are provided to a monopulse circuit. The monopulse circuit will be described in further detail below with reference to
Substrate integrated waveguide monopulse and antenna system 100 further includes conductive via holes 104. Conductive vias 104 pass through a first conductive layer disposed over a first surface 102a of substrate 102 and extend through substrate 102 to terminate at a second conductive layer disposed over a second, opposing surface 102b of substrate 102. In some embodiments, conductive via holes 104 extend straight through the substrate 102 (i.e. at an angle of ninety (90) degrees relative to the substrate surface), while in other embodiments conductive via holes 104 extend through the substrate in different angles. In the illustrative embodiment of
Conductive vias 104 extending through substrate 102 are arranged to form at least one via fence. A via fence encompasses rows of via holes 104 spaced apart so as to form an impediment (and ideally a complete barrier or wall) to electromagnetic waves propagating in the substrate. Thus, conductive vias 104 can be used to direct (or channel) the electromagnetic waves in a desired direction.
Consequently, the at least one via fence is arranged to form a monopulse circuit comprising at least one 90° hybrid coupler 106 and to form at least one resonant cavity within substrate 102. In the illustrative embodiment of
Resonant cavities 114 comprise via fences arranged as to allow electromagnetic waves (i.e. radio frequency (RF) signals) to propagate oscillate between the via fences. As the RF signals propagate within the resonant cavity, electromagnetic waves at the predetermined resonant frequency of the resonant cavity are reinforced to produce standing waves at the predetermine resonant frequency of the resonant cavity.
The vias are also arranged to provide 90° hybrid couplers 106 through which RF signals propagate. Once the RF signals are received, each 90° hybrid coupler 106 are configured to process the RF signals provided thereto to generate and output a sum, azimuth difference, elevation difference, diagonal difference (also referred to as a Q difference), or any combination thereof as detailed in the discussion of
Conductive vias 104 are further arranged to form signal paths (e.g. waveguide signal paths) that couple each resonant cavity 114 to at least one port of a 90° hybrid coupler 106 of the monopulse circuit. The signal paths coupling each resonant cavity 114 to at least one port of a 90° hybrid coupler 106 are provided from “fences” of vias (i.e. “via fences”) arranged through which RF signals may be directed from the port of 90° hybrid coupler 106 to resonant cavity 114 or directed from resonant cavity 114 to the port of 90° hybrid coupler 106.
Substrate integrated waveguide monopulse antenna 100 also comprises at least one slotted output coupler 112 provided in a second conductive layer disposed over a second opposite, opposing surface 102b of substrate 102. Slotted output couplers 112 may include electroconductive contacts provided within the second conductive layer, an exposed portion of the second conductive layer, or a cutout of the second conductive layer. In the illustrative embodiment of
Slotted output couplers 112 are configured to couple with a transceiver or other signal source as detailed in the discussion of
Referring now to
The antenna feed network 200 includes at least one slot antenna 208 situated within each resonant cavity 214 formed by conductive vias 204. In other words, at least one slot antenna 208 is provided in the first conductive layer disposed over a first surface of substrate 202 so that it is surrounded by the conductive vias 204 arranged to form a resonant cavity 214. While in the illustrative embodiment of
As discussed with reference to
For example, in the illustrative embodiment of
The portions of the desired transmit signal are further provided to each resonant cavity 214 by the monopulse circuit. Each resonant cavity 214 receives portions of the desired transmit signal from at least one 90° hybrid coupler 106 of the monopulse circuit as detailed in the discussion with reference to
Similarly, in a receive mode of operation, each slot antenna 208 is configured to couple received signals to the resonant cavity 214 to which the slot antenna 208 is coupled. For example, in the illustrative embodiment of
Once the resonant cavities 214 have received the signals provided thereto from a respective slot antenna 208, a standing wave at the resonant frequency of the resonant cavity 214 is produced. The standing waves formed or otherwise produced by each resonant cavity 214 correspond to the receive signals from respective slot antennas 208 (i.e. the slot antennas 208 coupled to ones of resonant cavities 214). The RF energy is coupled to the monopulse circuit. In particular, the received RF signals are coupled from respective ones of the resonant cavities to at least one port of respective ones of circuit elements which comprise the monopulse circuit (e.g. a 90° hybrid coupler, a 0°/180° coupler or any other circuit elements which may be appropriately coupled to form a monopulse circuit). A 90° hybrid coupler will be discussed in further detail below with regards to
Referring now to
Of course, as described herein by provided the monopulse as described herein, the advantages of a compact substrate integrated waveguide monopulse and antenna system are provided.
It should also be noted that in the illustrative embodiment of
The monopulse substrate 302 includes at least one 90° hybrid coupler 306 having at least one port 309 coupled to at least one resonant cavity 214 and at least one port 313 coupled to at least one other resonant cavity 214. For example, referring to the illustrative embodiment of
Further, the 90° hybrid coupler 306 includes at least one port 307 coupled to a port of at least one other 90° hybrid coupler 306 and another port 311 coupled to a port of a further, distinct 90° hybrid coupler 306 (i.e. a 90° hybrid coupler 306 different from the 90° hybrid coupler coupled to the first side). For example, in the illustrative embodiment of
The monopulse circuit also includes at least one other 90° hybrid coupler 306 with a port 307 coupled to at least one slotted output coupler and a port 311 coupled to at least one other slotted input/output coupler. For example, in the illustrative embodiment of
According to some embodiments, slotted input/output couplers 112 coupled to 90° hybrid couplers 306 may be provided in a second conductive layer disposed over a second surface 302b of substrate 302. The slotted input/output couplers 112 are arranged in the second conductive layer such that they are surrounded by the conductive via holes 304 that form the 90° hybrid couplers 306 to which the slotted input/output couplers 112 are coupled. In other words, in the second conductive layer, slotted couplers 112 are located with via holes 304 that form a coupled 90° hybrid coupler. For example, in the illustrative embodiment of
Further, the other 90° hybrid coupler 306 includes at least one port 309 coupled to a port of at least one other 90° hybrid coupler 306 and another port 313 coupled to a port of a different, distinct 90° hybrid coupler 306 (i.e. a 90° hybrid coupler 306 different from the 90° hybrid coupler coupled to the first side). For example, in the illustrative embodiment of
As discussed above in reference to
Referring now to
Each slotted output coupler 412 is provided within a second conductive layer disposed over a surface of substrate 402. According to some embodiments, the surface 402b of substrate 402 over which the second conductive layer is disposed is opposite and opposing to the surface 402a of substrate 402 over which a first conductive layer providing slotted antenna elements 108 is disposed. For example, in the illustrative embodiment of
Each slotted output coupler 412 is coupled to the monopulse circuit via at least one port of a 90° hybrid coupler. This coupling comprises a via fence formed by conductive via holes 404. For example, in the illustrative embodiment of
According to some embodiments, each slotted output coupler 412 is further configured to couple with a transceiver. Each slotted output coupler 412 may couple with the transceiver via contact, wiring, wirelessly—or any combination thereof. While coupled to the transceiver, each slotted output coupler 412 is configured to receive electromagnetic waves from the transceiver and provide electromagnetic waves to the transceiver. In some embodiments, at a first time, the transceiver may generate a transmit beam to be emitted by substrate integrated monopulse and antenna system 400. The transceiver is configured to provide portions of the transmit beam to at least one slotted output coupler 412. The slotted output coupler 412 is configured to provide the portions of the transmit beam to the monopulse circuit via coupled port of a 90° hybrid coupler 106.
According to some embodiments, at a second time, at least one slotted output coupler 412 receives signals representing sum, azimuth difference, elevation difference, Q difference—or any combination thereof—from the monopulse circuit. Each slotted output coupler 412 is then configured to provide the signals to the coupled transceiver.
Referring now to
According to some embodiments, transceiver 514 comprises a first surface and a second, opposing surface with a thickness between the two surfaces. In some embodiments, substrate integrated monopulse antenna 502 is configured so that when coupled to at least a portion of transceiver 514 via slotted output couplers, a surface of substrate integrated monopulse and antenna system 502 lies flat on at least a portion of a surface of transceiver 514. In other embodiments, the entirety of one surface of substrate integrate monopulse antenna system 502 is in continuous contact with at least a portion of a surface of transceiver 514, while in other embodiments at least a portion of a surface of the substrate integrated monopulse antenna system 502 is in continuous contact with a surface of transceiver 514. In the illustrate embodiment of
In some embodiments, substrate integrated monopulse antenna system 502 is configured to couple to at least a portion of transceiver 514 directly without the use of external connectors, cable, wires, or any combination thereof.
Referring now to
According to some embodiments, substrate integrated waveguide and monopulse antenna system 100 may be configured to receive signals from antennas 616 of seeker antenna 600 so that antennas 616 are provided in a conductive layer disposed over a first surface of substrate 102. In other words, antennas 616 of seeker antenna 600 may comprise slot antennas 116 of substrate integrated waveguide monopulse and antenna system 100. Portions of a desired radiation pattern transmitted by antennas 616 pass through dichroic lens 618 and are collected by dish 620 to form the desired radiation pattern. The dichroic lens 618 may be an optional element. For example, the dichroic lens can be used in aperture systems having a common dish that collects energy for multiple sensors, e.g., radar and infrared. In such embodiments, the dichroic lens 618 separates and distributes appropriate portions of the received signals to appropriate sensors. Dichroic lens 618 comprises a dichroic material that acts as a filter when portions of the desired radiation pattern are passed through. Further, dish 620 is configured to receive echoes that are passed through dichroic lens 618 and delivered to slot antennas 618.
In embodiments, the seeker antenna 600 can be used to transmit radio frequency energy and subsequently collect returning energy from that transmission that has been reflected by target like objects. A monopulse comparator (not shown) of the antenna a system 100 divides the antenna into four quadrants, then combines and compares the detected signals in four ways: 1) summation of the four quadrants (e.g., upper, lower, left, and right), 2) difference between upper and lower quadrants, 3) difference between left and right quadrants, and 4) a diagonal difference of the quadrants. These signals are then directed to a receiver and processor in order to determine a relative target angle and distance.
As used herein, the term “waveguide” is used to describe any system of material boundaries or structures for guiding electromagnetic waves.
As used herein, the term “conductive via hole” (or “conductive vias” or more simply a “via”) is used to describe a signal path with extends through (rather than along a surface of) one or more circuit boards or through an entire substrate to electrically connect conductors (e.g. ground planes on opposing sides of a substrate). In embodiments to be described hereinbelow, a conductive via hole passes through a first conductive layer disposed over a first surface of a substrate and terminates at a second conductive layer disposed over a second surface of the substrate.
It should also be appreciated that, as used herein, relational terms, such as “first,” “second,” “top,” “bottom,” “left,” “right,” and the like, may be used to distinguish one element or portion(s) of an element from another element or portion(s) of the element without necessarily requiring or implying any physical or logical relationship or order between such elements.
Comprise, include, and/or plural forms of each are open ended and include the listed parts and can include additional parts that are not listed. And/or is open ended and includes one or more of the listed parts and combinations of the listed parts.
One skilled in the art will realize the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The foregoing embodiments are therefore to be considered in all respects illustrative rather than limiting of the invention described herein. Scope of the invention is thus indicated by the appended claims, rather than by the foregoing description, and all changes that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.
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