N-shot antenna assembly and related manufacturing method

An antenna module and a manufacturing method for the same are disclosed. With the miniaturization trend for mobile communication terminals, the invention can achieve the miniaturization of antenna modules and facilitate the design of the antenna. The SMD as a matching component for given resonance frequency and impedance matching of the antenna is mounted on the antenna module to make the antenna module compact, and functions as a matching circuit for impedance matching to facilitate the design of mobile devices.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to wireless communications; and more particularly to an antenna for installation within a wireless communications device, and a manufacturing method of the same.

2. Description of the Related Art

In recent years, the field of wireless communications, including information technology (IT), has improved with the advent of the full-fledged information age, and there have been introduced various mobile devices such as cellular phones, digital cellular system (DCS), personal communication service (PCS), wideband code division multiple access (WCDMA), 4G long term evolution (LTE) phone, personal digital assistant (PDA) terminals, global positioning systems (GPS), smart phones, and notebook computers, among others, to provide a variety of services to users through wireless data communication.

An antenna such as helical antenna or dipole antenna is typically mounted on these mobile devices so as to enhance transmission intensity and receive sensitivity. These antennas, as an external antenna, are protruded to the outside of wireless communication terminals.

While the external antenna has useful radiation characteristics, being external to the mobile device presents problems such as breakage during normal use, de-tuning of the antenna due to direct contact with the user, and a negative impact on appearance and aesthetics.

As solutions to the abovementioned drawbacks, a flat internal antenna, such as a micro strip patch antenna or inverted F-type antenna, has been mounted within the terminal without protrusion to the outside thereof.

In general, the conventional internal antenna comprises a body molded with an insulator such as polycarbonate and a conductive pattern formed using a metal plate or etched conductive pattern on a flex circuit, for example, wherein the conductive pattern includes a circuit pattern capable of wireless transmission and reception in a specific frequency band and is coupled with the surface of the body.

To manufacture the internal antenna, there have been provided metal stamping method for punching a desired pattern into a metal piece and fusing the metal piece onto the molded body by heat, an etching method for plating the entire mold and eliminating the rest of mold except for the pattern; and a printing direct structuring (PDS) method for plating after directly printing the molded body with conductive ink.

The internal antenna is designed to transmit and receive the signal of a predetermined frequency band. In other words, the antenna may radiate the signal by resonance at a fixed frequency band.

In general, electrical characteristics of an antenna, such as radiation pattern, gain, bandwidth, frequency, polarization, and impedance, can be configured by varying the antenna design. For example, impedance of the antenna can be configured by providing a matching component such as a capacitor or an inductor. In conventional antennas, since matching components and antenna characteristic values are fixed, there is a problem that the new tuning of an internal antenna is required when the characteristic of antenna needs to be changed in the design process.

In other words, to obtain desired electric characteristics of the antenna, the conventional internal antenna requires a change in the design structure of the antenna through tuning according to the conditions of various systems, or to change the conditions of the system according to the characteristics of antenna. These limitations introduce added costs in the development process as well as difficulties in management of the product due to the development of various products.

To solve these problems, commonly owned Korean Patent Registration No. 10-0756312, entitled “RESONANCE FREQUENCY AND INPUT IMPEDANCE CONTROLLABLE MULTIPLEX BUILT-IN ANTENNA” discloses a built-in internal antenna, wherein the built-in antenna has one feeding point, two shorting points, and an inductor therebetween so as to control resonance frequency and input impedance.

In the above patent, however, there is a difficulty in process to install the inductor between the shorting point and the ground plane and it is difficult to install the built-in antenna with a PCB. Moreover, since only the inductor value is controlled from the outside of the built-in antenna, other electric characteristics of the built-in antenna are fixed.

SUMMARY OF THE INVENTION

In one aspect of the invention, a manufacturing method is provided for the fabrication of internal antennas in accordance with various embodiments of the invention.

In one embodiment, the manufacturing method comprises: molding a carrier to have one or more negative patterns, or “voids”, disposed along an outer surface thereof, the carrier being formed from a non-conductive and plating-resistive material, the voids essentially comprising a cavity extending along a conductor pattern which will ultimately become the conductive portions of the antenna; filling the voids of the carrier with a plating-friendly material; forming a plating resist for resisting a subsequent conductive plating to form a discontinuous part separating portions of the conductor pattern; plating a conductive material on the plating-friendly material to form one or more conductive portions along the conductor pattern of the carrier; and attaching a surface mounted device (SMD) such that terminal ends of the SMD are connected with the conductive portions adjacent to the discontinuous part of the conductor pattern. This method can be referred to herein as a dual-shot antenna forming technique since the method requires first molding a plating-resistive carrier having voids in the pattern of desired conductive portions, and second injecting a plating-friendly material within the voids of the carrier prior to plating the carrier.

In various embodiments, the method may comprise forming two or more plating resists for forming two or more discontinuous parts in the conductor pattern; and attaching multiple SMD's wherein one or more SMD's are disposed in a manner for connecting adjacent conductive portions separated by each discontinuous part of the conductor pattern. Moreover, one or more SMD components may be connected to radiating portions of the antenna.

In another embodiment, a dual-shot antenna forming technique as described above is used to form a first layer of a three-dimensional antenna structure; a second layer of the three-dimensional antenna structure is independently formed; and the first and second layers are combined to form a multi-layer antenna assembly.

In certain embodiments, the first layer of the three-dimensional antenna structure comprises a first dielectric material having at least a first dielectric constant associated therewith, and the second layer comprises a second dielectric material having at least a second dielectric constant, wherein the second dielectric constant is different from the first dielectric constant such that the multi-layer antenna comprises a dielectric gradient.

In another embodiment, the manufacturing method further comprises coupling at least one active element to a conductive portion of the antenna for actively tuning the conductive portion.

In another aspect of the invention, an antenna assembly is provided in accordance with the manufacturing methods of the invention. The antenna assembly comprises one or multiple layers, wherein at least one of the multiple layers comprises a carrier volume having one or more voids extending along a conductor pattern, a filler volume disposed within the voids, a conductive material overlaying at least one surface of the filler volume forming a conductor pattern, and at least one SMD attached to the conductor pattern. The carrier volume consists essentially of a non-conductive and plating-resistive material, and the filler volume consists essentially of a non-conductive and plating-friendly material.

Various other features and embodiments of the invention are further described within the following detailed description of the preferred embodiments.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Various features and advantages of this invention will become apparent from the following description of embodiments with reference to the accompanying drawings. Hereinafter, a preferred embodiment of the present invention will be described in more detail referring to the drawings and reference numerals associated thereof.

Accordingly, with the miniaturization trend for mobile communication terminals, the invention can achieve the miniaturization of antenna modules and facilitate the design of the antenna. The surface mounted device (SMD) as a matching component for given resonance frequency and impedance matching of the antenna is mounted on the antenna module to make the antenna module compact, and functions as a matching circuit for impedance matching to facilitate the design of mobile devices.

Additionally, in the application of a passive matching circuit, PCB manufacturers can manufacture the PCB regardless of input impedances of antennas. In a design process, it may occur that the antenna has to be retuned for some reason. In this situation, antenna characteristics may be changed with the SMD as a matching component of the antenna. The SMD is configured by the combination of inductors (L) and capacitors (C), and adjusts capacitive and inductive properties to remove the necessity for special antenna tuning even when the design of the PCB is changed. The SMD may comprise one or more capacitors, inductors, resistors, diodes, active components, or switches

Further, active components can be installed on the conductive pattern of the antenna assembly to provide an integrated solution for an active tunable antenna. A flex circuit can be attached to the antenna assembly to bring voltage supply and control signals to the active component. Alternately, conductive patterns can be positioned on the side wall of the antenna assembly to provide a connection with the PCB of the host device to provide supply voltage and control signals to the active component.

For purposes of this invention, the SMDs used in the antenna may include any passive component, such as a capacitor or inductor, or any active component, such as a tunable phase shifter, veractor or vericap diode, tunable capacitor, switch, or other similar active component. In the embodiments including active components, a control signal will be required and thus may be provided by way of a flex-circuit with voltage control, or using baseband signaling.

Further, in the application of an active matching circuit, operations at a desired frequency level can be implemented by positioning the SMD on a specific antenna radiation pattern. The SMD may include one or more inductors and/or capacitors, and may further be configured to adjust the amount of inductors and capacitors so as to acquire optimum signal sensitivity for desired band characteristics.

Further, the size and shape of the antenna may be constantly maintained irrespective of the ambient conditions and location where the antenna is installed, and all electrical characteristics including antenna impedance as well as desired frequencies and operation band may be controlled by using the component of the SMD having various capacitance and inductance values.

Still further, in certain embodiments an antenna radiation pattern is formed by plating, and more specifically, it can be simply formed through dual shot molding and electroless plating, although generally any plating technique can be used with minor adjustment to the process.

For purposes of this invention, the terms antenna module, antenna assembly, and antenna are intended to be interchangeably applicable throughout the description. More particularly, in several embodiments an antenna may comprise a modular molded and plated structure in the form of an antenna module, or may be a multi-layered module combined as an assembly of multiple parts.

Now turning to the examples as illustrated in the appended drawings, certain antennas and methods are demonstrated to enable those having skill in the art to make and use the invention. Certain deviations from the provided examples are expected, and may be practiced without undue experimentation when exercised by those having ordinary skill in the art, thus the claimed invention is not intended to be limited by the scope of the following illustrative examples.

Built-in Antenna Assembly

FIGS. 1-3illustrate an antenna assembly according to various embodiments of the invention.FIG. 1is a perspective view illustrating an antenna module for mounting on a printed circuit board (PCB) of mobile wireless device according to various embodiments of the invention.FIG. 2is a top plan view showing an antenna module according to the embodiment ofFIG. 1.FIG. 3is a sectional view taken along the line A-A′ inFIG. 2.

Referring now toFIGS. 1 to 3, an antenna module100is adapted for installation on a Printed circuit board (PCB) of mobile wireless device.

The antenna module100comprises a carrier110which is made of non-conductive and plating-resistive resin material. The carrier further comprises one or more voids extending along a negative conductor pattern on an outer surface of the carrier. The voids of the carrier further comprise a filler material120spanning a volume thereof, the filler material120being plating-friendly. One or more plating resists130are disposed on an exposed surface of the filler material and adapted to resist plating and form a discontinuous part of the conductor pattern. A conductive material is plated on the remaining exposed surface of the filler material120and extends along the filler material surface to form the conductive pattern125. The conductive pattern125may have various shapes according to various designs.

Since plating resists130are formed between lines of the conductive pattern125, a discontinuous part of the conductive pattern lines exists.

Preferably, the conductive pattern125has a three dimensional shape where a curved part is formed in the outer portion thereof, and has at least one connecting pin160downwardly bent and extended from one side of the conductive pattern. When assuming that the conductive pattern125has two connecting pins160as shown inFIG. 1, one of the connecting pins160functions as a feeding pin161being connected to an RF connector of the PCB10and the other one functions as a ground pin162being grounded by the medium of the PCB. When the antenna module100with the conductive pattern125is mounted on the PCB, the feeding and ground pins161,162are respectively in contact with feeding and ground lines11,12on the PCB.

An antenna contact device may be interposed between the antenna module100and the PCB. In other words, the antenna contact device is formed in a “C” shape to have elasticity, a flat lower part is fixed to the feeding and ground lines11,12of the PCB10, and an upper bent part is elastically in contact with the connecting pin160of the antenna module100.

At least one surface mounted device (SMD,150) capable of electrically connecting a discontinuous part and adjusting electrical characteristics is interposed between the lines of the antenna conductive pattern125. The SMD150is mounted to connect the conductive patterns125on both sides of the plating resists130at the discontinuous part of the antenna conductive pattern125.

In certain embodiments, a solder mask140having open areas141can be formed in a portion where the SMD150is mounted.

An input/output terminal unit of the SMD150is electrically connected with the conductive pattern125through a solder bump170in the open area141of the solder mask where the conductive pattern125is exposed, thereby giving electrical continuity to the conductive pattern125as well as controlling electrical characteristics of the antenna.

The SMD150mounted in the antenna module according to the present invention functions as follows:

First, depending on the miniaturization of mobile communication terminals, it may achieve miniaturization of the antenna module and facilitate the design thereof. The SMD as a matching component for given resonance frequency and impedance matching of the antenna is mounted on the antenna module to make the antenna module compact, and functions as a matching circuit for impedance matching to facilitate designs.

Second, in the application of a passive matching circuit, it enables PCB manufacturers to manufacture the PCB regardless of input impedances of antennas. In a design process, it can occur that the antenna has to be retuned for some reason. In this situation, antenna characteristics may be changed with the SMD as a matching component of the antenna. The SMD is configured by the combination of inductors (L) and capacitors (C), and adjusts inductive and capacitive values to remove the necessity for special antenna tuning even when the design of the PCB is changed.

Third, in the application of an active matching circuit, operations at a desired frequency level can be possible by positioning the SMD on a specific antenna conductive pattern. The SMD may include an inductor or capacitor and is adapted to adjust the amount of reactance so as to acquire optimum receive sensitivity for desired band characteristics.

Dual-Shot Manufacturing Method

Hereinafter, there will be described a manufacturing method for an antenna module according to one embodiment of the present invention.

FIGS. 4 to 8illustrate manufacturing methods for an antenna module according the various embodiments of the present invention.

Referring toFIG. 4, a carrier110is formed with non-conductive and plating-resistive resin material by injection molding in a mold, or a similar technique. In the outer surface of the carrier110, a negative pattern, or void pattern, is formed. The void pattern may be formed by providing ridges in the mold used to mold the carrier, or by stamping, laser etching or similar techniques. For the plating-resistive resin material, polycarbonate (PC), polyamide (nylon), and other similar plating-resistive materials may be used. Then, plating-friendly resin material, or a filler material, is injected into the void pattern formed on the outer surface of the carrier110. In this regard, the void pattern is injected or otherwise filled with a filler material120in preparation for plating a conductive material thereon to form a conductive pattern. In general, for the plating-friendly resin material, acrylonitrile-butadiene-styrene (ABS) resin material may be used.

Referring toFIG. 5, on the pattern of filler material120at the portion where the SMD is mounted, plating resists130are deposited for preventing conductive plating and forming a discontinuous part in the pattern. The plating resists130can include a film for preventing the plating at a coated portion, and may function as a screen. For the plating resists, dry film type photosensitive polymer resists may be used.

Referring toFIG. 6, through a step of plating conductive material onto the exposed filler material120by dipping that into a vessel containing solution of conductive material and draining that, an antenna conductive pattern125is formed. At this point, since there is no plating on the plating resists130, the conductive pattern125may have a discontinuous part. Then, the discontinuous part is electrically connected by the SMD. The plating can be electroless plating, and for example, may form copper (Cu), nickel (Ni), and gold (Au) sequentially. The electroless plating is a method for plating metal onto the exposed plating-friendly filler material120by autocatalytically reducing metal ions within aqueous solution of metal salt by the force of reducing agents without the supply of electric energy from the outside.

Referring toFIG. 7, a solder mask140having an open area141is formed. The open areas141are portions where conductive patterns125adjacent to the plating resists130and the discontinuous part are exposed, and also a portion where a terminal unit of the SMD is coupled by the solder bump. In a lower part of the solder mask140between the open areas141, the plating resists130and the discontinuous part is disposed.

Referring toFIG. 8, on the open areas141where the conductive patterns125are exposed, the solder bump (not shown) and input/output terminals of the SMD150are aligned, and then the procedure advances to a reflow process at a temperature where the solder bump can be melt in order to connect the SMD150with the conductive pattern125through the solder bump. In order words, by mounting the SMD150, the discontinuous part of the conductive pattern125is continuously connected through the terminal unit of the SMD150.

Other Examples

In another embodiment as illustrated inFIG. 9, one or more SMD components150can be mounted at locations on radiating portions of the antenna element to provide the capability to reactively load portions of the radiating structure or to connect or disconnect portions of the radiator. In this regard, the SMD components150can be mounted as described above, i.e. by attaching plating resists and forming a discontinuous part in the conductive pattern and using a soldering technique to attach the SMD components to adjacent portions of the conductive pattern at the discontinuous part.

The SMDs150can be individually selected from passive and active components as described above, depending on the design requirements for the antenna.

In another embodiment as illustrated inFIG. 10, the manufacturing method can be expanded to include an “n” shot concept, wherein multiple plastic layers are metalized and stacked to provide multiple conductive patterns displayed in several layers across three dimensions. This will provide an antenna assembly which more optimally utilizes the volume allocated for the antenna. Moreover, in addition to driven conductive patterns, one or more parasitic conductor patterns may be disposed within one or more layers of the multi-layer stacked antenna.

Generally, at least a first layer500of a multi-layer antenna comprises an antenna carrier manufactured by the above “Dual Shot Manufacturing Method”. A second layer550is independently fabricated using the dual-shot technique, or other technique. The first and second layers are then combined, for example by nesting the first layer with the second layer, to form a three-dimensional multi-layer antenna assembly.

In another embodiment as depicted inFIG. 11, an antenna assembly is fabricated wherein multiple layers are stacked and metalized to provide multiple conductive patterns displayed in three dimensions. A first of the multiple layers comprises a first material having a first dielectric constant D1and a second layer comprises a second material having a second dielectric constant D2, wherein the second dielectric constant is different than the first dielectric constant. In this regard, up to each layer of the multiple layers of the antenna may comprise a unique dielectric constant, thereby forming a dielectric gradient. Varying the dielectric constant of the multiple layers provides another parameter for optimizing the antenna assembly.

In another embodiment, a conductive portion of the second layer of the multi layer antenna assembly can be connected to at least one conductive portion of a first layer of the multi-layered antenna assembly. The connection can be made using conductive plating or can be made by inserting a conductive element such as a wire, post, or strap.

In another embodiment, a flexible circuit (flex circuit) comprising one or more conductive traces can be attached to the antenna assembly for providing one or more of: voltage, current, and control signals to components attached to the antenna assembly.

In another embodiment as illustrated byFIG. 12, an antenna assembly is provided wherein at least one active component is attached conductive patterns on the antenna. A flex circuit750is connected to conductive patterns of the antenna assembly and is used to provide supply voltage and/or control signals to the active component.

One having skill in the art would recognize various methods for connecting a flex-circuit to the one or more SMD components, either by providing a conductive pattern that is suitable for attaching to a flex-circuit, or using a wire connection, etc.

In another embodiment as illustrated byFIG. 13, the antenna may comprise a combination of a laser directed structured (LDS) assembly950and a dual-shot assembly900(as described above), wherein the LDS assembly is first configured and the dual-shot assembly is positioned on top of the LDS assembly. The dual-shot assembly has one or multiple components attached to conductive features.

In yet another embodiment as depicted byFIG. 14, the antenna may comprise a combination of a laser directed structured (LDS) assembly950and a dual-shot assembly900(as described above), wherein the dual-shot assembly is first configured and the LDS assembly is positioned on top of the dual-shot assembly. The dual-shot assembly has one or multiple components attached to conductive features.

Then, not shown in drawings, to improve adhesive reliability of the solder bump and the radiation pattern, underfill materials (for example, epoxy based adhesive materials filled with SiO2) are dispensed, and curing is performed to harden the underfill materials with heat. By the above mentioned processes, an antenna module is formed. Further, a coating layer may be formed on the carrier where the conductive pattern is formed.