Patent Grant
11616019
Modern integrated circuit chips and multi-chip systems pose a number of packaging challenges for designers. One such challenge relates to the number of electrical connections that must be located on the exterior of the chip package. As chip technology has developed, the quantity of on-chip circuitry has increased dramatically. This has been especially true for central processing unit (“CPU”) and graphics processing unit (“GPU”) designs, for example. The increased quantity of on-chip circuitry has caused a commensurate increase in the number of external connections that must be provided on the chip package so that the on-chip circuitry can be interfaced with the surrounding circuitry of a host system in which the chip package will be deployed. Packaging techniques have developed accordingly, such that modern CPU and GPU packages include a substrate on which an integrated circuit die is mounted. A rectangular grid or array of connecting points is typically provided on the bottom side of the substrate to connect the circuitry of the integrated circuit die with the circuitry of the host system. Examples of such grids or arrays of connecting points include pin grid arrays (“PGA”), ball grid arrays (“BGA”), land grid arrays (“LGA”) and the like. A substrate has a larger area than does an integrated circuit die, so inclusion of a substrate in the chip package makes more space available to accommodate the relatively large PGA pins, BGA solder balls, or LGA contact pads that must be placed on the package. A large substrate, however, occupies a large area of the host printed circuit board (“PCB”) on which the substrate is mounted. This, in turn, constrains space available on the host PCB for placement of the many other components that are required by the host system. In addition, the high concentration of connecting points on the bottom of the substrate results in a high routing density for signals in the area of the PCB over which the substrate is mounted. The high routing density often requires adding layers to the host PCB, which increases both its cost and its complexity.
A second packaging challenge relates to signal integrity. As the density of connecting points on a chip packages becomes higher, the distance between adjacent connecting points on the package becomes smaller. Consequently, the risk of unwanted signal coupling increases—especially as frequencies increase in the signals that are routed through the connecting points. Even when coupling noise can be addressed successfully, however, transient voltage drops associated with individual switching signals remain as a separate problem. Signals that switch with fast edge rates (“fast slew rate” signals) are associated with higher changes in current per unit time (“di/dt”) at the switching edges than are signals that switch with slower edge rates. This is true regardless of the frequency at which they switch. Moreover, the current path associated with any switching signal presents an inductance, L. Any switching signal will therefore produce a transient voltage drop across this inductance in an amount proportional to its di/dt, since the voltage across an inductor, VL, is equal to the product of the inductance and the di/dt. In other words, VL=L*di/dt. To compensate, designers place decoupling capacitors in close proximity to switching circuits in order to absorb the transients by supplying short-term current demand with a nearby charge, thereby reducing the associated voltage drop on the signal path and improving signal integrity. Specifically, designers place the decoupling capacitors in close proximity to the integrated circuit die where the switching circuitry resides. Decoupling capacitors can be very large, however, compared to the size of an integrated circuit die. Placement of the decoupling capacitors has therefore become increasingly problematic because the area in close proximity to the integrated circuit die is already dense with PCB traces, pins, solder balls or contact pads.
A third packaging challenge relates to heat dissipation. A modern CPU or GPU can dissipate well over 100 Watts of power across a die area measuring less than half of one square inch. This produces a tremendous amount of heat density, which requires efficient heat dissipation techniques in order to maintain die temperatures within safe operating limits.
Various techniques and apparatus that beneficially address the above and other challenges will be described below with reference to the following drawings, in which like reference numbers generally denote like or similar elements.
This disclosure describes multiple embodiments by way of example and illustration. It is intended that characteristics and features of all described embodiments may be combined in any manner consistent with the teachings, suggestions and objectives contained herein. Thus, phrases such as “in an embodiment,” “in one embodiment,” and the like, when used to describe embodiments in a particular context, are not intended to limit the described characteristics or features only to the embodiments appearing in that context.
The phrases “based on” or “based at least in part on” refer to one or more inputs that can be used directly or indirectly in making some determination or in performing some computation. Use of those phrases herein is not intended to foreclose using additional or other inputs in making the described determination or in performing the described computation. Rather, determinations or computations so described may be based either solely on the referenced inputs or on those inputs as well as others. The phrase “configured to” as used herein means that the referenced item, when operated, can perform the described function. In this sense an item can be “configured to” perform a function even when the item is not operating and is therefore not currently performing the function. Use of the phrase “configured to” herein does not necessarily mean that the described item has been modified in some way relative to a previous state. “Coupled” as used herein refers to a connection between items. Such a connection can be direct or can be indirect through connections with other intermediate items. Terms used herein such as “including,” “comprising,” and their variants, mean “including but not limited to.” Articles of speech such as “a,” “an,” and “the” as used herein are intended to serve as singular as well as plural references except where the context clearly indicates otherwise.
As shown in the drawing, integrated circuit die 102 may include circuitry 106 that exhibits higher di/dt (i.e., faster switching edge rates) and circuitry 108 that exhibits lower di/dt (i.e., slower switching edge rates relative to those corresponding to circuitry 106). A non-limiting example of circuitry that may exhibit slower edge rates, and thus lower di/dt, would be off-chip input/output signals. A non-limiting example of circuitry that may exhibit faster edge rates, and thus higher di/dt, would be processing stages within a CPU or GPU core. Although the diagram shows circuitry 106 and 108 in distinct areas of die 102, this is only for purposes of illustration and clarity. In embodiments, elements that make up circuitry 106 and 108 may in general be disposed at any locations on die 102 and may be distributed across several different regions, which regions may themselves be overlapping or distinct, contiguous or fragmented.
The top side surface area of substrate 104 is larger than that of die 102, such that die 102 does not cover the entire top surface of substrate 104. In particular, a first region 110 of substrate 104 (shown in the drawing with a vertical line pattern) is not covered by die 102, while a second region 112 of substrate 104 (shown in the drawing with a crosshatch pattern) is covered by die 102.
At least one electrically conductive element 114 is located in region 110 on the top side of substrate 104. Conductive element 114 may take a variety of forms including, for example, one or more exposed portions of a conductive layer disposed within or near the surface of substrate 104, or one or more separate conductive elements attached to the top side of substrate 104. In the embodiment shown in
Each of embodiments 200-500 includes one or more electrically conductive elements 114 located on a top side 218, 318, 418, 518 of a substrate 204, 304, 404, 504. For embodiments in which protective cover 203 will extend over a portion of conductive elements 114 on the top side of the substrate, as shown in
In each of embodiments 200-500, integrated circuit die 102 may be coupled to the corresponding substrate using any of a variety of known techniques. In embodiments 200 and 400, for example, die 102 is shown coupled to the corresponding substrate in “flip chip” fashion. According to the flip chip technique, the integrated circuit die is mounted face down onto the substrate so that connecting pads on the face of the integrated circuit die may be coupled to electrical contacts in or on the substrate by means of solder balls or fused connection points 205, 405. In embodiments 300 and 500, die 102 is shown coupled to the corresponding substrate in “wire bonding” fashion. According to the wire bonding technique, the integrated circuit die is mounted face up on the substrate so that connecting pads on the face of the integrated circuit die may be coupled to electrical contacts in or on the substrate by means of bonding wires such as those illustrated at 305, 505. Other die mounting techniques may also be used. Regardless of the mounting technique employed, connecting pads on die 102 will be electrically connected to corresponding electrical contacts in or on the corresponding substrate (“substrate contacts”). Only a few such connecting pads and substrate contacts are shown in
Referring now to
Embodiment 300, illustrated in
Note that, in embodiment 200, both distinct ground return paths to the host system pass through the interior of the substrate. In embodiment 300, however, only one of the two distinct ground return paths to the host system passes through the interior of the substrate. The latter arrangement may be of benefit not only with the wire bonding technique but also with other die mounting techniques in which the connecting pads of the die are upward facing relative to the mounting surface of the substrate.
Referring now to
Embodiment 500, illustrated in
Embodiment 600, illustrated in
In embodiment 700, illustrated in
In embodiment 800, illustrated in
Note that, in each of example embodiments 600-800, PCB ground contacts 664 are configured to be located underneath the substrate when the substrate is coupled to PCB 650. Thus, in each embodiment, the second electrically conductive paths are very short—comprising just the solder balls under the substrate in embodiment 600 and just the conductors inside the sockets in embodiments 700 and 800. The first electrically conductive paths 668, 768, 868 in these embodiments are longer than the second electrically conductive paths, because the distance between substrate contacts 114 and PCB ground contacts 660 is longer in each embodiment than is the distance between the bottom sides of substrates 604, 704, 804 and the adjacent surface of PCB 650 on which PCB ground contacts 664 are formed.
In some embodiments, therefore, the ground pads on die 102 that are in the first set, 234, 334, 434, 534, correspond to the circuitry 108 on die 102 that has the lower di/dt, while the ground pads on die 102 that are in the second set, 236, 336, 436, 536, correspond to the circuitry 106 on die 102 that has the higher di/dt. Thus, in such embodiments, the circuitry 106 with higher di/dt has a shorter ground return path to the host system of PCB 650 than does the circuitry 108 with the lower di/dt.
Also note that, in each of example embodiments 600-800, one or more sets of off-chip decoupling capacitors may be placed on PCB 650 in advantageous locations. Specifically, off-chip decoupling capacitors 670, 672 may be placed under the substrate in regions 654, 754, 854 of PCB 650, while potentially larger off-chip decoupling capacitors 674 may be placed in regions 652, 752, 852 of PCB 650 where more space is available. (The phrase “under the substrate” as used herein and in the appended claims refers to regions 654, 754, 854 and includes the locations shown for capacitors 670, which are on the opposite side of PCB 650 from the substrate, as well as the locations shown for capacitors 672, which are on the same side of PCB 650 as the substrate.) In such embodiments, off-chip decoupling capacitors 670, 672 may be associated with circuitry 106 with higher di/dt, either because they are located proximate to a host system ground return path that is exclusive to circuitry 106, or because they are located proximate to ground contacts 664 to which circuitry 106 is connected, or both. Similarly, decoupling capacitors 674 may be associated with circuitry 108 with lower di/dt, either because they are located proximate to a host system ground return path that is exclusive to circuitry 108, or because they are located proximate to ground contacts 660 to which circuitry 108 is connected, or both. In either case, decoupling capacitors 670, 672 may generally be located closer to die 102 than decoupling capacitors 674, because capacitors 670, 672 are located in region 654 under the substrate (in some embodiments, even under the die area itself), whereas capacitors 674 are located in region 652, which in most embodiments will be farther from the die area. Decoupling capacitors need not be present in all embodiments. In some embodiments, only one or the other type of decoupling capacitors, such as 670 and/or 672, or such as 674, may be present.
In embodiments generally, electrically conductive paths 668, 768, 868 may take any of a variety of forms including, for example, wires or cables. In a more particular class of embodiments, conductive paths 668, 768, 868 may take the form of one or more metal plates.
An example of one such embodiment is shown in
In system 900, metal plate 906 defines an opening 912 that is configured to expose the upward facing side of die 102 after the plate is installed on PCB 650 over semiconductor assembly 100. In some embodiments, opening 912 may facilitate thermal management of assembly 100. Referring now to
Referring again to
In embodiments, coolers 1000, 1202 may take a wide variety of forms. For example, cooler 1000, 1202 may be a passive heat dissipation device such as a simple heat sink, or cooler 1000, 1202 may be an active heat dissipation device that includes one or more active elements such as a fan 1004, as shown, or such as a liquid cooling system. The number of cooling elements and their spatial orientations may also vary.
Metal plate 906 may take a wide variety of forms in other embodiments. For example,
System 1300 may also be implemented using a plate and cooler arrangement such as that shown in
Multiple specific embodiments have been described above and in the appended claims. Such embodiments have been provided by way of example and illustration. Persons having skill in the art and having reference to this disclosure will perceive various utilitarian combinations, modifications and generalizations of the features and characteristics of the embodiments so described. For example, steps in methods described herein may generally be performed in any order, and some steps may be omitted, while other steps may be added, except where the context clearly indicates otherwise. Similarly, components in structures described herein may be arranged in different positions or locations, and some components may be omitted, while other components may be added, except where the context clearly indicates otherwise. The scope of the disclosure is intended to include all such combinations, modifications, and generalizations as well as their equivalents.
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