The present disclosure is generally related to phased array antennas.
Antenna arrays include a plurality of radiating elements which may be arranged on a printed circuit board (PCB). The area surrounding each of the plurality of radiating elements must be grounded to provide good ground continuity between assembly layers and to prevent radio frequency (RF) leakage (e.g., crosstalk) between radiating elements. As antenna arrays become increasingly smaller in size, it becomes more difficult to achieve operating frequencies in excess of fifteen (15) gigahertz (GHz). In particular, as the physical size of an antenna array becomes small, it becomes more difficult to ground the areas surrounding the radiating elements. The reduced physical size of the antenna arrays has resulted in an operating frequency plateau of approximately fifteen (15) GHz. Attempts to construct reduced size antenna arrays capable of operation at frequencies in excess of fifteen (15) GHz have failed due to an inability to reliably provide sufficient grounding contacts within the physical size limits of the reduced feature sizes of the antenna arrays, where the feature sizes of the components (e.g., the radiating elements, grounding contacts, etc.) of the antenna arrays are inversely proportional to the operating frequency.
An antenna (e.g., a phased array antenna) is disclosed and includes a plurality of radio frequency (RF) elements arranged into a plurality of rows and columns. Each of the plurality of RF elements is disposed on a printed circuit board (PCB). During operation, the antenna is configured to operate at RF frequencies in excess of fifteen (15) gigahertz (GHz). To provide good connection between the antenna assembly layers and to prevent leakage (e.g., crosstalk) of RF signals (i.e., RF leakage) between adjacent RF elements, the antenna includes one or more grounding shims (e.g., conductive sheets) configured to create ground contacts around a perimeter of each of the RF elements disposed on the PCB. The one or more grounding shims may be made of a conductive material (e.g., Beryllium-Copper) and may define a plurality of openings. Each of the one or more grounding shims includes a plurality of bumps disposed on a surface of the grounding shim and one or more of the plurality of openings defined by a grounding shim may be surrounded by a set of the plurality of bumps.
When assembled, the one or more grounding shims may be positioned between the PCB and a cover of the antenna, between the PCB and a pressure plate of the antenna, or both. The grounding shims are configured to align with the PCB such that the each openings of the grounding shim corresponds to a particular RF element of the PCB. During use of the antenna, the sets of bumps surrounding the one or more openings function as ground contacts and reduce RF leakage (e.g., crosstalk) between adjacent RF elements. An antenna according to one or more of the embodiments described herein may be capable of transmitting and receiving RF signals at frequencies up to and in excess of fifty (50) gigahertz (GHz).
In an embodiment, an apparatus includes a cover including a plurality of waveguides, a pressure plate, a printed circuit board (PCB) including a plurality of radiating elements of an antenna array, and a first conductive sheet defining a first plurality of openings and including a first plurality of bumps. One or more openings of the first plurality of openings is surrounded by a set of bumps of the first plurality of bumps. The PCB and the first conductive sheet are positioned between the cover and the pressure plate.
In an embodiment, a method includes coupling a printed circuit board (PCB) and a first conductive sheet to a pressure plate to form an antenna sub-assembly. The cover includes a plurality of waveguides. The PCB includes a plurality of radiating elements of an antenna array. The first conductive sheet defines a first plurality of openings and includes a first plurality of bumps. At least one opening of the first plurality of openings is surrounded by a set of bumps of the first plurality of bumps. The method includes coupling the antenna sub-assembly to a cover to form an antenna assembly. The PCB and the first conductive sheet are positioned between the cover and the pressure plate.
In another embodiment, an apparatus includes a printed circuit board (PCB) including a plurality of radiating elements of an antenna array, an antenna array radiating aperture comprising a plurality of conductive waveguides, and a conductive sheet comprising a plurality of bumps. The conductive sheet is positioned between the PCB and the antenna array radiating aperture. During operation of the antenna array, the plurality of bumps function as a plurality of ground contacts of the antenna array.
In another embodiment, a method includes coupling at least one conductive sheet to an antenna array. The at least one conductive sheet includes a plurality of bumps, and, during operation of the antenna array, the plurality of bumps function as a plurality of ground contacts of the antenna array.
Referring to
The PCB 120 includes a first surface 124 and a second surface 126. A plurality of radiating elements 122 of an antenna array may be disposed on the first surface 124 of the PCB 120. As shown in
As shown in
In an embodiment, the first plurality of bumps is disposed on the first surface 114 of the first conductive sheet 110. In another embodiment, the first plurality of bumps may be disposed on the second surface 116 of the first conductive sheet 110. One or more of the first plurality of openings 112 may be surrounded by a set of bumps of the first plurality of bumps. During use of the apparatus 100, the first plurality of bumps functions as ground contacts of the apparatus 100. The ground contacts (e.g., the first plurality of bumps) electrically isolate a corresponding one of the radiating elements 122 of the PCB 120 and reduce an amount of RF leakage (e.g., crosstalk) between adjacent radiating elements 122.
For example, referring to
As shown in
Ground contacts (e.g., the first plurality of bumps) between each of the first plurality of openings 112 may be sized in order to provide effective signal blocking (e.g., prevent RF leakage and cross-coupling between adjacent radiating elements based on a design frequency range of operation or based on a maximum design frequency). To illustrate, effective signal blocking may be achieved when each of the plurality of radiating elements 122 is surrounded by ground contacts (e.g., the first plurality of bumps) such that a distance between adjacent ground contacts (e.g., adjacent bumps of the first plurality of bumps) is approximately one-twentieth ( 1/20) of a wavelength apart. The wavelength corresponds to the shortest wavelength signal in the design frequency range. In a particular embodiment, the first plurality of bumps may be configured (e.g., sized and spaced) to provide effective RF ground contact and signal blocking between adjacent radiating elements of the apparatus 100 at a frequency range up to, and in excess of fifty (50) GHz. Specific dimensions of elements of the apparatus 100 described herein are examples of dimensions that may be used to enable operation of the apparatus 100 at a design frequency of fifty (50) GHz or more.
The first conductive sheet 110 and the first plurality of bumps provide a simple to manufacture, low cost solution for providing effective RF ground contact and signal blocking between radiating elements of antenna arrays configured to transmit and/or receive RF signals at frequencies up to, and in excess fifty (50) GHz. For example, the first conductive sheet 110 and the first plurality of bumps may be formed using a machining process, a mechanical punching process, a stamping process, an etching process, or a combination thereof. The size (e.g., a diameter, length, width, or height) and shape of each of the bumps of the first plurality of bumps may be determined based on the design frequency range of the apparatus 100. In an embodiment, each bump of the first plurality of bumps has a height of approximately two (2) one-thousandths of an inch relative to a surface (e.g., the first surface 114) of the first conductive sheet 110. In another embodiment, each of the first plurality of bumps has a height of approximately three (3) one-thousandths of an inch relative to a surface (e.g., the first surface 114) of the first conductive sheet 110. In another embodiment, each of the first plurality of bumps has a height of approximately four (4) one-thousandths of an inch relative to a surface (e.g., the first surface 114) of the first conductive sheet 110. In an embodiment, a base of each of the first plurality of bumps may have a diameter of approximately five (5) one-thousandths of an inch. In a particular embodiment, each bump of the first plurality of bumps has a domed shape. In another embodiment, each bump of the first plurality of bumps may have another shape.
Additionally, the spacing (i.e., the distance) between adjacent bumps may be selected to provide effective RF grounding and signal blocking (e.g., prevent RF leakage and cross-coupling between adjacent radiating elements) based on the design frequency range of the apparatus 100. For example, as illustrated in
Thus, when the apparatus 100 includes the first conductive sheet 110 and the PCB 120 between the cover 102 and the pressure plate 140, the apparatus 100 may be configured to transmit and/or receive RF signals with reduced RF leakage at frequencies up to, and in excess of fifty (50) GHz. In a particular embodiment, when the apparatus 100 includes the first conductive sheet 110 and the PCB 120 between the cover 102 and the pressure plate 140, the apparatus 100 may be configured to transmit and/or receive RF signals with reduced RF leakage at frequencies up to, and in excess of fifty (50) GHz. Additionally, the first conductive sheet 110 provides a simple to manufacture, low cost solution for providing effective signal blocking in the apparatus 100.
In a particular embodiment, effective RF ground and RF leakage between adjacent radiating elements of the plurality of radiating elements 122 is reduced when the apparatus 100 includes the first conductive sheet 110 between cover 102 and the first surface 124 of the PCB 120. However, RF leakage between adjacent radiating elements may also occur through the second surface 126 of the PCB 120. Thus, in a particular embodiment, the apparatus 100 may include the second conductive sheet 130 to prevent or reduce an amount of RF leakage via the second surface 126 of the PCB 120.
As shown in
For example, referring to
Ground contacts (e.g., the second plurality of bumps) between each of the second plurality of openings 132 may be sized to provide effective RF ground and signal blocking (e.g., prevent RF leakage and cross-coupling between adjacent radiating elements based on the design frequency range of operation or based on the maximum design frequency). In a particular embodiment, a distance between adjacent openings of the second plurality of openings 132 may be between seven (7) one-thousandths of an inch and ten (10) one-thousandths of an inch. As described with reference to
The second conductive sheet 130 and the second plurality of bumps provide a simple to manufacture, low cost solution for providing effective RF ground and signal blocking between radiating elements of antenna arrays configured to transmit and/or receive RF signals at frequencies up to, and in excess fifty (50) GHz. For example, the second conductive sheet 130 and the second plurality of bumps may be formed using a machining process, a mechanical punching process, a stamping process, an etching process, or a combination thereof. The size (e.g., a diameter, length, width, or height) and shape of each of the bumps of the second plurality of bumps may be determined based on the design frequency range of the apparatus 100. In an embodiment, each of the second plurality of bumps has a height relative to a surface (e.g., the second surface 136) of the second conductive sheet 130 between two (2) one-thousandths of an inch and four (4) one-thousandths of an inch. In an embodiment, a base of each of the second plurality of bumps may have a diameter of approximately five (5) one-thousandths of an inch. In a particular embodiment, each bump of the second plurality of bumps has a domed shape. In another embodiment, each bump of the second plurality of bumps may have another shape. In an embodiment, a shape of the second plurality of openings 132 may be determined based on a shape of the HF-IC packages coupled to the second surface 126 of the PCB 120, based on a shape of the plurality of recesses 148 defined by the pressure plate 140, or both.
Additionally, the spacing (i.e., the distance) between adjacent bumps may be selected to provide effective RF ground and signal blocking (e.g., prevent RF leakage and cross-coupling between adjacent radiating elements) based on the frequency range of the apparatus 100. For example, as illustrated in
Thus, when the apparatus 100 includes the second conductive sheet 130 and the PCB 120 between the cover 102 and the pressure plate 140, the apparatus 100 may be configured to transmit and/or receive RF signals with effective RF ground and reduced RF leakage at frequencies up to, and in excess of fifty (50) GHz. In a particular embodiment, when the apparatus 100 includes the second conductive sheet 130 and the PCB 120 between the cover 102 and the pressure plate 140, the apparatus 100 may be configured to transmit and/or receive RF signals with effective RF ground and reduced RF leakage at frequencies up to, and in excess of fifty (50) GHz. Additionally, the second conductive sheet 130 provides a simple to manufacture, low cost solution for providing effective signal blocking in the apparatus 100.
In an embodiment, the first conductive sheet 110, the second conductive sheet 130, or both, are made of a conductive material (e.g., a metal or metal alloy). For example, first conductive sheet 110 and the second conductive sheet 130 may be formed of Beryllium-Copper. In an embodiment, the first conductive sheet 110, the second conductive sheet 130, or both, may be treated to have a conductive surface. For example, first conductive sheet 110, the second conductive sheet 130, or both, may be gold plated. The gold plating may have a thickness between fifty (50) microns and seventy (70) microns. In a particular embodiment, the first conductive sheet 110, the second conductive sheet 130, or both, may be plated with Nickel before the gold plating is applied. The Nickel plating may have a thickness between fifty (50) micro-inches and two-hundred (200) micro-inches.
In a particular embodiment, a particular set of bumps surrounding a particular opening may include at least one bump in common with another set of bumps surrounding another opening that is adjacent to the particular openings. To illustrate, referring to
Referring to
As shown in
The plurality of connectors (e.g., the periphery connectors 144 and the internal connectors 146) may be tightened or loosened to adjust spring-loaded force between the pressure plate 140 and the cover 102. The spring-loaded force generated by the tightening of the plurality of connectors secures the first conductive sheet 110, the PCB 120, and the second conductive sheet 130 between the pressure plate 140 and the cover 102.
Additionally, during use, the apparatus 100 may generate heat, causing thermal expansion and/or thermal contraction of one or more of the components. The plurality of connectors is designed to generate constant pressure on the antenna assembly over a range of environmental changes (e.g., temperature). The constant pressure keeps the first plurality of bumps of the first conductive sheet 110 and the second plurality of bumps of the second conductive sheet 130 under constant pressure to secure ground contacts, as described with reference to
As shown in
Thus, an antenna array, such as the apparatus 100, that includes the first conductive sheet 110, the second conductive sheet 130, or both, may be configured to transmit and/or receive RF signals at frequencies up to, and in excess of fifty (50) GHz while providing RF ground and reducing an amount of RF leakage (e.g., cross talk) between radiating elements of the antenna array. Additionally, due to the low costs methods for producing (e.g., using a stamping process) the first conductive sheet 110 and the second conductive sheet 130, an antenna, such as the apparatus 100, may be manufactured at reduced cost.
Referring to
One or more of the first plurality of openings 112 is surrounded by a set of bumps of the first plurality of bumps. For example, referring to
In a particular embodiment, the cover 102 may include mechanical mounts 104. The mechanical mounts 104 may be configured to receive mounting bolts (not shown) or another form of connector that enables the apparatus 100 to be mounted on a structure (e.g., an aircraft, a land-based vehicle, a sea craft, a building, etc.). In a particular embodiment, the mechanical mounts 104 may be used to couple the apparatus 100 to one or more other devices (e.g., another apparatus 100).
As shown in
Referring to
One or more of the second plurality of openings 132 is surrounded by a set of bumps (e.g., the set of bumps 362) of the second plurality of bumps. For example, referring to
As shown in
As shown in
Referring to
When the connector 800 is tightened (i.e., secured to the connector receptacle 806), the connector 800 secures the first conductive sheet 110, the PCB 120, and the second conductive sheet 130 between the cover 102 and the pressure plate 140. Additionally, the tightening of the connector 800 applies clamping pressure to the antenna assembly. The clamping pressure applied by the connector 800 causes a portion of the first plurality of bumps of first conductive sheet 110 and a portion of the second plurality of bumps of the second conductive sheet 130 to maintain grounding of the plurality of radiating elements (e.g., the plurality of radiating elements 122) of the PCB 120. The portion of the first plurality of bumps corresponds to an area of the first conductive sheet that is proximate a connector opening (e.g., a periphery connector opening 404 or an internal connector opening 406) through which the connector 800 is extended. The portion of the second plurality of bumps corresponds to an area of the second conductive sheet that is proximate a connector opening (e.g., a periphery connector opening 604 or an internal connector opening 606) through which the connector 800 is extended. Thus, the plurality of connectors may include a number of connectors (e.g., the connector 800) such that the clamping pressure is applied across the entire antenna assembly. When the clamping pressure is applied across the entire antenna assembly, each set of bumps in the first plurality of bumps and the second plurality of bumps provides radio frequency (RF) grounding and reduces an amount of RF leakage (e.g., cross talk) between adjacent radiating elements of the PCB 120 during use of the antenna assembly.
In a particular embodiment, the connector 800 includes a spring 804. The spring 804 is configured to maintain force (e.g., an amount of pressure) applied by the connector 800 at constant level during environmental changes (e.g., changes in temperature). For example, use of the antenna assembly may generate heat, causing thermal expansion of one or more of the components of the antenna assembly. The spring 804 causes the force applied to the components of the antenna assembly (e.g., the first conductive sheet, the PCB, and/or the second conductive sheet) to be relatively constant despite thermal expansion of the one or more of the components, enabling each set of bumps in the first plurality of bumps and the second plurality of bumps to provide RF grounding and to reduce RF leakage (e.g., cross talk) between adjacent radiating elements of the PCB 120 during use of the antenna assembly.
Referring to
At 904, the method 900 includes coupling the antenna sub-assembly to a cover to form an antenna assembly. The PCB and the first conductive sheet are positioned between the cover and the pressure plate. The cover includes plurality of waveguides. In a particular embodiment, the cover corresponds to the cover 102 of
In an embodiment, the method 900 includes, at 906, coupling the antenna sub-assembly to a second conductive sheet. Coupling the antenna sub-assembly to the second conductive sheet may be performed prior to coupling the antenna sub-assembly to the cover to form the antenna assembly. The second conductive sheet defines a second plurality of openings and includes a second plurality of bumps. At least one opening of the second plurality of openings is surrounded by a set of bumps of the second plurality of bumps. The second plurality of bumps may be located on a first surface of the second conductive sheet of the antenna assembly. In this embodiment, the PCB, the first conductive sheet, and the second conductive sheet are positioned between the cover and the pressure plate. In an embodiment, the second conductive sheet corresponds to the first conductive sheet 110 of
The antenna assembly, during use, is configured to transmit and/or receive signals at a frequency up to, and in excess of fifty (50) gigahertz (GHz). During use of the antenna assembly, each set of bumps of the first plurality of bumps functions as ground contacts of the antenna assembly. During operation, the ground contacts (e.g., each set of bumps surrounding one of the openings defined by the first conductive sheet) electrically isolate a corresponding one of the radiating elements of the PCB from an adjacent radiating element. When the antenna assembly includes the second conductive sheet that includes the second plurality of bumps, each set of bumps of the second plurality of bumps function as ground contacts of the antenna assembly. During operation, the ground contacts (e.g., each set of bumps surrounding one of the openings defined by the second conductive sheet) electrically isolate a corresponding one of the radiating elements of the PCB.
By coupling the first conductive sheet and/or the second conductive sheet to the PCB between the cover and the pressure plate, the first plurality of bumps and/or the second plurality of bumps provide improved grounding and electrical isolation of the radiating elements of the PCB. Additionally, the first conductive sheet and/or the second conductive sheet are able to flex to accommodate thermal expansion and thermal contraction of the elements of the antenna assembly without losing grounding and electrical isolation of the radiating elements. Additionally, the elements of an antenna assembly assembled using the method 900 may flex (e.g., shift or bend) due to the forces generated when the pressure plate is coupled to the cover. The first plurality of bumps and/or the second plurality of bumps are configured to maintain contact (e.g., maintain grounding and electrical isolation of the radiating elements) with the PCB, the cover, and/or the pressure plate when the elements of the antenna assembly flex. Further, the plurality of connectors apply clamping pressure across the entire antenna assembly, enabling each set of bumps in the first plurality of bumps and the second plurality of bumps to provide radio frequency (RF) grounding and to reduce an amount of RF leakage (e.g., cross talk) between adjacent radiating elements of the PCB 120 during use of the antenna assembly.
Thus, an antenna assembly assembled using the method 900 has good RF ground contacts between each of the antenna assembly layers and reduces the amount of cross-coupling, the amount of radio-frequency (RF) leakage, and cross-talk between each of the radiating elements of the PCB, resulting in improved performance of the antenna assembly. Additionally, an antenna array according to one or more of the embodiments described herein may be manufactured and assembled at a reduced cost due to the simplicity of manufacturing the conductive sheet(s) (e.g., the first conductive sheet 110, the second conductive sheet 130, or both). For example, the conductive sheet(s) may be manufactured using a machining process, a mechanical punching process, a stamping process, an etching process, or a combination thereof.
The illustrations of the embodiments described herein are intended to provide a general understanding of the structure of the various embodiments. The illustrations are not intended to serve as a complete description of all of the elements and features of apparatus and systems that utilize the structures or methods described herein. Many other embodiments may be apparent to those of skill in the art upon reviewing the disclosure. Other embodiments may be utilized and derived from the disclosure, such that structural and logical substitutions and changes may be made without departing from the scope of the disclosure. For example, method steps may be performed in a different order than is shown in the illustrations or one or more method steps may be omitted. Accordingly, the disclosure and the figures are to be regarded as illustrative rather than restrictive.
Moreover, although specific embodiments have been illustrated and described herein, it should be appreciated that any subsequent arrangement designed to achieve the same or similar results may be substituted for the specific embodiments shown. This disclosure is intended to cover any and all subsequent adaptations or variations of various embodiments. Combinations of the above embodiments and other embodiments not specifically described herein will be apparent to those of skill in the art upon reviewing the description.
In the foregoing Detailed Description, various features may have been grouped together or described in a single embodiment for the purpose of streamlining the disclosure. This disclosure is not to be interpreted as reflecting an intention that the claimed embodiments require more features than are expressly recited in each claim. Rather, as the following claims reflect, the claimed subject matter may be directed to less than all of the features of any of the disclosed embodiments.
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