The present application claims the benefit of priority to Chinese Patent Application No. CN 2019110212930, titled “ANTENNA PACKAGING STRUCTURE AND METHOD FOR FORMING THE SAME”, filed with CNIPA on Oct. 25, 2019, and Chinese Patent Application No. CN2019218043495, titled “ANTENNA PACKAGING STRUCTURE AND METHOD FOR FORMING THE SAME”, filed with CNIPA on Oct. 25, 2019, the disclosure of both are incorporated herein by reference in its entirety.
The present disclosure generally relates to electronic devices, in particular, to an antenna packaging structure and a method for forming the same.
The advanced developments of science and technology have brought in various high-tech electronic products to improve people's lives, including high-tech electronic devices such as laptop computers, mobile phones, and tablet personal computers. Wireless communication technologies have added tremendous popularity to these electronic products. Thanks to wireless communication technologies, users can access these products from any places and at any times, providing convenience to users.
Antenna in Package (AiP) is a technology that integrates antennas and chips in a single package to achieve system-level wireless functions. AiP technology conforms with the trend of increasing silicon-based semiconductor process integration, and provides a good antenna packaging solution for system-level wireless chips. Therefore, AiP technology has become a necessary technology for 5G (5th Generation) communications and automotive radar chips and receives a great amount of attention. Wafer-level Packaged Antennas technologies (WLP AiP) operate on an entire wafer and fabricate antennas on a plastic encapsulation layer. So Compared with the traditional AiP module, WLP AiP has a higher precision. WLP AiP module is lighter, thinner and smaller in size. In the application of antennas, such as in the application of mobile phone terminals, the antennas transmitting and receiving signals need to be integrated with multiple functional chip modules. One traditional method is to directly fabricate the antennas on the surface of a circuit board (PCB), which requires the antennas to occupy additional circuit board area. This method results in long transmission signal lines, poor performance, high power consumption, large package volume, resulting in high transmission loss when transmitting 5g millimeter waves, therefore questionable protection for chips.
The present disclosure provides a method for packaging antennas, which includes: forming a temporary bonding layer on a supporting substrate; forming a rewiring layer on the temporary bonding layer, the rewiring layer including a first surface connected to the temporary bonding layer, and a second surface opposite to the first surface; fabricating a first antenna layer on the second surface, with the first antenna layer electrically connected to the rewiring layer; fabricating first metal feedline pillars on the first antenna layer, with the first metal feedline pillars electrically connected to the first antenna layer; encapsulating the first metal feedline pillars with a first packaging layer, with top surfaces of the first metal feedline pillars exposed on the first packaging layer; fabricating a second antenna layer on the first packaging layer, with the second antenna layer electrically connected to the first metal feedline pillars; fabricating second metal feedline pillars on the second antenna layer, with the second metal feedline pillars electrically connected to the second antenna layer; encapsulating the second feedline pillars with a second packaging layer, with top surfaces of the second feedline pillars exposed on the second packaging layer; fabricating a third antenna layer on the second packaging layer, with the third antenna layer electrically connected to the second feedline pillars; peeling the temporary bonding layer off from the rewiring layer and the supporting substrate, to expose the first surface of the rewiring layer; forming a first opening on the first surface in the rewiring layer; fabricating one or more semiconductor chips on the first surface, with the one or more semiconductor chips electrically connected to the rewiring layer; forming a metal bump in the first opening, with the metal bump electrically connected to the rewiring layer; encapsulating the one or more semiconductor chips and the meta bump using a third packaging layer; and forming a second opening in the third packaging layer, with the metal bump exposed by the second opening.
The present disclosure also provides an antenna packaging structure, which includes a supporting substrate, a rewiring layer on the supporting substrate, a first antenna layer on the rewiring layer, first metal feedline pillars on the first antenna layer, a first packaging layer covering the first metal feedline pillars except exposing the top surfaces of the first metal feedline pillars, a second antenna layer on the first packaging layer, second metal feedline pillars, a second packaging layer covering the second metal feedline pillars except exposing the top surfaces of the second metal feedline pillars, a third antenna layer on the second packaging layer, semiconductor chips connected to the rewiring layer, a metal bump inside an opening in the rewiring layer, and a third packaging layer encapsulating the semiconductor chips and the metal bump.
One or more specific embodiments of the present disclosure will be described below. These described embodiments are only examples of the presently disclosed techniques, and are not intended to limit aspects of the presently disclosed invention. Additionally, in an effort to provide a concise description of these embodiments, all features of an actual implementation may not be described in the specification. It should be appreciated that in the development of any such actual implementation, numerous implementation-specific decisions must be made to achieve the developers' specific goals, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
The term regarding spatial relationships such as “lower,” “below,” “under,” and “on,” “above,” etc., are used for convenience of description to describe the relationship of one element or feature to another element or feature in a figure. It should be understood that in addition to the orientation shown in the figure, the spatial relationship terms are intended to include different orientations during use and operation. In addition, when a layer is referred to as being “between” two layers, it may be the only layer between the two layers, or one of a plurality of layers between the two layers.
In the context of this application, when a first feature is “above” a second feature, the two features may be in direct or indirect contact with each other.
Herein embodiments of the present invention and intermediate structures are illustrated using schematic diagrams or cross-sectional diagrams. Thus, variations in shapes can be expected as manufacturing techniques and/or tolerances may vary. Thus, embodiments of the present invention should not be limited to the particular shapes of regions illustrated, but includes the shapes that result, for example, from manufacturing deviations. For example, an implanted region shown as a rectangle at its edges in a drawing can also have rounded or curved features and/or a gradient of implant concentration, rather than a binary change from implanted to non-implanted regions. Similarly, a buried region formed by implantation may result in the injection being present in the intermediate regions between the buried region and the surface. Thus, the shapes in the figure are illustrative in nature and are not intended to restrict the actual shape of the region and not intended to limit the scope of the invention.
at S3, the method may fabricate a first antenna layer on the second surface, with the first antenna layer electrically connected to the rewiring layer; at S4, the method may fabricate first metal feedline pillars on the first antenna layer, with the first metal feedline pillars electrically connected to the first antenna layer; at S5, the method may encapsulate the first metal feedline pillars with a first packaging layer, with top surfaces of the first metal feedline pillars exposed on the first packaging layer; at S6, the method may fabricate a second antenna layer on the first packaging layer, with the second antenna layer electrically connected to the first metal feedline pillars; at S7, the method may fabricate second metal feedline pillars on the second antenna layer, with the second metal feedline pillars electrically connected to the second antenna layer; at S8, the method may encapsulate the second feedline pillars with a second packaging layer, with top surfaces of the second feedline pillars exposed on the second packaging layer; at S9, the method may fabricate a third antenna layer on the second packaging layer, with the third antenna layer electrically connected to the second feedline pillars; at S10, the method may peel the temporary bonding layer off from the rewiring layer and the supporting substrate, to expose the first surface of the rewiring layer, form a first opening on the first surface in the rewiring layer, and fabricate one or more semiconductor chips on the first surface, with the one or more semiconductor chips electrically connected to the rewiring layer; at S11, the method may form a metal bump in the first opening, with the metal bump electrically connected to the rewiring layer; at S12, the method may encapsulate the one or more semiconductor chips and the meta bump using a third packaging layer, and form a second opening in the third packaging layer, with the metal bump exposed by the second opening.
Referring to
In some embodiments, the supporting substrate 101 may be a glass substrate, a metal substrate, a semiconductor substrate, a polymer substrate, or a ceramic substrate. In
In some embodiments, the temporary bonding layer 102 includes a light-to-heat conversion layer. As shown in
Operation step S2 in
In some embodiments, the rewiring layer is formed by the following process as illustrated by
As shown in
Next, as shown in
Next, referring to
Still referring to
In some embodiments, as shown in
As shown in
In some embodiments, as shown in
In some embodiments, the first protective adhesive layer 306 is made of polyimide. Since two adjacent layers of antenna structures in some embodiments are separated by one antenna layer, the adhesion strength between the two layers of antenna structures tends to decrease and cause displacement or breakage. Therefore, in some embodiments, a protective adhesive layer is formed between the two layers of antenna structures. The first protective adhesive layer 306 as illustrated in
As shown in
In some embodiments, before forming the first metal feedline pillars 303, a first lower metal layer 302 is formed on the surface of the first antenna layer 301, and the first metal feedline pillars 303 are formed on the first lower metal layer 302. On a surface of the first lower metal layer 302, in some embodiments, the first metal feedline pillars 303 are formed by a wire bonding process, an electroplating process, or an electroless plating process.
More specifically, in some embodiments, the first lower metal layer 302 includes a stacked layer composed of a Ni layer and an Au layer. In some embodiments, the first metal feedline pillars 303 are made of one or more of Au, Ag, Cu, Al. In some other embodiments, the first metal feedline pillars 303 are made of a material that is suitable for forming a metal pillar. In some embodiments, a wire bonding process is used to form the first metal feedline pillars 303 on the first lower metal layer 302. The first lower metal layer 302 strengthens the bonding strength of the first metal feedline pillars 303 and the first antenna layer 301, and reduces the contact resistance between first metal feedline pillars 303 and the first antenna layer 301. In some other embodiments, when the first protective adhesive layer 306 is present, the method for packaging antennas further includes forming an opening in the first protective adhesive layer 306 to expose one of the first metal feedline pillars 303.
In some embodiments, there are multiple first metal feedline pillars 303. In some embodiments, an electromagnetic shielding structure is also formed above the first metal feedline pillars 303 and the first antenna layer 301, to provide electromagnetic shielding for the package structure.
In some embodiments, the first metal feedline pillars 303 are formed a surface of the first antenna layer 301, and the first metal feedline pillars 303 are so distributed that the first metal feedline pillars 303 and one or more metal parts of the first antenna layer 301 form an electromagnetic shielding structure, to provide electromagnetic shielding for the package structure.
As shown in
Specifically, in some embodiments, the first metal feedline pillars 303 are encapsulated by a first packaging material layer 304, and the first packaging material layer 304 is thinned so that the top surfaces of the first metal feedline pillars 303 is exposed, and the thinned first packaging material layer 304 forms the first packaging layer 305. In some embodiments, the first metal feedline pillars 303 are encapsulated by the first packaging material layer 304 by one of compression molding, transfer molding, liquid-sealing molding, vacuum lamination, and spin coating. The first packaging layer 305 is made of one of silica gel and epoxy. As shown in
As shown in
In an embodiment, as shown in
In some embodiments, a top surface of the dielectric layer is even at the same plane as the top surface of the second antenna layer 307, a second packaging layer 311 is then formed on the top surfaces of the dielectric layer and the second antenna layer 307. The second antenna layer 307 and the first antenna layer 301 are electrically connected by the first metal feedline pillars 303. This a multi-layer antenna has better reception, higher receiver bandwidth, better electrical properties, antenna efficiency, shortened conduction paths between components, and lower power consumption.
In some embodiments, after forming the second antenna layer 307, the method for packaging antennas further includes forming a second protective adhesive layer covering the second antenna layer 307 on the first packaging layer 305, and the second metal feedline pillars 309 are formed on a surface of the second antenna layer 307 extending through the second protective adhesive layer. The second packaging layer 311 is subsequently formed on the second protective adhesive layer. In an embodiment, the second protective adhesion layer is made of polyimide. Since two adjacent layers of antenna structures in some embodiments are separated by one antenna layer, the adhesion quality between the two layers of antenna structures tends to degrade with time which causes displacement or breakage. Therefore, in some embodiments, a protective adhesive layer is formed between the two layers of antenna structures. The first protective adhesive layer 306 as illustrated in
In some embodiments, the packaging structure includes only one of the first protective adhesive layer 306 and the second protective adhesive layer. In some other embodiments, the packaging structure includes both the first protective adhesive layer and the second protective adhesive layer.
As shown
In some embodiments, before the second metal feedline pillars 309 are formed, a second lower metal layer 308 is formed on a surface of the second antenna layer 307, and then the second metal feedline pillars 309 are formed on the first antenna layer. On a surface of the second lower metal layer 308, in some embodiments, the second metal feedline pillars 309 are formed by a wire bonding process, an electroplating process, or an electroless plating process.
Specifically, the second lower metal layer 308 includes a stacked layer composed of a Ni layer and an Au layer. The second metal feedline pillars 309 are made of one of Au, Ag, Cu, and Al, In some other embodiments, the second metal feedline pillars are made of a material that is suitable for forming a metal pillar. In some embodiments, a wire bonding process is used to form the second metal feedline pillars 309 on the second lower metal layer 308.
The second lower metal layer 308 strengthens the bonding strength of the second metal feedline pillars 309 and the second antenna layer 307, and reduces the contact resistance between second metal feedline pillars 309 and the second antenna layer 307. In some other embodiments, when the second protective adhesive layer is present, the method for packaging antennas further includes forming an opening in the second protective adhesive layer to expose one of the second metal feedline pillars 309.
In some embodiments, there are multiple second metal feedline pillars 309. In some embodiments, an electromagnetic shielding structure is also formed above the second metal feedline pillars 309 and the second antenna layer 307, to provide electromagnetic shielding for the package structure.
As shown in
Specifically, in some embodiments, the second metal feedline pillars 309 are encapsulated by a second packaging material layer 310, and the second packaging material layer 310 is thinned so that the top surfaces of the second metal feedline pillars 309 is exposed, and the thinned second packaging material layer 310 forms the second packaging layer 311. In some embodiments, the second metal feedline pillars 309 are encapsulated by the second packaging material layer 310 by one of compression molding, transfer molding, liquid-sealing molding, vacuum lamination, and spin coating. The second packaging layer 311 is made of one of silica gel and epoxy. As shown in When the second protective adhesive layer is present, the second packaging layer 311 is formed on the second protective adhesive layer.
As shown in
As shown in
More specifically, in some embodiments, laser light is used to irradiate the light-to-heat conversion layer to separate the light-to-heat conversion layer from the rewiring layer and the supporting substrate 101. In addition, after separation, the first surface of the rewiring layer can be punched to form the first opening 501, which can be achieved by laser drilling technology. The first opening 501 reveals metal leads in the rewiring layer. The first opening 501 defines the position where a metal bumps is formed subsequently. In one embodiment, the first opening 501 is formed first, and then the semiconductor chips 401 are formed on the first surface of the rewiring layer in order to protect the semiconductor chips 401. In some embodiments, there is a gap between the first opening 501 and the semiconductor chips 401.
In some embodiments, the number of the semiconductor chips 401 is more than one, and the semiconductor chips are made of either active components or passive components. The active components can be one of a power management circuit, a transmitting circuit, and a receiving circuit. The passive components can be one of resistance, capacitance and inductance.
As shown in
Specifically, the metal bumps 502 are preliminarily fixed in the first openings 501. The metal bumps 502 may be made of one of tin solder, silver solder, and gold-tin alloy solder. The solder ball is preliminarily fixed on the rewiring layer through reflow soldering after ball mounting,
In addition, in an embodiment, the semiconductor chips 401 are under-filled before the metal bumps 502 is formed. Such an order helps to prevent the metal bumps 502 from interfering with siphoning of the under-filling process. The material used for the under-filling may be epoxy. The under-filling is achieved with the help of the siphon effect. Filler used in the under-filling is siphoned into the gap between the semiconductor chips 401 and the rewiring layer. The metal bumps 502 could also cause the siphon effect, which is the reason the metal bumps 502 is formed after the under-filling in some embodiments.
In some embodiments, after the under-fill layer 402 is formed, a dam & fill protective layer 403, as shown in
More specially, the dam & fill protective layer 403 is formed after the semiconductor chips 401 are attached to the first surface; the dam & fill protective layer 403 is formed by first forming a dam around the semiconductor chips 401 using glue, and then dispensing glue in the area surrounded by the dam. In some embodiments, the dam & fill protective layer 403 increases the stability of the semiconductor chips 401, and offers more protection for the semiconductor chips 401. In some embodiments, the dam & fill protective layer 403 is formed after the under-filing process, and the dam & fill protective layer 403 together with the under-fill layer envelops the semiconductor chips 401. In some embodiments, the dam & fill protective layer 403 is made of an epoxy.
As shown in step S12 in
Specifically, the third packaging layer 503 is formed by compression molding, transfer molding, liquid sealing molding, vacuum lamination, or spin coating. The third packaging layer 503 is made of one of silica gel and epoxy materials. In addition, in some embodiments, a laser is used to drill in the third packaging layer 503 to form the second opening 504. The second opening 504 exposes the metal bumps 502. In some embodiments, as shown in
Additionally, when there is a dam & fill protective layer 403, the third packaging layer also encapsulates the dam & fill protective layer 403, which increases the device's stability in some embodiments.
As discussed above, a method for packaging antennas is disclosed herein. The present disclosure further provides an antenna packaging structure corresponding to the method, as shown in
In some embodiments, as shown in
The rewiring layer includes a first surface and a second surface opposite to the first surface. The rewiring layer also includes a first opening 501 formed on the first surface. The first antenna layer 301 is formed on the second surface and electrically connected to the rewiring layer. The first metal feedline pillars 303 are formed on the first antenna layer 301 and electrically connected to the first antenna layer 301. The first packaging layer 305 covers the first metal feedline pillars 303, and the top surfaces of the first metal feedline pillars 303 are exposed. That is, the first metal feedline pillars 303 penetrate the first packaging layer 305.
The second antenna layer 307 is formed on the first packaging layer 305 and electrically connected to the first metal feedline pillars 303. The second metal feedline pillars 309 are formed on the second antenna layer and electrically connected to the second antenna layer 307. The second packaging layer 311 covers the second metal feedline pillars 303 with top surfaces of the second metal feedline pillars 303 exposed. The third antenna layer 312 is formed on the second packaging layer 311 and electrically connected to the second metal feedline pillars 309. The semiconductor chips 401 are connected to the first surface and electrically connected to the rewiring layer. The metal bumps 502 is formed in the first opening 501 and electrically connected to the rewiring layer. The third packaging layer 503 encapsulates the semiconductor chips 401 and the metal bumps 502, and the third packaging layer 503 includes a second opening 504 exposing the metal bumps 502.
Specifically, in some embodiments, the rewiring layer includes a first dielectric layer 201, a first metal wiring layer 202, a second dielectric layer 203, a conductive plug, and a second metal wiring layer 204. In some embodiments, the rewiring layer has a multi-layer stack structure comprising multiple metal layers and multiple dielectric layers to achieve different wiring functions. In some embodiments, the first dielectric layer 201 and the second dielectric layer 203 are made of one or more of epoxy, silica gel, PI (polyimide), PBO, BCB, silicon oxide, phosphosilicate glass, and fluorine-containing glass. In some embodiments, the first dielectric layer 201 and the second dielectric layer 203 are made of PI (polyimide), which facilitates the process and reduces manufacturing cost.
In some embodiments, the first metal wiring layer 202 and the second metal wiring layer 204 are made of one or more of copper, aluminum, nickel, gold, silver, and titanium.
In some embodiments, the first lower metal layer 302 is formed in a connection area between the first metal feedline pillars 303 and the first antenna layer 301. In one embodiment, the first metal feedline pillars 303 are made of one of gold, silver, copper, and, aluminum. In another embodiment, the first metal feedline pillars 303 are made of a material that is suitable for forming a metal pillar. In some embodiments, the first lower metal layer 302 includes a stacked layer composed of a Ni layer and an Au layer. The first lower metal layer 302 strengthens the bonding strength of the first metal feedline pillars 303 and the first antenna layer 301, and reduces the contact resistance between first metal feedline pillars 303 and the first antenna layer 301.
In some embodiments, the second lower metal layer 308 is formed in a connection area between the second metal feedline pillars 309 and the second antenna layer 307. In one embodiment, the second metal feedline pillars 309 are made of one of gold, silver, copper, and, aluminum. In another embodiment, the second metal feedline pillars 309 are made of a material that is suitable for forming a metal pillar. In some embodiments, the second lower metal layer 308 includes a stacked layer composed of a Ni layer and an Au layer. The second lower metal layer 308 strengthens the bonding strength of the second metal feedline pillars 309 and the second antenna layer 307, and reduces the contact resistance between the second metal feedline pillars 309 and the second antenna layer 307.
Specifically, in some embodiments, the first antenna layer 301 is made of copper. In some embodiments, the second antenna layer 307 is made of copper. In some embodiments, the third antenna layer 312 is made of materials including copper.
The second antenna layer 307 and the first antenna layer 301 are electrically connected through the first metal feedline pillars 303, and the third antenna layer 312 and the second antenna layer 307 are electrically connected through the second metal feedline pillars 309. In some embodiments, such a multi-layer antenna leads to better reception, higher receiver bandwidth, better electrical properties and antenna efficiency, shortened conduction paths between components, and lower power consumption.
In some embodiments, the antenna packaging structure also includes a first protective adhesive layer 306 covering the first antenna layer 301 on the rewiring layer. The first metal feedline pillars 303 are formed on a surface of the first antenna layer 301 and extend through the first protective adhesive layer 306. The first packaging layer 305 is formed on the first protective adhesive layer 306.
In some embodiments, a second protective adhesive layer (not illustrated in
Referring to
In some embodiments, the first protective adhesive layer 306 is made of polyimide. Since two adjacent layers of antenna structures in some embodiments are separated by one antenna layer, the adhesion strength between the two layers of antenna structures tends to decrease and cause displacement or breakage. Therefore, in some embodiments, a protective adhesive layer is formed between the two layers of antenna structures. The first protective adhesive layer 306 as illustrated in
The first packaging layer 305 is made of one of silica gel and epoxy. As shown in
In some embodiments, the number of the semiconductor chips 401 is more than one, and the semiconductor chips are made of either active components or passive components. The active components can be one of a power management circuit, a transmitting circuit, and a receiving circuit. The passive components can be one of resistance, capacitance and inductance. In some embodiments, all passive components and active components are encapsulated in one packaging unit. In some embodiments, both passive components and active components are placed on one wafer.
In some embodiments, there are multiple first metal feedline pillars 303. In some embodiments, an electromagnetic shielding structure is formed by the first metal feedline pillars 303 and the first antenna layer 301.
Specifically, in some embodiments, the first metal feedline pillars 303 are formed a surface of the first antenna layer 301, and the first metal feedline pillars 303 are so distributed that the first metal feedline pillars 303 and one or more metal parts of the first antenna layer 301 form an electromagnetic shielding structure, to provide electromagnetic shielding for the package structure.
In some embodiments, there are multiple second metal feedline pillars 309. In some embodiments, an electromagnetic shielding structure is also formed by the second metal feedline pillars 309 and the second antenna layer 307.
In some embodiments, the antenna packaging structure also includes an under-fill layer 402, which is formed between the semiconductor chips 401 and the rewiring layer.
In some embodiments, the under-fill layer 402 is made of materials including epoxy.
In some embodiments, the antenna packaging structure also includes a dam & fill protective layer 403, and the under-fill layer 402 together with the dam & fill protective layer 403 envelops the semiconductor chips 401.
In some embodiments, the dam & fill protective layer 403 is made of materials including epoxy.
Specifically, in
In some embodiments, the antenna packaging structure also includes an under-fill layer 402. The under-fill layer 402 helps with improving the packaging stability of the semiconductor chips 401. In some embodiments, the antenna packaging structure also includes a dam & fill protective layer 403. The dam & fill protective layer 403 helps with improving the stability of the semiconductor chips 401, and offers protection for the semiconductor chips 401. The dam & fill protective layer 403 and the under-fill layer 402 surround the semiconductor chips 401, offering a hermetical seal to protect the semiconductor chips 401. In some embodiments, the under-fill layer 402 is made of epoxy. In some embodiments, the dam & fill protective layer 403 is made of epoxy.
In addition, in some embodiments, the third packaging layer 503 is made of one of silica gel and epoxy. The third packaging layer 503 helps to further stabilize the metal bumps 502. In some embodiments, the metal bumps 502 is fixed to the third packaging layer 503 by molding. In some embodiments, laser technology is used to laser drill in the third packaging layer 503 to form the second opening 504. The second opening 504 exposes the metal bumps 502. In some embodiments, as shown in
Additionally, when there is a dam & fill protective layer 403, the third packaging layer also encapsulates the dam & fill protective layer 403, which increases the device's stability in some embodiments.
Compared to the existing technologies, simultaneous packaging of the semiconductor chips and the metal bumps is able to improve the stability of the packaging structure. Also, adopting the multi-layered antenna structure which comprises multiple layers of metal feedline pillars and multiple packaging layers can reduce the device's package size, which leads to better reception and higher receiver bandwidth. In addition, the under-fill layer serves to improve the stability of the semiconductor chips. The under-filling process is performed before the metal bumps are formed, which helps to reduce the metal bumps' interference to the under-filling process. The dam & fill protective layer adds an extra protection to the semiconductor chips. Aligning the semiconductor chips, the rewiring layer stack, and metal antennas elements in a vertical structure shortens the conduction path between various components, and leads to better electrical properties, higher antenna efficiency, and lower power consumption.
While particular elements, embodiments, and applications of the present invention have been shown and described, it is understood that the invention is not limited thereto because modifications may be made by those skilled in the art, particularly in light of the foregoing teaching. It is therefore contemplated by the appended claims to cover such modifications and incorporate those features which come within the spirit and scope of the invention.
List of Reference Numerals in the Disclosure:
101 supporting substrate
102 temporary bonding layer
201 first dielectric layer
202 first metal wiring layer
203 second dielectric layer
204 second metal wiring layer
301 first antenna layer
302 first lower metal layer
303 first metal feedline pillars
304 first packaging material layer
305 first packaging layer
306 first protective adhesive layer
307 second antenna layer
308 second lower metal layer
309 second metal feedline pillars
310 second packaging material layer
311 second packaging layer
312 third antenna layer
401 semiconductor chip
402 under-fill layer
403 dam & fill protective layer
501 first opening
502 metal bump
503 third packaging layer
504 second opening
S1-S15 processe steps of an antenna packaging method
Number | Date | Country | Kind |
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201911021293.0 | Oct 2019 | CN | national |
201921804349.5 | Oct 2019 | CN | national |
Number | Name | Date | Kind |
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6552555 | Nuytkens | Apr 2003 | B1 |
20190163939 | Yamamoto | May 2019 | A1 |
Number | Date | Country | |
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20210391637 A1 | Dec 2021 | US |