Abstract:
An interconnect structure (i.e., a laminate interposer) which is mounted to a semiconductor package leadframe or substrate prior to molding the package body of the semiconductor package. During the molding process, the top of the laminate interposer is protected such that the top surface of the interposer is exposed subsequent to the completion of the molding process. In this manner, electrical signals can be routed from the package leadframe or substrate to the top surface of the package body of the semiconductor package. Subsequently, a mating package can be mounted on top of the underlying package by way of a ball grid array (BGA) interconnect or other type of interconnect.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     Not Applicable 
     STATEMENT RE: FEDERALLY SPONSORED RESEARCH/DEVELOPMENT 
     Not Applicable 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to integrated circuit chip package technology and, more particularly, to a semiconductor package which includes an embedded laminate interposer configured to allow a mating semiconductor package to be mounted and electrically connected thereto. 
     2. Description of the Related Art 
     Semiconductor dies are conventionally enclosed in plastic packages that provide protection from hostile environments and enable electrical interconnection between the semiconductor die and an underlying substrate such as a printed circuit board (PCB) or motherboard. The elements of such a package include a metal leadframe, an integrated circuit or semiconductor die, bonding material to attach the semiconductor die to the leadframe, bond wires which electrically connect pads on the semiconductor die to individual leads of the leadframe, and a hard plastic encapsulant material which covers the other components and forms the exterior of the semiconductor package commonly referred to as the package body. 
     The leadframe is the central supporting structure of such a package, and is typically fabricated by chemically etching or mechanically stamping a metal strip. A portion of the leadframe is internal to the package, i.e., completely surrounded by the plastic encapsulant or package body. Portions of the leads of the leadframe extend externally from the package body or are partially exposed therein for use in electrically connecting the package to another component. In certain semiconductor packages, a portion of the die attach pad or die pad of the leadframe also remains exposed within the package body. In other semiconductor packages, the metal leadframe is substituted with a laminate substrate to which the semiconductor die is mounted and which includes pads or terminals for mimicking the functionality of the leads and establishing electrical communication with another device. 
     Once the semiconductor dies have been produced and encapsulated in the semiconductor packages described above, they may be used in a wide variety of electronic devices. The variety of electronic devices utilizing semiconductor packages has grown dramatically in recent years. These devices include cellular phones, portable computers, etc. Each of these devices typically includes a printed circuit board on which a significant number of such semiconductor packages are secured to provide multiple electronic functions. These electronic devices are typically manufactured in reduced sizes and at reduced costs, which results in increased consumer demand. Accordingly, not only are semiconductor dies highly integrated, but also semiconductor packages are highly miniaturized with an increased level of package mounting density. 
     Even though semiconductor packages have been miniaturized, space on a printed circuit board remains limited and precious. Thus, there is a need to find a semiconductor package design to maximize the number of semiconductor packages that may be integrated into an electronic device, yet minimize the space needed to accommodate these semiconductor packages. One method to minimize space needed to accommodate the semiconductor packages is to stack the semiconductor packages on top of each other, or to stack individual semiconductor devices or other devices within the package body of the semiconductor package. However, when attempting to integrate a large number of devices such as memory chips into a vertical stack, test yield loss typically becomes higher as more such devices are assembled in a single package. As a result, it becomes desirable to use multiple packages which each contain a subset of the memory chips or devices to be integrated vertically. Existing solutions for package stacking such as straddle mount laminate BGA or stacked die TSOP often do not meet form factor requirements. Therefore, a new solution is needed. The present invention is an extension of the stacking solution for space efficiency in that it is directed to, among other things, a semiconductor package which includes an embedded laminate interposer configured to allow a mating semiconductor package to be mounted and electrically connected thereto. In this regard, the present invention provides a three-dimensional packaging solution which is required for, among other things, high density NAND Flash integration. These, as well as other features and attributes of the present invention will be discussed in more detail below. 
     BRIEF SUMMARY OF THE INVENTION 
     In accordance with one aspect of the invention, there is provided a two sided interconnect structure (i.e., a laminate interposer) which is mounted to a semiconductor package leadframe or substrate prior to molding the package body of the semiconductor package. During the molding process, the top of the laminate interposer is protected such that the top surface of the interposer is exposed subsequent to the completion of the molding process. In this manner, electrical signals can be routed from the package leadframe or substrate to the top surface of the package body of the semiconductor package. Subsequently, a mating package can be mounted on top of the underlying package by way of a ball grid array (BGA) interconnect or other type of interconnect. The interposer may be mounted to the package leadframe or substrate using a standard BGA interconnect method. During molding of the package body, the mold compound will flow underneath the interposer and between the BGA joints, thus helping to lock the interposer in place in the completed semiconductor package. The interposer may be mounted to a substrate strip with an array of units so that a single interposer strip or frame is attached to adjacent units. During singulation (i.e., the separation of the completed units or semiconductor packages from each other), the interposer is separated so that the interposer is exposed on the side of the semiconductor package. Locking features may be added to the laminate interposer to improve reliability. 
     In accordance with another aspect of the present invention, there is provided a chip stack wherein multiple semiconductor packages (e.g., QFN packages) are stacked together using a laminate interposer. The leads of the semiconductor packages integrated into the stack are extended to provide a mounting surface for the laminate interposer. The laminate interposer provides routing between the bottom and top packages in the stack. This is required to route chip-select signals in such a way that all the semiconductor packages in the stack may have identical bond diagrams. 
     The present invention is best understood by reference to the following detailed description when read in conjunction with the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       These, as well as other features of the present invention, will become more apparent upon reference to the drawings wherein: 
         FIG. 1  is a top plan view of a semiconductor package constructed in accordance with a first embodiment of the present invention; 
         FIG. 2  is a cross-sectional view of the semiconductor package of the first embodiment of the present invention taken along line  2 - 2  of  FIG. 1 ; 
         FIG. 3  is a cross-sectional view of a pair of semiconductor packages constructed in accordance with the first embodiment as arranged in a stacked configuration; 
         FIG. 4  is a cross-sectional view of a semiconductor package constructed in accordance with a second embodiment of the present invention; 
         FIG. 5  is a cross-sectional view of a pair of semiconductor packages constructed in accordance with the second embodiment as arranged in a stacked configuration; and 
         FIG. 6  is a cross-sectional view of a pair of semiconductor packages as arranged in a stacked configuration through the use of an interposer constructed in accordance with a third embodiment of the present invention. 
     
    
    
     Common reference numerals are used throughout the drawings and detailed description to indicate like elements. 
     DETAILED DESCRIPTION OF THE INVENTION 
     Referring now to the drawings wherein the showings are for purposes of illustrating various embodiments of the present invention only, and not for purposes of limiting the same,  FIGS. 1 and 2  depict a semiconductor package  10  constructed in accordance with a first embodiment of the present invention. The semiconductor package  10  comprises a leadframe  12  which itself includes a die attach pad or die pad  14 . In the semiconductor package  10 , the die pad  14  has a generally quadrangular configuration defining four (4) peripheral edge segments. In addition, the die pad  14  defines a generally planar top surface  16 , and an opposed, generally planar bottom surface  18 . 
     In addition to the die pad  14 , the leadframe  12  of the semiconductor package  10  comprises a plurality of leads  20 . In the semiconductor package  10 , the leads  20  are segregated into two sets, with the leads  20  of each set extending along and in spaced relation to a respective one of an opposed pair of the peripheral edge segments defined by the die pad  14 . Each lead  20  preferably defines a generally planar top surface  22 , and a generally planar bottom surface  24  which is disposed in opposed relation to the top surface  22 . In addition to the top and bottom surfaces  22 ,  24 , each lead  20  further defines a shoulder or shelf  26  which is recessed relative to the bottom surface  24 , and extends in opposed relation to the top surface  22 . The shelf  26  of each lead  20  also extends to the innermost end thereof, i.e., the end disposed closest to the die pad  14 . 
     The leadframe  12  of the semiconductor package  10  is preferably fabricated from a conventional metal material, such as copper or copper alloy. The formation of the shelves  26  within the leads  20  and the top surface  16  of the die pad  14  is preferably facilitated by subjecting a metal plate from which the leadframe  12  is typically formed to a partial etching process. More particularly, each of the opposed, generally planar faces or sides of such metal plate preferably has an etch mask applied thereto in a manner wherein the subsequent application of a suitable etchant to the metal plate will effectively remove metal material therefrom as facilitates the formation of the top surface  16  of the die pad  14  and the recessed shelves  26  of the leads  20 . Such etching process may also be used to facilitate the formation of the die pad  14  and leads  20  themselves from the original metal plate, or may be implemented so as to facilitate the formation of the top surface  16  and shelves  26  subsequent to the die pad  14  and leads  20  being defined by the completion of a stamping process upon the original metal plate. 
     As is further seen in  FIG. 2 , the partial etching process to which the die pad  14  and leads  20  are subjected is preferably completed in a manner wherein the thickness of the die pad  14  between the top and bottom surfaces  16 ,  18  thereof is approximately one-half of the thickness of each of the leads  20  between the top and bottom surfaces  22 ,  24  thereof. Similarly, the thickness of each lead  20  between the top surface  22  and the shelf  26  thereof is approximately one-half of the thickness of each lead  20  between the top and bottom surfaces  22 ,  24  thereof. Thus, in the leadframe  12 , the bottom surfaces  18 ,  24  of the die pad  14  and leads  20  extend in generally co-planar relation to each other. Though the top surface  16  of the die pad  14  and the shelves  26  of the leads  20  are typically not perfectly planar due to their formation as a result of the completion of a chemical etching process, such surfaces also extend in generally co-planar relation to each other in the manner shown in  FIG. 2 . Though not shown, those of ordinary skill in the art will recognize that the die pad  14  may be alternately configured to have a thickness similar to that of the leads  20 , such that the top surface  16  of the die pad  14  and the top surfaces  22  of the leads  20  extend in substantially coplanar relation to each other. Further, it is contemplated that that the die pad  14  may be formed to include a recessed shelf similar to the shelf  26  of each of the leads  20  or another suitable locking feature to assist in the firm interlock thereof to a package body  60  of the semiconductor package  10  which is described in detail below. Still further, it is also contemplated that the bottom surface  18  of the die pad  14  may included a recessed portion for providing a surface for adhesively bonding two stacked packages to each other, as will also be described below. 
     Attached to the top surface  16  of the die pad  14  is a die stack  28  of the semiconductor package  10 . The die stack  28  comprises a plurality of individual semiconductor dies  30  which are arranged in a stacked configuration. In this regard, each of the semiconductor dies  30  in the die stack  28  is secured to the semiconductor die  30  below it by a layer  32  of a suitable adhesive. Similarly, the attachment of the lowermost semiconductor die  30  in the die stack  28  to the top surface  16  of the die pad  14  is facilitated by an additional adhesive layer  32 . As shown in  FIG. 2 , four semiconductor dies  30  are depicted as being included in the die stack  28 . However, those of ordinary skill in the art will recognize that the die stack  28  may be assembled to include fewer or greater than the four semiconductor dies  30  depicted in  FIG. 2 . In the semiconductor package  10 , the pads or terminals of each of the semiconductor dies  30  of the die stack  28  are electrically connected to the leads  20  through the use of conductive wires  34 . The conductive wires  34  may be fabricated from aluminum, copper, gold, silver or a functional equivalent. 
     The semiconductor package  10  of the present invention further comprises a laminate interposer  36  which is mounted and electrically connected to the top surfaces  22  of the leads  20 . As seen in  FIGS. 1 and 2 , the interposer  36  comprises a first segment  36   a  which is electrically connected to each of the leads  20  of one of the sets thereof, and a separate second segment  36   b  which is electrically connected to each of the leads  20  of the remaining set thereof. The first and second segments  36   a ,  36   b  of the interposer  36  are identically configured to each other and, in the completed semiconductor package  10 , extend in spaced, generally parallel relation to each other. 
     Each of the interposer segments  36   a ,  36   b  of the interposer  36  comprises an interposer body  38  having a top surface  40 , a bottom surface  42 , an opposed pair of longitudinal side surfaces  44 , and an opposed pair of lateral side surfaces  46 . Embedded within the interposer body  38  of each of the first and second segments  36   a ,  36   b  is a plurality of top pads  48  and bottom pads  50 . The top and bottom pads  48 ,  50  embedded within the interposer body  38  of each of the first and second segments  36   a ,  36   b  are segregated into multiple pairs, with the top pad  48  of each pair being disposed in spaced, substantial vertical alignment with the bottom pad  50  of the same pair. As seen in  FIG. 2 , the top and bottom pads  48 ,  50  of each pair within each of the first and second segments  36   a ,  36   b  are electrically connected to each other by one or more conductive vias  52  which extend through the interposer body  38  substantially perpendicularly between the top and bottom pads  48 ,  50  of the corresponding pair. The top and bottom pads  48 ,  50  of each pair are preferably identically configured to each other, and fabricated from a suitable conductive material, as is the conductive via(s)  52  extending therebetween. Those of ordinary skill in the art will recognize that the top and bottom pads  48 ,  50  of each pair need not necessarily be in exact vertical alignment, and that some degree of juxtaposition therebetween is contemplated to fall within the scope of the present invention. 
     As further seen in  FIGS. 1 and 2 , formed in the top surface  40  of the interposer body  38  of each of the first and second segments  36   a ,  36   b  of the laminate interposer  36  is a plurality of top openings  54 . Similarly, formed in the bottom surface  42  of the interposer body  38  of each of the first and second segments  36   a ,  36   b  is a plurality of bottom openings  56 . Though depicted as being circularly configured, those of ordinary skill in the art will recognize that the top and/or bottom openings  54 ,  56  may be formed to have alternative shapes (e.g., square, rectangular). Exposed within each of the top openings  54  is a respective one of the top pads  48 , while exposed within each of the bottom openings  56  is a respective one of the bottom pads  50 . In the semiconductor package  10 , each exposed bottom pad  50  in each of the first and segments  36   a ,  36   b  is electrically connected to the top surface  22  of a respective one of the leads  20  of the corresponding set thereof by a solder ball  58 . It is contemplated that a conductive adhesive or solder paste may be used as an alternative to the solder balls  58 . As best seen in  FIG. 2 , such attachment is preferably facilitated such that one of the longitudinal side surfaces  44  of each of the first and second segments  36   a ,  36   b  extends in generally co-planar relation to the outermost, generally planar distal ends of the leads  20  of the corresponding set thereof. 
     In the semiconductor package  10 , the die stack  28 , wires  34 , and portions of the die pad  14 , leads  20  and first and second segments  36   a ,  36   b  of the laminate interposer  36  are encapsulated or covered by an encapsulant material which, upon hardening, forms a package body  60  of the semiconductor package  10 . Also fully covered by the package body  60  are the solder balls  58  used to effectuate the electrical connection between the first and second segments  36   a ,  36   b  of the laminate interposer  36  and the first and second sets of leads  20  of the leadframe  12 . The fully formed package body  60  has a generally quadrangular configuration and defines a generally planar top surface  62  and an opposed, generally planar bottom surface  64 . In addition to the top and bottom surfaces  62 ,  64 , the package body  60  also defines multiple side surfaces  66 . The package body  60  is preferably formed such that the bottom surfaces  18 ,  24  of the die pad  14  and leads  20  are each exposed in and substantially flush with the bottom surface  64 . The package body  60  is further formed such that the top surface  40  of the interposer body  38  of each of the first and second segments  36   a ,  36   b  is exposed in and substantially flush with the top surface  62 , with one of the longitudinal side surfaces  44  of the interposer body  38  of each of the first and second segments  36   a ,  36   b  being exposed in and substantially flush with a respective one of the side surfaces  66 . Further, each of the of the lateral side surfaces  46  of the interposer body  38  of each of the first and second segments  36   a ,  36   b  is exposed in and substantially flush with a respective one of the side surfaces  66 . The encapsulant material which ultimately hardens into the package body  60  under fills the leads  20  (i.e., covers the shelves  26  defined by the leads  20 ), thus effectively creating a mechanical interlock between the package body  60  and leads  20  embedded therein. 
     Referring now to  FIG. 3 , there is shown a pair of semiconductor packages  10  (each of which has the above-described structural attributes) as mechanically and electrically connected to each other in a stacked arrangement. To facilitate such stacking, the exposed bottom surfaces  24  of the leads  20  of each set within the upper semiconductor package  10  of the stack are electrically connected to respective ones of the exposed top pads  48  of a corresponding one of the first and second segments  36   a ,  36   b  of the laminate interposer  36  embedded in the package body  60  of the lower semiconductor package  10  in the stack. Such electrical connection is preferably facilitated through the use of solder layers  68 , each of which is captured between one of the top pads  48  of the lower semiconductor package  10  of the stack and the bottom surfaces  24  of respective ones of the leads  20  of the upper semiconductor package  10  of the stack. Though only two semiconductor packages  10  are depicted in  FIG. 3  as being stacked upon each other, those of ordinary skill in the art will recognize that the configuration of each of the semiconductor packages  10  allows for the assembly of stacks including more than two semiconductor packages  10 . Additionally, if a stack is to be formed including only the two semiconductor packages  10  shown in  FIG. 3 , it will be recognized that the top semiconductor package  10  in the stack could be modified so as to eliminate the embedded interposer  36 . 
     As indicated above, in the semiconductor package  10  of the first embodiment, two sets of the leads  20  are provided, with the leads  20  of each set extending along a respective one of an opposed pair of the side surfaces  66  defined by the package body  60 . Additionally, as is apparent from the number of exposed top pads  48  included in each of the first and second segments  36   a ,  36   b  as depicted in  FIG. 1 , thirteen leads  20  are included in each set. However, those of ordinary skill in the art will recognize that fewer or greater than thirteen leads  20  (and hence fewer or greater than thirteen top pads  48  in each of the first and second segments  36   a ,  36   b  of the laminate interposer  36 ) may be included in each set thereof without departing from the spirit and scope of the present invention. Additionally, it is further contemplated that the leads  20  may be segregated into greater or fewer than the two sets shown in  FIG. 1 , and may be arranged so as to extend along one or more of the side surfaces  66  defined by the package body  60  in any combination. As will be recognized, if the leads  20  are arranged as a single set extending along only a single side surface  66  of the package body  60 , such semiconductor package may include a laminate interposer  36  having only one of the above-described first and second segments  36   a ,  36   b . Alternatively, if multiple sets of the leads  20  are provided so as to extend along respective ones of each of the side surfaces  66  of the body  60 , the laminate interposer  36  may be formed to have a continuous, ring-like or frame-like configuration. 
     Referring now to  FIG. 4 , there is depicted a semiconductor package  100  constructed in accordance with a second embodiment of the present invention. The semiconductor package  100  comprises a laminate substrate  112  which has a generally quadrangular configuration defining four (4) peripheral edge segments. In addition, the substrate  112  defines a generally planar top surface  116 , and an opposed, generally planar bottom surface  118 . Disposed in the approximate center of the top surface  116  of the substrate  112  is a generally quadrangular die pad  120  thereof. Also disposed on the top surface  116  is a plurality of top contacts  122  of the substrate  112 . In the substrate  112 , the contacts  122  are segregated into two sets, with the contacts  122  of each set extending along and in spaced relation to a respective one of an opposed pair of the peripheral edge segments defined by the die pad  120 . Formed on the bottom surface  118  of the substrate  112  is a plurality of bottom contacts  124 . In the semiconductor package  100 , the top and bottom contacts  122 ,  124  are preferably segregated into multiple pairs, with the top contact  122  of each pair being disposed in spaced, substantial vertical alignment with the bottom contact  124  of the same pair. Though not shown, the top and bottom contacts  122 ,  124  of each pair are electrically connected to each other by conductive vias which extend through the substrate  112 . However, those of ordinary skill in the art will recognize that each top contact  122  may be electrically connected to one or more bottom contacts  124  other than for the bottom contact  124  in vertical alignment therewith. Further, the top and bottom contacts  122 ,  124  of each pair are preferably identically configured to each other, and fabricated from a suitable conductive material, as is any conductive via extending therebetween. 
     Attached to the die pad  120  of the substrate  112  is a die stack  128  of the semiconductor package  100 . The die stack  128  comprises a plurality of individual semiconductor dies  130  which are arranged in a stacked configuration. In this regard, each of the semiconductor dies  130  in the die stack  128  is secured to the semiconductor die  130  below it by a layer  132  of a suitable adhesive. Similarly, the attachment of the lowermost semiconductor die  130  in the die stack  128  to the die pad  120  is facilitated by an additional adhesive layer  132 . As shown in  FIG. 4 , four semiconductor dies  130  are depicted as being included in the die stack  128 . However, those of ordinary skill in the art will recognize that the die stack  128  may be assembled to include fewer or greater than the four semiconductor  130  dies depicted in  FIG. 4 . In the semiconductor package  100 , the pads or terminals of each of the semiconductor dies  130  of the die stack  128  are electrically connected to the top contacts  122  through the use of conductive wires  134 . The conductive wires  134  may be fabricated from aluminum, copper, gold, silver or a functional equivalent. Though not shown in  FIG. 4 , it is contemplated that that lowermost one of the semiconductor dies  130  in the stack thereof may be electrically connected to the underlying substrate  122  through the use of a flip-chip connection as an alternative to the use of the wires  134 . 
     The semiconductor package  100  further comprises a laminate interposer  136  which is mounted and electrically connected to the top contacts  122  of the substrate. As seen in  FIG. 4 , the interposer  136  comprises a first segment  136   a  which is electrically connected to each of the top contacts  122  of one of the sets thereof, and a separate second segment  136   b  which is electrically connected to each of the top contacts  122  of the remaining set thereof. The first and second segments  136   a ,  136   b  of the interposer  136  are identically configured to each other and, in the completed semiconductor package  100 , extend in spaced, generally parallel relation to each other. 
     Each of the interposer segments  136   a ,  136   b  of the interposer  136  comprises an interposer body  138  having a top surface  140 , a bottom surface  142 , an opposed pair of longitudinal side surfaces  144 , and an opposed pair of lateral side surfaces. Embedded within the interposer body  138  of each of the first and second segments  136   a ,  136   b  is a plurality of top pads  148 . Additionally, disposed on the bottom surface  142  of the interposer body  138  of each of the first and second segments  136   a ,  136   b  is a plurality of bottom pads  150 . The top and bottom pads  148 ,  150  of each of the first and second segments  136   a ,  136   b  are segregated into multiple pairs, with the top pad  148  of each pair being disposed in spaced, substantial vertical alignment with the bottom pad  150  of the same pair. As seen in  FIG. 4 , the top and bottom pads  148 ,  150  of each pair within each of the first and second segments  136   a ,  136   b  are electrically connected to each other by one or more conductive vias  152  which extend through the interposer body  138  substantially perpendicularly between the top and bottom pads  148 ,  150  of the corresponding pair. The top and bottom pads  148 ,  150  of each pair are preferably identically configured to each other, and fabricated from a suitable conductive material, as is the conductive via(s)  152  extending therebetween. Those of ordinary skill in the art will recognize that the top and bottom pads  148 ,  150  of each pair need not necessarily be in exact vertical alignment, and that some degree of juxtaposition therebetween is contemplated to fall within the scope of the present invention. 
     Formed in the top surface  140  of the interposer body  138  of each of the first and second segments  136   a ,  136   b  of the laminate interposer  136  is a plurality of circularly configured top openings  154 . Exposed within each of the top openings  154  is a respective one of the top pads  148 . In the semiconductor package  100 , each bottom pad  150  in each of the first and segments  136   a ,  136   b  is electrically connected to a respective one of the top contacts  122  of the corresponding set thereof by a solder ball  158 . As best seen in  FIG. 4 , such attachment is preferably facilitated such that one of the longitudinal side surfaces  144  of each of the first and second segments  136   a ,  136   b  extends in generally co-planar relation to a respective one of the sides or peripheral edge segments defined by the substrate  112 . Formed on each of the bottom contacts of the substrate  122  is a solder bump  168 , the use of which will be described in more detail below. 
     In the semiconductor package  100 , the die stack  128 , wires  134 , and portions of the substrate  112  and first and second segments  136   a ,  136   b  of the laminate interposer  136  are encapsulated or covered by an encapsulant material which, upon hardening, forms a package body  160  of the semiconductor package  100 . Also fully covered by the package body  160  are the solder balls  158  used to effectuate the electrical connection between the first and second segments  136   a ,  136   b  of the laminate interposer  136  and the first and second sets of top contacts  122  of the substrate  112 . The fully formed package body  160  has a generally quadrangular configuration and defines a generally planar top surface  162  and an opposed, generally planar bottom surface which contacts the top surface  116  of the substrate  112 . The package body  160  also defines multiple side surfaces  166 . The package body  160  is preferably formed such that the bottom surface  118  of the substrate  112  is not covered thereby. The package body  160  is further formed such that the top surface  140  of the interposer body  138  of each of the first and second segments  136   a ,  136   b  is exposed in and substantially flush with the top surface  162 , with one of the longitudinal side surfaces  144  of the interposer body  138  of each of the first and second segments  136   a ,  136   b  being exposed in and substantially flush with a respective one of the side surfaces  166 . Further, each of the of the lateral side surfaces of the interposer body  138  of each of the first and second segments  136   a ,  136   b  is exposed in and substantially flush with a respective one of the side surfaces  166 . 
     Referring now to  FIG. 5 , there is shown a pair of semiconductor packages  100  (each of which has the above-described structural attributes) as mechanically and electrically connected to each other in a stacked arrangement. To facilitate such stacking, the solder bumps  168  formed on the exposed portions of bottom contacts  124  of each set within the upper semiconductor package  100  of the stack are electrically connected to respective ones of the exposed top pads  148  of a corresponding one of the first and second segments  136   a ,  136   b  of the laminate interposer  136  embedded in the package body  160  of the lower semiconductor package  100  in the stack. Such electrical connection is preferably facilitated through the reflow of the solder bumps  168 . Though only two semiconductor packages  100  are depicted in  FIG. 5  as being stacked upon each other, those of ordinary skill in the art will recognize that the configuration of each of the semiconductor packages  100  allows for the assembly of stacks including more than two semiconductor packages  100 . Additionally, if a stack is to be formed including only the two semiconductor packages  100  shown in  FIG. 5 , it will be recognized that the top semiconductor package  100  in the stack could be modified so as to eliminate the embedded interposer  136 . 
     As indicated above, in the semiconductor package  100  of the second embodiment, two sets of the top contacts  122  are provided on the substrate  112 , with the top contacts  122  of each set extending along a respective one of an opposed pair of the side surfaces  166  defined by the package body  160 . The top plan view of the completed semiconductor package  100  is identical to that of the semiconductor package  10  as shown in  FIG. 1 . However, it is contemplated that the top contacts  122  may be segregated into greater or fewer than the two sets, and may be arranged so as to extend along one or more of the side surfaces  166  defined by the package body  160  in any combination. As will be recognized, if the top contacts  122  are arranged as a single set extending along only a single side surface  166  of the package body  160 , such semiconductor package may include a laminate interposer  136  having only one of the above-described first and second segments  136   a ,  136   b . Alternatively, if multiple sets of the top contacts  122  are provided so as to extend along respective ones of each of the side surfaces  166  of the body  160 , the laminate interposer  136  may be formed to have a continuous, ring-like or frame-like configuration. 
     Referring now to  FIG. 6 , there is depicted a chip stack comprising a stacked pair of identically configured semiconductor packages  200 , the electrical connection between the stacked semiconductor packages  200  being effectuated by a laminate interposer  236 . Each of the semiconductor packages  200  comprises a leadframe  212  which itself includes a die attach pad or die pad  214 . The die pad  214  has a generally quadrangular configuration defining four (4) peripheral edge segments. In addition, the die pad  214  defines a generally planar top surface  216 , and an opposed, generally planar bottom surface  218 . 
     In addition to the die pad  214 , the leadframe  212  of each of the semiconductor packages  200  comprises a plurality of leads  220 . The leads  220  of each semiconductor package  200  are segregated into two sets, with the leads  220  of each set extending along and in spaced relation to a respective one of an opposed pair of the peripheral edge segments defined by the die pad  214 . Each lead  220  preferably defines a generally planar top surface  222 , and a generally planar bottom surface  224  which is disposed in opposed relation to the top surface  222 . In addition to the top and bottom surfaces  222 ,  224 , each lead  220  further defines a shoulder or shelf  226  which is recessed relative to the bottom surface  224 , and extends in opposed relation to the top surface  222 . The shelf  226  of each lead  220  also extends to the innermost end thereof, i.e., the end disposed closest to the die pad  214 . 
     The leadframe  212  of each semiconductor package  200  is preferably fabricated from a conventional metal material, such as copper or copper alloy. The formation of the shelves  226  within the leads  220  and the top surface  216  of the die pad  214  is preferably facilitated by subjecting a metal plate from which the leadframe  212  is typically formed to a partial etching process. More particularly, each of the opposed, generally planar faces or sides of such metal plate preferably has an etch mask applied thereto in a manner wherein the subsequent application of a suitable etchant to the metal plate will effectively remove metal material therefrom as facilitates the formation of the top surface  216  of the die pad  214  and the recessed shelves  226  of the leads  220 . Such etching process may also be used to facilitate the formation of the die pad  214  and leads  220  themselves from the original metal plate, or may be implemented so as to facilitate the formation of the top surface  216  and shelves  226  subsequent to the die pad  214  and leads  220  being defined by the completion of a stamping process upon the original metal plate. 
     As is further seen in  FIG. 6 , the partial etching process to which the die pad  214  and leads  220  are subjected is preferably completed in a manner wherein the thickness of the die pad  214  between the top and bottom surfaces  216 ,  218  thereof is approximately one-half of the thickness of each of the leads  220  between the top and bottom surfaces  222 ,  224  thereof. Similarly, the thickness of each lead  220  between the top surface  222  and the shelf  226  thereof is approximately one-half of the thickness of each lead  220  between the top and bottom surfaces  222 ,  224  thereof. Thus, in the leadframe  212 , the bottom surfaces  218 ,  224  of the die pad  214  and leads  220  extend in generally co-planar relation to each other. Though the top surface  216  of the die pad  214  and the shelves  226  of the leads  220  are typically not perfectly planar due to their formation as a result of the completion of a chemical etching process, such surfaces also extend in generally co-planar relation to each other in the manner shown in  FIG. 6 . 
     Attached to the top surface of the die pad  214  is a die stack  228  of the semiconductor package  200 . The die stack  228  comprises a plurality of individual semiconductor dies  230  which are arranged in a stacked configuration. In this regard, each of the semiconductor dies  230  in the die stack  228  is secured to the semiconductor die  230  below it by a layer  232  of a suitable adhesive. Similarly, the attachment of the lowermost semiconductor die  230  in the die stack  228  to the die pad  214  is facilitated by an additional adhesive layer  232 . As shown in  FIG. 6 , four semiconductor dies  230  are depicted as being included in the die stack  228 . However, those of ordinary skill in the art will recognize that the die stack  228  may be assembled to include fewer or greater than the four semiconductor dies  230  depicted in  FIG. 6 . In each semiconductor package  200 , the pads or terminals of each of the semiconductor dies  230  of the corresponding die stack  228  are electrically connected to the leads  220  through the use of conductive wires  234 . The conductive wires  234  may be fabricated from aluminum, copper, gold, silver or a functional equivalent. 
     In each semiconductor package  200 , the die stack  228 , wires  234 , and portions of the die pad  214  and leads  220  are encapsulated or covered by an encapsulant material which, upon hardening, forms a package body  260  of the semiconductor package  200 . The fully formed package body  260  has a generally quadrangular configuration and defines a generally planar top surface  262  and an opposed, generally planar bottom surface  264 . In addition to the top and bottom surfaces  62 ,  64 , the package body  60  also defines multiple, sloped or tapered side surfaces  266 . The package body  260  is preferably formed such that the bottom surfaces  218 ,  224  of the die pad  214  and leads  220  are each exposed in and substantially flush with the bottom surface  264 . The package body  260  is further formed such that portions of the leads  220  protrude from respective side surfaces  266 , thus resulting in portions of the top surfaces  222  of the leads  220  not being covered by the package body  260  and thus exposed in the semiconductor package  200 . The encapsulant material which ultimately hardens into the package body  260  under fills the leads  220  (i.e., covers the shelves  226  defined by the leads  220 ), thus effectively creating a mechanical interlock between the package body  260  and leads  220  embedded therein. 
     In the chip stack shown in  FIG. 6 , the upper and lower semiconductor packages  200  are electrically and mechanically connected to each other by a laminate interposer  236  which is mounted and electrically connected to the exposed portions of the top surfaces  222  of the leads  220  of the lower semiconductor package  200  of the stack and to the bottom surfaces  224  of the leads  220  of the upper semiconductor package  200  of the stack. The interposer  236  comprises a first segment  236   a  which is electrically connected to each of the leads  220  of one of the sets included in each of the semiconductor packages  200 , and a separate second segment  236   b  which is electrically connected to each of the leads  220  of the remaining set included in each of the semiconductor packages  200 . The first and second segments  236   a ,  236   b  of the interposer  236  are identically configured to each other and, in the chip stack, extend in spaced, generally parallel relation to each other. 
     Each of the interposer segments  236   a ,  236   b  of the interposer  236  comprises an interposer body  238  having a top surface  240 , a bottom surface  242 , an opposed pair of longitudinal side surfaces  244 , and an opposed pair of lateral side surfaces. Disposed on the top surface  240  of the interposer body  238  of each of the first and second segments  236   a ,  236   b  is a plurality of top pads  248 . Additionally, disposed on the bottom surface  242  of the interposer body  238  of each of the first and second segments  236   a ,  236   b  is a plurality of bottom pads  250 . The top and bottom pads  248 ,  250  of each of the first and second segments  236   a ,  236   b  are segregated into multiple pairs, with the top pad  248  of each pair being disposed in spaced, substantial vertical alignment with the bottom pad  250  of the same pair. As seen in  FIG. 6 , the top and bottom pads  248 ,  250  of each pair within each of the first and second segments  236   a ,  236   b  are electrically connected to each other by one or more conductive vias  252  which extend through the interposer body  238  substantially perpendicularly between the top and bottom pads  248 ,  250  of the corresponding pair. The top and bottom pads  248 ,  250  of each pair are preferably identically configured to each other, and fabricated from a suitable conductive material, as is the conductive via(s)  252  extending therebetween. 
     To facilitate the formation of the chip stack shown in  FIG. 6 , the exposed portions of the top surfaces  222  of the leads  220  of each set within the lower semiconductor package  200  of the stack are electrically connected to respective ones of the bottom pads  250  of a corresponding one of the first and second segments  236   a ,  236   b  of the laminate interposer  236 . Such electrical connection is preferably facilitated through the use of solder layers  268 . Similarly, the exposed bottom surfaces  224  of the leads  220  of each set within the upper semiconductor package  200  of the stack are electrically connected to respective ones of the top pads  248  of a corresponding one of the first and second segments  236   a ,  236   b  of the laminate interposer  236  through the use of the solder layers  268 . In order to improve reliability, the bottom surface  264  of the package body  260  and/or the bottom surface  218  of the die pad  214  of the top semiconductor package  200  in the stack may be adhesively attached to the top surface  262  of the package body  260  of the bottom semiconductor package  200  in the stack through the use of an adhesive. Because the exposed bottom surface  218  of the die pad  214  typically has a surface finish that is not compatible with adhesives, a half etched region may be added into the bottom surface  218  of the die pad  214  in each semiconductor package  200  to provide an area that will be compatible with adhesive materials. The same holds true in relation to the bottom surface  18  of the die pad  14  of the semiconductor package  10  shown in  FIGS. 2 and 3 . Though only two semiconductor packages  200  are depicted in  FIG. 6  as being stacked upon each other, those of ordinary skill in the art will recognize that the configuration of each of the semiconductor packages  200  allows for the assembly of stacks including more than two semiconductor packages  200 . 
     As indicated above, in each of the semiconductor package  200 , two sets of the leads  220  are provided, with the leads  220  of each set extending along a respective one of an opposed pair of the side surfaces  266  defined by the package body  260 . However, those of ordinary skill in the art will recognize that the leads  220  may be segregated into greater or fewer than the two sets, and may be arranged so as to extend along one or more of the side surfaces  266  defined by the package body  260  in any combination. As will be recognized, if the leads  220  are arranged as a single set extending along only a single side surface  266  of the package body  260 , the chip stack may include a laminate interposer  236  having only one of the above-described first and second segments  236   a ,  236   b . Alternatively, if multiple sets of the leads  220  are provided so as to extend along respective ones of each of the side surfaces  266  of the body  260 , the laminate interposer  236  integrated into the chip stack may be formed to have a continuous, ring-like or frame-like configuration. 
     This disclosure provides exemplary embodiments of the present invention. The scope of the present invention is not limited by these exemplary embodiments. Numerous variations, whether explicitly provided for by the specification or implied by the specification, such as variations in structure, dimension, type of material and manufacturing process may be implemented by one of skill in the art in view of this disclosure.