Various embodiments related to a compact device package are disclosed herein. In some arrangements, a flexible substrate can be coupled to a carrier having walls angled relative to one another. The substrate can be shaped to include two bends. first and second integrated device dies can be mounted on opposite sides of the substrate between the two bends in various arrangements.
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18. An integrated device package comprising:
a carrier having at least two walls angled relative to one another;
a substrate having at least one bend and coupled to the carrier, the substrate including a first segment that defines at least part of an exterior surface of the integrated device package;
a first integrated device die mounted to the substrate; and
a first interfacing feature formed on the first segment of the substrate.
1. An integrated device package comprising:
a carrier having at least two walls angled relative to one another;
a substrate coupled to the carrier, the substrate having a first bend and a second bend;
a first integrated device die mounted to a first side of the substrate between the first bend and the second bend; and
a second integrated device die mounted to a second side of the substrate between the first bend and the second bend, the second side opposite the first side.
28. An integrated device package comprising:
a carrier having at least two walls angled relative to one another, the at least two walls defining a package housing;
a substrate coupled to the carrier, the substrate having at least one bend within the housing, the bend separating first and second segments;
a first integrated device die mounted to a first side of the first segment of the substrate; and
a second integrated device die mounted to a second side of the first segment of the substrate, the first side opposite the second side.
22. An integrated device package comprising:
a carrier;
a substrate having at least one bend and coupled to the carrier, the substrate including a first segment that defines at least part of an exterior surface of the integrated device package;
a first integrated device die mounted to the substrate; and
a first interfacing feature formed on the first segment of the substrate,
wherein the first interfacing feature is a sensor or a wireless communications component,
wherein the substrate further comprises a plurality of contact pads configured to electrically couple to an external motherboard.
24. An integrated device package comprising:
a carrier;
a substrate having at least one bend and coupled to the carrier, the substrate including a first segment that defines at least part of an exterior surface of the integrated device package;
a first integrated device die mounted to the substrate; and
a first interfacing feature formed on the first segment of the substrate,
wherein the first interfacing feature is a sensor or a wireless communications component,
wherein the substrate comprises a second segment that defines at least part of the exterior surface of the integrated device package, the integrated device package further comprising a second interfacing feature formed on the second segment of the substrate.
32. A method for manufacturing an integrated device package, the method comprising:
providing a carrier having at least two walls angled relative to one another;
mounting a first integrated device die to a first side of a substrate;
mounting a second integrated device die to a second side of the substrate, the second side opposite the first side,
bending the substrate in a first direction to form a first bend;
bending the substrate in a second direction to form a second bend, the second direction opposite the first direction; and
coupling a segment of the substrate to a first wall of the carrier,
wherein the first integrated device die and the second integrated device die are mounted between the first bend and the second bend.
2. The integrated device package of
3. The integrated device package of
4. The integrated device package of
5. The integrated device package of
6. The integrated device package of
7. The integrated device package of
8. The integrated device package of
9. The integrated device package of
a fourth segment extending from the first segment and folded over a first wall of the carrier, the fourth segment coupled to the first wall; and
a first interfacing feature formed on an exterior surface of the fourth segment.
10. The integrated device package of
11. The integrated device package of
12. The integrated device package of
13. The integrated device package of
a fifth segment extending from the first segment and folded over a second wall of the carrier, the fifth segment coupled to the second wall; and
a second interfacing feature formed on an exterior surface of the fifth segment.
14. The integrated device package of
15. The integrated device package of
a fifth integrated device die mounted to the third segment of the substrate; and
a sixth integrated device die mounted to the third segment of the substrate.
16. The integrated device package of
a sixth segment extending from the third segment of the substrate, the sixth segment bent relative to the third segment of the substrate; and
a plurality of contact pads formed on an exterior surface of the sixth segment, the contact pads configured to electrically couple to an external motherboard.
17. The integrated device package of
19. The integrated device package of
20. The integrated device package of
21. The integrated device package of
23. The integrated device package of
25. The integrated device package of
26. The integrated device package of
27. The integrated device package of
29. The integrated device package of
30. The integrated device package of
31. The integrated device package of
33. The method of
34. The method of
35. The method of
36. The integrated device package of
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1. Field
The field relates to apparatus and methods for packaging, and in particular, to apparatus and methods for forming compact packages.
2. Description of the Related Art
Electronic devices are often manufactured to include numerous components designed to perform multiple functions. For example, advanced sensor devices can include multiple sensors that measure many different types of properties, and multiple processors programmed to process information detected by the sensors. In conventional packages that include multiple components, various device dies may be stacked on a package substrate to reduce the footprint of the package. In other conventional arrangements, through silicon vias (TSVs) may be used to provide a higher level of vertical integration. While these advanced sensor devices are manufactured to incorporate multiple sensors and/or processors, there is a continuing need to integrate the advanced sensor devices within a compact, low profile package.
In one embodiment, an integrated device package is disclosed. The integrated device package can include a carrier having at least two walls angled relative to one another. A substrate can be coupled to the carrier. In some arrangements, the substrate can have a first bend and a second bend. A first integrated device die can be mounted to a first side of the substrate between the first bend and the second bend. A second integrated device die can be mounted to a second side of the substrate between the first bend and the second bend, the second side opposite the first side.
In another embodiment, an integrated device package is disclosed. The integrated device package can comprise a carrier. The integrated device package can also include a substrate having at least one bend and coupled to the carrier. The substrate can include a first segment that defines at least part of an exterior surface of the integrated device package. A first integrated device die can be mounted to the substrate. A first interfacing feature can be formed on the first segment of the substrate.
In another embodiment, an integrated device package is disclosed. The integrated device package can comprise a carrier having at least two walls angled relative to one another. The at least two walls can define a package housing. A substrate can be coupled to the carrier. The substrate can have at least one bend within the housing, the bend separating first and second segments. A first integrated device die can be mounted to a first side of the first segment of the substrate. A second integrated device die can be mounted to a second side of the first segment of the substrate, the first side opposite the second side.
In yet another embodiment, a method for manufacturing an integrated device package is disclosed. The method can comprise providing a carrier having at least two walls angled relative to one another. A first integrated device die can be mounted to a first side of a substrate. A second integrated device die can be mounted to a second side of the substrate, the second side opposite the first side. The method can include bending the substrate in a first direction to form a first bend, and bending the substrate in a second direction to form a second bend, the second direction opposite the first direction. Further, the method can comprise coupling a segment of the substrate to a first wall of the carrier. The first integrated device die and the second integrated device die can be mounted between the first bend and the second bend.
For purposes of summarizing the invention and the advantages achieved over the prior art, certain objects and advantages of the invention have been described herein above. Of course, it is to be understood that not necessarily all such objects or advantages may be achieved in accordance with any particular embodiment of the invention. Thus, for example, those skilled in the art will recognize that the invention may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages as taught or suggested herein without necessarily achieving other objects or advantages as may be taught or suggested herein.
All of these embodiments are intended to be within the scope of the invention herein disclosed. These and other embodiments will become readily apparent to those skilled in the art from the following detailed description of the preferred embodiments having reference to the attached figures, the invention not being limited to any particular preferred embodiment(s) disclosed.
These aspects and others will be apparent from the following description of preferred embodiments and the accompanying drawing, which is meant to illustrate and not to limit the invention, wherein:
Various embodiments disclosed herein relate to a compact device package that integrates multiple devices. Electronic devices, such as medical devices, mobile computing devices, and consumer electronics, can perform numerous types of functions. For example, as disclosed herein, a hearing aid can incorporate multiple sensors with various functionalities, and multiple processors to process the signals detected by the sensors and/or to control the operation of the package or hearing aid device.
In particular, various compact packages disclosed herein can include a package housing and a substrate coupled to the housing. The substrate can be a flexible substrate that can be bent or folded into various geometrical configurations. The substrate can include many internal conductive traces that provide electrical communication between multiple device dies mounted to the substrate and between the package and an external system substrate (such as a system motherboard). Mounting multiple device dies to a flexible substrate can provide electrical communication between and among all the sensors and/or processors in the package. The package housing can include a carrier having at least two walls angled relative to one another to provide structure for the package. In other arrangements, however, the carrier may be a stiffener with only one wall. To provide for a high level of device integration, the substrate can be bent or folded one or more times, and multiple integrated device dies (e.g., sensor and/or processor dies) can be mounted on both sides of the substrate. In some arrangements, for example, the bends formed in the substrate may be disposed within the housing defined by the at least two walls. By bending or folding the substrate, the package can achieve a high degree of three-dimensional (3D) integration.
In the disclosed embodiments, sensor and/or processor dies can be mounted to the flexible substrate within the housing, e.g., within the housing defined by the at least two walls of the carrier. For example, a microelectromechanical systems (MEMS) sensor and an associated processor (such as an Application-Specific Integrated Circuit, or ASIC) can be mounted to the substrate within the package housing. Additional processor or sensor dies may also be mounted to the substrate within the housing, such as processor die(s) that control the operation of the overall electronic device (for example, a hearing aid) and/or that manage the passive electrical components of the package (such as capacitors). In some embodiments, the substrate can be bent to include two bends. The sensor and/or processor dies can be mounted on a segment of the substrate between the two bends. In some arrangements, the dies can be mounted on opposing sides of the segment between the two bends. In other arrangements, the device dies can be mounted on the same side of the substrate.
The carrier described herein may have any suitable number of walls. For example, the carrier can have at least two walls in various embodiments, such as a two-walled carrier or a three-walled carrier. The carrier can generally be configured to provide structural support for a substrate and device dies mounted to the substrate. In some arrangements, the walls can be angled relative to one another, such as by a 90° angle. Two- and three-walled carriers may advantageously be employed, because the open spaces defined between the angled walls may facilitate assembly of the package. A package assembler can therefore easily couple a package substrate to the carrier, and couple devices to the package substrate, by placing the substrate and device dies within the housing through the open sides of the carrier. For example, in a two-walled carrier, four sides may generally be open to allow the package assembler to couple the substrate and device dies to the carrier. In a three-walled carrier, three sides may generally be open to facilitate package assembly. In other embodiments, however, the carrier may be a substantially planar stiffener, e.g., a plate that does not include at least two angled walls.
In some embodiments, one or more interfacing features can be formed on a segment of the substrate that defines at least part of an exterior surface of the package. The interfacing features can include, e.g., sensors and/or communications devices or components that may be mounted on or integrally formed with the segment of the flexible substrate. For example, a capacitive touch sensor may be disposed on an outer surface of the package and can be configured to detect the movement of a user's finger over the sensor surface. A microstrip antenna may also be integrated on an exterior or outer surface of the package. The antenna can be configured to receive and/or transmit radio frequency (RF) signals from and/or to the package. Such devices can, for example, be integrated into a segment of the package substrate that extends over an outer surface of the carrier. Processor dies associated with the interfacing features may be mounted to the substrate within the package housing.
Advantageously, the embodiments disclosed herein can allow for the integration of multiple different device dies within a small, compact volume, and can also provide interfacing features on the exterior surface of the package. For example, it can be advantageous to dispose interfacing features (e.g., a capacitive sensor, an antenna, an optical sensor, etc.) on the exterior surface of the package to enhance the interaction with the user and/or other devices. Further, it can be advantageous to provide electrical contacts on the exterior of the package to provide electrical communication between the package and an external system substrate (e.g., a system motherboard).
By contrast, for devices or components that may not directly interface with the user or another device, it can be advantageous to mount such devices within the housing to improve the compactness of the package. For example, processor dies and/or sensor dies that may not directly interface with a user or other device (e.g., a motion sensor die) may be mounted within the interior of the housing. To reduce the overall package volume (e.g., including package height and/or a package's lateral footprint), the device dies within the housing may be mounted in close proximity to one another and may be mounted on opposing sides of the substrate that includes bends in order to utilize available space within the housing. An adhesive or molding material can be applied between the dies to provide structural support for the dies.
As an example, to detect sound waves, a hearing aid can include a microphone device die and one or more associated processors to process the detected sound waves and to amplify them for the user of the hearing aid. Although a primary function of conventional hearing aids is to detect and amplify sound, it should be appreciated that the packages disclosed herein may include multiple functionalities that can enhance user experience. For example, in some embodiments, a compact package configured for use in a hearing aid may include additional sensors that can provide the user with a more robust experience. In these embodiments, for example, the microphone device can be provided in a separate package or housing, and these additional sensors can be mounted in or on the disclosed compact package. The disclosed packages can include a motion sensor die (e.g., an accelerometer and/or gyroscopic device die) that can be configured to sense whether a user is falling down and/or whether a user is removing the hearing aid from, or inserting the hearing aid into, her ear. The motion sensor die can be electrically coupled to a motion sensor processor that can activate an alarm or other alert signal that can send for help if the hearing aid determines that a user is falling down. Further, in some embodiments, if the motion sensor and/or its associated processor determines that a user is removing the hearing aid, the package can be configured to send a shut-down signal to the hearing aid to conserve power. The motion sensor die and its associated processor may be mounted within the package housing, at least in part because the motion sensor die may not directly interface or interact with the user or an external device. Mounting the motion sensor die and processor within the housing can therefore free up space on the exterior surface of the package that can be used by various interfacing features.
Furthermore, in some embodiments, the compact package may include a capacitive touch sensor formed on an exterior surface of the package. The touch sensor can be presented on the outside of the package such that the user can interact with the package to turn the device(s) on or off, to adjust the volume, or to send any other instructions to the electronic device. The capacitive touch sensor can electrically communicate with a touch sensor processor mounted within the package housing, which can process signals detected by the touch sensor. Although a capacitive touch sensor is disclosed herein, it should be appreciated that in alternate embodiments a mechanical switch (such as a mechanical on/off button) can be provided on the exterior surface of the package. In some embodiments, the compact package can include an antenna formed on the exterior surface of the package. The antenna can provide wireless data communication between the package and an external device. For example, the antenna can receive and/or send radio frequency (RF) signals from and/or to the package. In one example embodiment, the antenna can receive a wireless signal from a device, such as a television or mobile computing device, and a processor mounted within the housing can convert the received signal into an audio signal that can be amplified and presented to the user by way of speaker(s). In some embodiments, the antenna can transmit wireless RF signals to an external device or user, including information detected by the electronic device, such as, e.g., when the motion sensor determines that the user is falling down. The integrated antenna can also communicate with other components of the hearing aid in some embodiments.
Other sensors and/or processors can be mounted within the housing or on an exterior surface of the housing or package. For example, pressure sensors, temperature sensors, microphone devices, optical sensors, chemical sensors, and other types of sensors may be mounted within the housing and/or on an exterior surface of the package or housing. As an example, in some arrangements, a resistive temperature sensor, or other suitable type of temperature sensor, may be mounted within the package housing to detect the temperature of an object in proximity to the housing in which the temperature sensor is disposed. An optical sensor may be mounted on an exterior surface of the housing and can be configured to detect light in various applications. In some embodiments, a pressure sensor can be mounted within the housing to detect the pressure of an object outside the package, such as air pressure, pressure changes, or the blood pressure of a user wearing the device that incorporates the compact package. It should be appreciated, however, that sensors described herein as being mounted within the housing may alternatively be disposed on an exterior surface of the package housing if suitable for a particular sensor arrangement. Similarly, sensors that are described herein as being positioned on an exterior surface of the housing may instead be mounted within the housing if suitable for the particular application, and/or may include a pathway or aperture providing communication from a die within the housing to an exterior surface of the housing. Skilled artisans will appreciate that a sensor may be mounted within the housing or on an exterior surface of the housing, depending on the suitability of the particular application. The use of the flexible substrate can advantageously provide electrical communication between the sensors and various processors mounted to the substrate.
It should be appreciated that while the disclosed embodiments describe compact sensor modules that include sensors and processors, the disclosed embodiments can be implemented in any other suitable type of device package, including packages that do not include sensors. Furthermore, while various examples disclosed herein relate to packages suitable for integration in a hearing aid device, the disclosed packages may also be implemented in any other suitable device, such as other medical devices, mobile computing devices, consumer electronics devices, etc. For example, the packages disclosed herein may be implemented in a variety of wearable electronics devices, such as wearable medical devices that can monitor one or more biological functions. As one example, the highly integrated, compact packages disclosed herein may also be implemented in a wearable blood pressure or heart monitor (e.g., electrocardiographic or EKG monitor, or a heart pulse monitor), a blood glucose monitor, or a blood oxygen monitor (oximeter). For example, for the wearable blood pressure or heart monitor, a pressure sensor die can be mounted to the substrate within the housing or on an exterior surface of the package. For the glucose monitor or the blood oxygen monitor, an optical sensor can be mounted to the substrate on an exterior surface of the package. Such medical monitoring sensors may be implemented in a wearable device, such as a wristwatch or a bandage-type structure. Processors can be mounted within the housing to process the signals detected by the blood pressure monitor, heart monitor, blood glucose monitor, or blood oxygen level monitor.
The carrier 105 can serve as a stiffener that provides structural support for the package. For example, the carrier 105 can serve to protect the package against external forces, such as when the package is dropped or otherwise impacted. Furthermore, the carrier 105 can be shaped and sized to define the approximate volume of the assembled package. For example, the walls of the carrier 105 can be dimensioned and selected to fit within a predetermined space in the electronic device. As explained above, the carrier 105 can assist in the assembly of the package by, e.g., a robotic manipulator programmed to pick and place components in the package. Because there are fewer than four walls in the disclosed embodiments (e.g., the three-walled carrier of
The carrier 105 disclosed herein can have at least two walls angled relative to one another. For example, as shown in
The carrier 105 can be made of any suitable material that provides structural support for the compact package. For example, in some embodiments, the carrier 105 can be formed from a plastic material. In other embodiments, the carrier 105 can be formed from a metal, such as aluminum. In general, therefore, the carrier 105 can define a package housing defined by the walls 117a, 117b, and 117c that are angled relative to one another. As explained below, the substrate can be coupled to the carrier 105 and can support one or more device dies. Some device dies can be mounted within the package housing, e.g., within the corner portion defined by the three walls 117a, 117b, and 117c. Other components, like the interfacing features, can be formed on portions of the substrate that define an exterior surface of the package.
Furthermore, one or more interfacing features can be provided on the substrate on an exterior surface of the package 100. For example, the package 100 can include interfacing features, such as a capacitive touch sensor 107 and a microstrip antenna 109 (see, e.g.,
The substrate 103 can be coupled to one or more of the walls 117a-117c of the carrier 105. For example, in some embodiments, segments of the substrate 103 can be attached to the carrier using an adhesive, such as an epoxy. As best seen from the unfolded views of
As explained herein, the substrate 103 can be a flexible substrate with integrated bond pads, leads and traces that are configured to provide electrical communication between components coupled to the substrate 103. Flexible substrates can be useful in arrangements where it is desirable for the substrate to conform to a particular geometry employed within a system. Flexible substrates can be made of a flexible plastic material, such as polyimide or PEEK and can include integrated bond pads, traces and leads similar to those used in conventional PCB substrate technologies. The flexible substrate can be bent or folded to conform to a particular geometry, which permits contacting downstream components in a variety of configurations. Furthermore, traces and leads can be patterned on or within the flexible substrate in very small dimensions. For example, in some embodiments, the traces can have line widths and spaces on the order of about 15 to 20 μm, and the leads or bond pads can have widths or diameters of about 200-300 μm with similar spacing, such that the pitch is on the order of 400-600 μm. The skilled artisan will appreciate, however, that folds or bends in the substrate can be accomplished with different materials.
As shown in
It should be appreciated that segments 115a, 115b, 115c, and 115f each define at least part of an exterior surface of the package 100, because segments 115a, 115b, 115c, and 115f are disposed on an outer surface of the carrier 105 and/or exposed outside the housing defined by the walls 117a-c of the carrier 105. Interfacing features and electrical contacts can be provided on segments that define the exterior surface of the package. For example, one type of interfacing feature, the capacitive touch sensor 107, can be formed in segment 115b, and another type of interfacing feature, the microstrip antenna 109, can be formed in segment 115c. For example, segment 115b of the substrate 103 can be suitably patterned with conductive and insulating materials that are configured to detect a changing capacitance induced by coming into contact with a user's finger, for example. In other arrangements, a capacitive touch sensor 107 can be formed in a device that is mounted to segment 115b. As explained above, when implemented in various electronic devices (such as a hearing aid), the touch sensor 107 may be used to turn the device on or off, to adjust the volume of the device, and/or to transmit other suitable instructions to the device. In some embodiments, the microstrip antenna 109 can be patterned onto segment 115c of the substrate 103 in a serpentine pattern, or any other suitable pattern. For example, the antenna 109 can be formed of a conductive material and can be disposed on a portion of the exterior surface of the package 100 in order to provide improved wireless communication with an external device. In some embodiments, a separate antenna can be mounted on segment 115c of the substrate 103. The antenna 109 can be shaped and sized to receive and/or transmit wireless data communication at any suitable band of frequencies, e.g., RF frequencies. In some embodiments, for example, the antenna 109 can be shaped and sized to provide communication over a Bluetooth and/or wireless Internet connection.
Furthermore, electrical contact pads 111 can be formed in segment 115f, which also forms part of an exterior surface of the package 100. The illustrated array of contact pads 111 can be formed of a conductor, such as copper or gold, and can be shaped and positioned to electrically couple to corresponding landing pads or leads on an external device or system motherboard. For example, as shown in
In
Turning to FIGS. 1F and 1H-1J, various components are illustrated that are mounted to the substrate 103 within the housing, e.g., mounted within the protected volume formed by the three walls 117a-117c of the carrier 105. For example, bends 113c and 113d can be formed at an angle between about 170° and about 190°, e.g., at about 180°. As shown in
For example, the oscillator 124, the motion sensor die 126, the passive components 128, the IPD die 130, and the ASIC die 132 can be mounted to the substrate 103 between bends 113c and 113d. As shown in, e.g.,
The passive components 128 can include one or more passive electrical components, such as, e.g., capacitors, resistors, etc. The passive components 128 can be configured to smooth electrical signals that are transmitted from the sensor dies to the processor dies, or any other suitable signals. The IPD die 130 can provide for central management of the various passive electrical components.
Furthermore, as shown in FIGS. 1F and 1H-1J, the controller die 134 and the signal processing die 136 can be mounted to segment 115e, which is defined adjacent bends 113d and 113e. In the illustrated embodiment, the controller die 134 is mounted to the first side 116 of the substrate 103, and the signal processing die 136 is mounted on the second side 118 of the substrate 103. Of course, the controller die 134 and the signal processing die 136 can be mounted on the second side 118 and the first side 116, respectively. Further the controller die 134 or the signal processing die 136 can also be mounted on segment 115f, e.g., on the second side 118 of segment 115f.
In some embodiments, the controller die 134 can be configured to act as a controller for the entire package 100 and/or the larger electronic device into which the package 100 is incorporated. For example, the controller die 134 can be programmed to manage the communications between the device dies mounted in the package 100, and can also be programmed to manage the power consumption of the device dies in the package 100. In general, therefore, the controller die 134 can act to control the overall operations of the package 100 and/or the larger device (e.g., hearing aid). The signal processing die 136 can be a digital signal processing die in some embodiments. For example, the signal processing die 136 can be programmed to process audio signals detected by the microphone device(s) located in other parts of a hearing aid. For example, analog audio signals can be transmitted from the microphone device(s) to the signal processing die 136 by way of the electrical contacts 111. The signal processing die 136 can convert the analog signals to digital signals and can provide for the amplification of the audio signals before being transmitted to the user by the speaker(s) provided in the hearing aid.
As shown in
While the embodiment of
Segments 115b and 115c can extend from segment 115a, and segment 115f can extend from segment 115e. The first side 116 of segments 115a, 115b, 115c, and 115f can be bent to form at least part of an exterior surface of the package. Indeed, the interfacing features can be integrated with one or more of segments 115a, 115b, 115c, and 115f. For example, the capacitive touch sensor 107, one example of an interfacing feature, can be formed within segment 115b and can be sensitive to touch on the first side 116. The microstrip antenna 109, another example of an interfacing feature, can be formed within segment 115c and can communicate wirelessly from the outwardly facing first side 116. The electrical contact pads 111 can be exposed on the first side 116 of segment 115f.
In addition, as shown in
As shown in
The package 1 of
Segment 15a can be coupled to wall 17b of the carrier 5, and segment 15b can be coupled to wall 17a of the carrier 5. As illustrated, segments 15a and 15b can define at least part of an exterior surface of the package 1, and bend 13a can be formed between segments 15a and 15b. For example, as shown in
As described above, bend 13a can be formed along the outer surface of the carrier 5. Within the housing formed by the two walls 17a and 17b, the substrate 3 can include multiple bends. For example, bend 13b can be defined between segments 15b and 15c. Bend 13c can be formed between segments 15c and 15d of the substrate 3. Bend 13d can be defined between segments 15d and 15e. The illustrated bends 13b-13d can be formed at an angle between about 170° and 190°, e.g., at about 180°. As shown, bend 13c can be bent in a direction opposite the direction in which bends 13d and 13e are formed.
In
As with the embodiment of
Furthermore, the wireless communications die 4 can be mounted on the second side 18 of segment 15c of the substrate 3 in mounting region 4′, e.g., on the opposite side of the substrate 3 from the motion sensor die 6 and the capacitive sensor processor die 8. The signal processing die 14 can be mounted to the second side 18 of segment 15d of the substrate 3 in mounting region 14′, e.g., on the opposite side of the substrate 3 from the controller die 10 and the IPD die 12. As with
The method 50 then moves to a block 55, in which the substrate is bent in a first direction. As explained herein, the substrate can be bent by any suitable angle, such as, e.g., between about 170° and about 190°. Turning to a block 56, the substrate can be bent in a second direction. In some arrangements, for example, the second bend can be formed in a direction opposite the direction of the first bend. The second bend can also be bent by any suitable angle. In one embodiment, the second bend is bent at about the same angle as the first bend, but in an opposite direction. Further, the first and second bends can be formed such that the first and second integrated device dies are mounted between the first and second bends.
In a block 58, the substrate can be coupled to a first wall of a carrier. The carrier can have at least two walls angled relative to one another and can be configured to provide structural support for the package. In some arrangements, the carrier can be formed of a metal, such as aluminum, or a suitable plastic material. In some embodiments, the substrate can be adhered to a wall of the carrier. As disclosed herein, various segments of the substrate can define exterior surfaces of the compact device package. Interfacing features can be formed in the substrate segments that define the exterior surfaces. For example, a first segment of the substrate can be coupled to a first wall of the carrier, and can define at least part of an exterior surface of the integrated device package. A first interfacing feature can be formed in the first segment. Further, a second segment can be coupled to a second wall of the carrier. The second segment can also define at least part of an exterior surface of the integrated device package, and a second interfacing feature can be formed in the second segment. One example of an interfacing feature is a capacitive touch sensor. In other arrangements, a mechanical interfacing feature, such as a mechanical on/off button, can be formed on the exterior surfaces of the package. As disclosed herein, another example of an interfacing feature is a microstrip antenna. Still other examples of interfacing features may be suitable in various applications.
In some embodiments, a first segment can be disposed adjacent the first bend, a second segment can be disposed between the first bend and the second bend, and a third segment can be disposed adjacent the third bend. The first and second integrated device dies can be mounted to the second segment. To provide structural support between the segments and to support the weight of the device dies, an adhesive or a molding material can be applied between the first segment and the second segment and between the second segment and the third segment. The adhesive or molding material may be cured and hardened to support the segments of the substrate and the device dies. The adhesive or molding material may also serve to encapsulate and/or seal the dies. For example, the adhesive or molding material may protect the dies from moisture and contaminants.
Devices employing the above described schemes can be implemented into various electronic devices. Examples of the electronic devices can include, but are not limited to, consumer electronic products, parts of the consumer electronic products, electronic test equipment, medical devices, etc. Examples of electronic products can include, but are not limited to, a mobile phone, a hearing aid, a wearable electronic device (such as a watch or bandage) that includes one or more biological monitoring sensors, a telephone, a television, a computer monitor, a computer, a hand-held computer, a personal digital assistant (PDA), a microwave, a refrigerator, an automobile, a stereo system, a cassette recorder or player, a DVD player, a CD player, a VCR, an MP3 player, a radio, a camcorder, a camera, a digital camera, a washer, a dryer, a washer/dryer, a copier, a facsimile machine, a scanner, a multi functional peripheral device, a wrist watch, a clock, etc. Further, the electronic device can include unfinished products.
Although this invention has been disclosed in the context of certain preferred embodiments and examples, it will be understood by those skilled in the art that the present invention extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses of the invention and obvious modifications and equivalents thereof. In addition, while several variations of the invention have been shown and described in detail, other modifications, which are within the scope of this invention, will be readily apparent to those of skill in the art based upon this disclosure. It is also contemplated that various combinations or sub-combinations of the specific features and aspects of the embodiments may be made and still fall within the scope of the invention. It should be understood that various features and aspects of the disclosed embodiments can be combined with, or substituted for, one another in order to form varying modes of the disclosed invention. Thus, it is intended that the scope of the present invention herein disclosed should not be limited by the particular disclosed embodiments described above, but should be determined only by a fair reading of the claims that follow.
Patent | Priority | Assignee | Title |
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