Patent Publication Number: US-6664131-B2

Title: Method of making ball grid array package with deflectable interconnect

Description:
RELATED APPLICATIONS 
     This present application is a divisional of U.S. application Ser. No. 09/929,616, filed on Aug. 14, 2001 now U.S. Pat. No. 6,503,777, entitled “DEFLECTABLE INTERCONNECT,” which is a divisional of U.S. application Ser. No. 09/352,802, now U.S. Pat. No. 6,285,081, filed Jul. 13, 1999, entitled “DEFLECTABLE INTERCONNET.” The present application incorporates the foregoing disclosures herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates in general to integrated circuit packages and more particularly to ball grid array (BGA) packages. 
     2. Background 
     An increasing consideration in the design and use of integrated circuits is the package in which the integrated circuit (IC) resides. As ICs become more complex, and printed circuit boards become more crowded, IC packages continually need more leads or pins while their footprints consume smaller and smaller areas. In an effort to meet these demands, developers created the ball grid array (BGA) package. 
     A typical BGA package includes an IC affixed to a flexible polymide tape. A very thin conductor or wire bond connects a pad on the IC to a conductive trace on the polymide tape. The conductive trace is routed to a solder ball. The solder ball is one of an array of solder balls that connect to the opposite side of the polymide tape and protrude from the bottom of the BGA package. These solder balls interconnect with an array of pads located on a substrate, such as a printed circuit board. Accordingly, the typical BGA package electrically connects each pad on an IC to a pad on a printed circuit board. 
     Typical BGA packages have drawbacks arising from the different coefficients of thermal expansion for the IC and the polymide tape. In general, the coefficient of thermal expansion of a material corresponds to the degree in which the material will expand when heated and contract when cooled. As the IC and the polymide tape expand and contract at different rates, the wire bond experiences stress and tension. Such stress and tension may cause the wire bond to loosen or break, thereby disconnecting the IC from the printed circuit board. 
     To compensate for stress and tension caused by thermal expansion, designers have developed IC packages without wire bonds. One conventional package is a “flip chip” package. A flip chip package includes an IC affixed to a polymide tape with a thick adhesive such that the pads of the IC are positioned over a layer of conductive traces. Gaps in the adhesive provide room for a plurality of solder bumps that are used to connect the pads of the IC to the conductive traces. Similar to the typical BGA package, the conductive traces are routed to downward facing solder balls, which connect with pads of a substrate, such as a printed circuit board. 
     Accordingly, the solder bumps of the flip chip package provide an electrical connection from the pads of the IC to the layer of conductive traces. Unfortunately, several drawbacks of these packages can prevent a good electrical connection from happening. For example, the solder bump and adhesive dimensions need to be matched with a great deal of accuracy. When the solder bump diameter is small as compared to the thickness of the adhesive, the solder bump cannot connect the pads of the IC to the conductive traces. On the other hand, when the solder bump diameter is large as compared to the thickness of the adhesive, then the adhesive layer cannot sufficiently affix the IC to the tape. Furthermore, when the solder bumps are heated to cause the solder to reflow, air pockets or bubbles can form. These air pockets not only make for a poor electrical connection, but also further exacerbate the relatively narrow tolerances allowed for the solder bump and adhesive. 
     These drawbacks can cause the loss of an electrical connection between the IC pads and the conductive traces. Such loss lowers yield rates, which in turn increases the overall cost of package manufacture. 
     SUMMARY OF THE INVENTION 
     One aspect of the invention is to provide a package having an electrical connection between an IC and an interposer. The package comprises a solder bump, a solder ball, and an interconnect having a deflectable cantilever. When the IC is affixed to the interconnect, the solder bump applies surface tension to the deflectable cantilever, thereby causing the cantilever to deflect downward. When the solder bump is heated and the solder reflows, the reflowing solder releases the surface tension on the cantilever. According to one aspect of the invention, the cantilever then springs back toward its original position, within the reflowing solder. Thus, the reflowing solder partially absorbs the cantilever. 
     In one embodiment, use of a deflectable cantilever advantageously provides for greater absorption of the interconnect into the solder, thereby reducing the possible effects of air pockets. In another embodiment, use of a larger diameter solder bump advantageously provides more solder, thereby also reducing the possible effects of air pockets. 
     Another aspect of the invention relates to a ball grid array package for an integrated circuit. The ball grid array package interconnects a plurality of solder bumps on an integrated circuit with a plurality of solder balls located on the exterior of the ball grid array package. The ball grid array package comprises at least one solder bump attached to an integrated circuit and at least one solder ball which is configured to interface with a printed circuit board. The ball grid array package further comprises an interposer with at least one pocket and at least one via, wherein the pocket is configured to receive the solder bump and wherein the via is configured to receive the solder ball. 
     The ball grid array package further comprises a conductive interconnect circuit which electrically interconnects the solder ball in the via with the solder bump in the pocket. The conductive interconnect circuit further comprises at least one deflectable cantilever which extends into the pocket such that the deflectable cantilever is partially absorbed by the solder bump in the pocket. 
     One embodiment of the invention relates to an integrated circuit package that comprises at least one solder connection attached to an integrated circuit. The integrated circuit package further comprises a substrate with an opening which is configured to receive the solder connection attached to the integrated circuit. The integrated circuit package also comprises a resilient cantilever which extends into the opening such that the resilient cantilever applies pressure to the solder connection during reflow. 
     Another embodiment of the invention relates to an apparatus that comprises an interconnect layer with a first opening. The apparatus further comprises a conductor layered above the interconnect layer. The conductor comprising a deformable portion that extends into the first opening, wherein the deformable portion has resiliency that urges the deformable portion into a solder connection. 
     An additional embodiment relates to an integrated circuit package that comprises a first solder connection in communication with an integrated circuit. The integrated circuit package further comprises an interconnect layer having a first opening. The integrated circuit package also comprises a conductor layered above the interconnect layer. The conductor comprising a deflectable portion that extends into the first opening, wherein the deflectable portion has resiliency that urges the deflectable portion into the solder connection during reflow. 
     One embodiment of the invention relates to an apparatus comprising a substrate with an opening. The apparatus further comprising a conductive layer above the interconnect layer. The conductive layer comprising at least two malleable portions which extend into the opening. In another embodiment a package comprises an integrated circuit having a pad and a solder connection in communication with the pad. The package further comprises a partially deflected first conductor and a partially deflected second conductor. The partially deflected first and second conductors each at least partially absorbed by the solder connection. 
     In an additional embodiment, an apparatus comprises a substrate with an opening. The apparatus further comprises a conductive layer above the interconnect layer. The conductive layer comprising at least two flaps which extend into the opening. Yet another embodiment relates to a package that comprises an integrated circuit having a pad and a solder bump in communication with the pad. The package further comprises a deflectable conductor having partially deflected multiple flaps. The partially deflected multiple flaps are at least partially absorbed by the solder bump, wherein the absorption of the partially deflected multiple flaps is caused by the partially deflected multiple flaps moving from a deflected position toward a non-deflected position when the solder bump reflows. 
     One embodiment of the invention relates to a package for an integrated circuit that comprises an adhesive having a thickness and a solder bump having a diameter greater than the adhesive thickness. The package further comprises a conductive trace having a deflectable cantilever, wherein the deflectable cantilever deflects into a pocket when the adhesive layer affixes the integrated circuit to the conductive trace. The cantilever also springs toward its original position when the solder bump reflows. The package also comprises a solder ball and a tape attached between the conductive trace and the solder ball. 
     Another embodiment of the invention relates to a method for forming a package for an integrated circuit that comprises attaching a solder bump to an integrated circuit and forming a pocket in an interposer. The method further comprises tracing an interconnect over the interposer such that a deflectable portion of the interconnect extends over a portion of the pocket. The method also comprises affixing the integrated circuit to the interposer such that the solder bump deflects the deflectable portion of the interconnect into the pocket. 
     An additional embodiment relates to a method for forming a package for an integrated circuit. The method comprises heating a solder bump to at least partially melt the solder bump. The method further comprises allowing a deflectable portion of an interconnect to spring toward a non-deflected position of the deflectable portion. The method also comprises partially absorbing the deflectable portion into the solder of the solder bump. 
     Yet another embodiment of the invention relates to a method for forming a package for an integrated circuit. The method comprises forming an interconnect with at least two resilient conductors. The method further comprises deflecting the two resilient conductors with solder and heating the solder to at least partially melt the solder. The method also comprises allowing the two resilient conductors to spring into at least a portion of the solder. 
     One embodiment of the invention relates to a method for forming a package for an integrated circuit. The method comprises forming an interconnect with at least one deflectable flap and deflecting the flap with solder. The method further comprises heating the solder to at least partially melt the solder and allowing the flap to be absorbed by at least a portion of the solder bump. 
     Another embodiment of the invention relates to a method for forming an electrical connection between solder and a conductive material. The method comprises using solder to apply a surface tension on a deflectable portion of a conductive material, thereby deflecting the deflectable portion. The method further comprises heating the solder beyond a melting point, thereby substantially reducing the surface tension on the deflectable portion. The method also comprises partially absorbing the deflectable portion into the solder as the deflectable portion springs back toward its approximate original position. 
     An additional embodiment of the invention relates to a method for forming an electrical connection between solder and a conductive material. The method comprises using solder to deflect a cantilever and heating the solder beyond a melting point. The method further comprises partially absorbing the cantilever into the solder as the cantilever springs back toward a non-deflected position. 
     Yet another embodiment of the invention relates to a method for forming an electrical connection between solder and a conductive material. The method comprises using solder to deflect a cantilever from a first position to a second position and heating the solder beyond a melting point. The method further comprises at least partially absorbing the cantilever into the solder such that the cantilever moves from a second position to a third position. 
     One embodiment of the invention relates to a device that comprises means for affixing an integrated circuit to a conductive layer. The device further comprises means for deflecting the conductive layer and then partially absorbing the conductive layer, thereby electrically connecting the integrated circuit to the conductive layer. 
     For purposes of summarizing the invention, certain aspects, advantages and novel features of the invention have been described herein above. Of course, it is to be understood that not necessarily all such advantages may be achieved in accordance with any particular embodiment of the invention. Thus, the invention may be embodied or carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other advantages as may be taught or suggested herein. Furthermore, Other aspects and advantages of the invention will be apparent from the detailed description, the accompanying drawings and the appended claims. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The present invention is described in more detail below in connection with the attached drawings, which are meant to illustrate and not to limit the invention, and in which: 
     FIG. 1A is an exploded view of an electrical device, in accordance with one embodiment of the invention; 
     FIG. 1B is a cross-sectional view of the electrical device of FIG. 1A; 
     FIG. 2 is a cross-sectional view of a package having a deflectable cantilever, prior to attachment of an IC, according to another embodiment; 
     FIG. 3 is a top view of the deflectable cantilever of FIG. 2; 
     FIG. 4 is a cross-sectional view of the package of FIG. 2, after attachment of the IC; 
     FIG. 5 is a cross-sectional view of the package of FIG. 2, after reflow of the solder bump; 
     FIG. 6 is a cross-sectional view of a package having dual deflectable cantilevers, prior to attachment of an IC, according to yet another embodiment; 
     FIG. 7 is a top view of the dual deflectable cantilevers of FIG. 6; 
     FIG. 8 is a cross-sectional view of the package of FIG. 6, after attachment of the IC; 
     FIG. 9 is a cross-sectional view of the package of FIG. 6, after reflow of the solder bump; and 
     FIG. 10 is a top view of a multi-flap cantilever, according to yet another embodiment. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     While illustrated in the context of forming an electrical connection between an IC and an interposer, the skilled artisan will find application for the deflectable cantilever disclosed herein in a wide variety of contexts. For example, the disclosed deflectable cantilever has utility in providing an electrical connection when solder is used as a conductor, such as within a BGA package. 
     FIGS. 1A and 1B illustrate an electrical device  100 , including a package  105 , and a substrate  110 . FIG. 1A illustrates an exploded view of the electrical device  100 , while FIG. 1B illustrates a cross sectional view of the same. The electrical device  100  finds use in a wide variety of applications. For example, the package  105  can be used in any electronic circuit needing the attachment of an integrated circuit or the die  115  to the substrate  110 , such as the attachment of a microprocessor to a printed circuit board. 
     In the illustrated embodiment of FIGS. 1A and 1B, the package  105  comprises the die  115 , pads  120 , solder bumps  125 , an adhesive  130 , an interposer  135  having interconnects  140 , and solder balls  145 . The die  115  will be understood by one of ordinary skill in the art to be any integrated circuit. For example, the die  115  can be from a wide range of integrated circuit products, such as: microprocessors, co-processors, digital signal processors, graphics processors, microcontrollers, memory devices, reprogrammable devices, programmable logic devices, and logic arrays. In one embodiment, the die  115  comprises a memory device. 
     The pads  120  are shown in broken lines to indicate that they are on the reverse side of the die  115 . In one embodiment, the pads  120  electrically connect the die  115  to a variety of other devices, signals, or other “off chip” systems. It will be understood by one of skill in the art of semiconductor package design that throughout the disclosure, the number of pads  120 , solder bumps  125 , interposer  135 , interconnects  140 , solder balls  145 , etc. are illustrated for clarity with only a few examples. In reality, there may be many pads  120  on the die  115 . For example, commercially available memory devices from Micron Technology, Inc. include a 60-pin DRAM and a 100-pin SRAM, having 60 and 100 pads, respectively. 
     The pads  120  are electrically connected to the solder bumps  125 . Such connection can be by commercially available processes, such as those offered by Flip Chip Tech. In one embodiment, the solder bumps  125  are small approximate spheres of solder. However, it will be understood that a wide variety of shapes could be used. For example, the solder bumps  125  could be in the shape of a pin or a cylinder or be any type of solder connection. 
     As illustrated in FIG. 1B, the package  105  includes the adhesive  130  for affixing the die  115  to the interposer  135  and the interconnects  140 . In one embodiment, the adhesive  130  includes a number of adhesive gaps or adhesive pockets  133 , which make room for the solder bumps  125 . The adhesive  130  should also be strong enough to properly affix the die  115  to the interposer  135  and the interconnects  140 , such that the solder bumps  125  deflect a portion of the interconnects  140 , as discussed in more detail below. In one embodiment, the adhesive  130  comprises a thermal plastic polymer, however, it will be understood that the adhesive  130  can be a variety of products. For example, the adhesive  130  can comprise any thermal set, thermal plastic, or any adhesive. Such products are commercially available from various manufactures such as: Ablestik, Sumioxy, Dow Corning, and Hitachi. 
     As illustrated in FIG. 1A, the interconnects  140  are conductive paths or traces from the physical locations of the solder bumps  125  to the physical locations of the solder balls  145 . In one embodiment, the interconnects  140  are a resilient, yet malleable conductive material such that they provide spring or memory as well as conductivity. For example, when a surface tension is placed on the interconnects  140 , they should deflect in a direction corresponding to the surface tension. When the surface tension is removed, the interconnects  140  “spring” back in the direction of their original position. A wide variety of conductive materials exhibit such properties. For example, in one embodiment, the interconnects  140  include gold plated copper. However, it is understood that other conductive materials and combinations are also suitable, such as, but not limited to, copper, gold, aluminum, and various alloys. 
     The interconnects  140  can also comprise a wide variety of trace patterns, in a wide variety of sizes and layers. For example, the interconnects  140  trace from the physical positions of the solder bumps  125  to the physical positions of the solder balls  145  along a single layer. However, it is understood that multiple layers of the interconnects  140  could trace through multiple layers of the interposer  135  in order to provide sufficient physical space for the amount of the interconnects  140  needed to correspond to the amount of pads  120  on the die  115 . 
     In one embodiment, the interposer  135  provides on one side a surface upon which the interconnects  140  are traced, and on the other side a connecting point for the solder balls  145 . In one embodiment, the interposer  135  is a flexible “tape” substrate comprising insulating material, such as polymide tape. It is understood that other substrates could also be used, such as thermoplastic, thermoplast, epoxy, flex circuits, printed circuit board materials, or fiber materials. Polymide tape and analogous materials are commercially available from Shinko, Sumitomo, Compass, 3M, Casio, Packard-Hughes, Hitachi Cable, Cicorel, Shindo, Mitsui MS, and Rite Flex. 
     Further, the interposer  135  includes the vias  150  for attaching the solder balls  145  to the interconnects  140 . In one embodiment, the vias  150  correspond. to a pre-defined pattern of the solder balls  145  for the package  105 . Using pre-defined patterns for the solder balls  145  allows the output mechanisms, e.g., the solder balls  145 , to remain constant over changing patterns of the pads  120  corresponding to changing the die  115 . In such packages, the interposer  135  is customized on the side facing the interconnects  140 . For example, the interposer  135  would be customized by the tracing of the interconnects  140  from the pre-defined pattern of the vias  150  to corresponding physical locations of the pads  120  on the die  115 . 
     However, it will be understood that the pattern of the solder balls  145  need not be pre-defined. Rather, the interposer  135  could have a pre-defined pattern for the physical location of the pads  120 , and use the interconnects  140  to trace to the vias  150  connected to a customized pattern of the solder balls  145 . Alternatively, the interconnects  140  could connect customized patterns for both the pads  120  and the solder balls  145 . 
     Furthermore, in one embodiment, the interposer  135  includes deflection pockets  155 . The deflection pockets  155  exist on the interconnect-facing side of the interposer  135 . Deflectable portions, or cantilevers  160 , of the interconnects  140 , extend above the deflection pockets  155  such that when surface tension is applied to the tops of the cantilevers  160 , it causes the cantilevers  160  to deflect downward into the deflection pockets  155 . 
     In one embodiment, the package  105  is mounted on the substrate  110 , where the substrate  110  comprises a printed circuit board. However, it will be understood that the substrate  110  could comprise a wide variety of materials for a wide variety of applications. For example, in one embodiment, the substrate  110  is a printed circuit board. One of skill in the art, however, will recognize that the substrate can include a wide variety of materials including, but not limited to BT and FR 4 . 
     The substrate  110  includes conductive traces  165  electrically connected to substrate pads  170 . The substrate pads  170  are configured to correspond to, or match with, the physical location of the solder balls  145 . The conductive traces  165  trace an electrical connection from the substrate pads  170  to any number of “off chip” systems or signals. 
     FIGS. 2-5 illustrate a package  200 , according to another embodiment of the invention. In particular, FIGS. 2 and 4 illustrate a process of combining elements of the package  200  in order to deflect the cantilever  160  into a deflection pocket  155 , while FIG. 3 illustrates a top view of the cantilever  160 . FIG. 5 illustrates the package  200  after reflow of the solder in the solder bump  125 . It will be understood that for clarity, FIGS. 2-5 illustrate only one electrical connection made from the die  115 , through the solder bump  125  and interconnect  140 , to the solder ball  145 . As mentioned above, the die  115  may have many electrical connections through many solder bumps  125  and interconnects  140 , to many solder balls  145 . 
     FIG. 2 illustrates a cross-sectional view of the package  200  before attachment of the die  115 . As shown in FIG. 2, the solder bump  125  is attached to the die  115 . In addition, the interposer  135 , the interconnect  160  and the adhesive  130  are configured to receive the solder bump  125  and the die  115 . As discussed above, the interposer  135  comprises the via  150  and the deflection pocket  155 . In FIG. 2, the solder ball  145  has not yet been attached to the via  150 . However, it will be understood that the solder ball  145  could be attached and therefore, the solder ball  145  is shown in broken lines in FIGS. 2,  4 - 6 , and  8 - 9 . 
     In one embodiment, the interconnect  140  is constructed by depositing gold plated copper on to the interposer  135 . Conventional etching techniques are then used to create a desired pattern for the interconnect  140 . In certain embodiments, the interconnect  140  is traced on the die-facing side of the interconnect  140 . As discussed in further detail below, the interconnect  140  can include a cantilever  160 . The skilled artisan will recognize that the interconnect  140  can be a wide range of conductors, conductive traces or the like. Furthermore, the cantilever  160  can in certain embodiments include deflectable portions, resilient portions, deformable portions, or malleable portions of the interconnect  140 . 
     The adhesive  130  attaches the interposer  135  and the interconnect  140  to the die  115 . In one embodiment, the adhesive  130  is selected such that it can withstand a temperature of at least about  150 EC, for example, Sumioxy LOC Tape, manufactured by Occidental Chemical Corporation. 
     The adhesive layer  130  comprises at least one adhesive pocket  133 . In one embodiment, the adhesive pocket  133  extends through the adhesive layer  130  and partially into the interposer  135 . In other embodiments, the adhesive pockets  133  are holes that extend through the adhesive layer  130  and the interposer  135 . The adhesive pocket  133  is dimensioned to receive the solder bump  125 . In one embodiment, the adhesive pocket  133  is constructed by selectively applying adhesive to the interconnect  140  and the interposer  135  using known techniques. In other embodiments, the adhesive pocket  133  is constructed by screen printing, drilling or punching the adhesive layer  130  or interposer  135 . 
     FIG. 3 illustrates a top view of the interposer  135  and the interconnect  140 . In FIG. 3, the interposer  135  includes the deflection pocket  155  surrounded by the interconnect  140 . In one embodiment, the deflection pocket  155  is approximately square in shape and does not extend entirely through the interposer  135 . However, it will be understood that a wide variety of shapes could be used to form the deflection pocket  155 , for example, approximately circular, oval, or polygonal shapes could be used. Furthermore, it will be understood that a wide variety of shapes of the interconnect  140  could be used to surround the deflection pocket  155 . For example, the shapes of the interconnect  140  could either correspond to, or be different from, the wide variety of shapes of the deflection pocket  155 . For example, the deflection pocket  155  could be polygonal in shape and be surrounded by the interconnect  140  in a circular fashion. 
     Also, the deflection pocket  155  could extend entirely through the interposer  135  thereby creating another hole or via in the interposer  135 . While such a punched-through deflection pocket  155  is typically easier to manufacture, it can expose the interior of the package  200  to environmental conditions after the die  115  and the solder ball  125  are attached. 
     FIG. 3 also illustrates the cantilever  160  extending over the deflection pocket  155 . In one embodiment, the cantilever  160  extends approximately half the distance across the deflection pocket  155 . However, it is understood that one skilled in the art could manipulate the flexibility and spring constant of the cantilever  160  by adjusting the width and length thereof. The pattern of the interconnect  140  is shown deposited on a portion of the interposer  135  and over the defection pocket  155 . It will be understood by one of skill in the art that the pattern of the interconnect  140  can be adapted for a variety of patterns and situations. 
     FIG. 4 illustrates a cross-sectional view of the package  200 , after the die  115  and the solder bump  125  are affixed to the adhesive  130 . In one embodiment, the diameter of the solder bump  125  is larger than the thickness of the adhesive  130 , and therefore, the solder bump  125  applies a surface tension to the cantilever  160 . The surface tension deflects the cantilever  160  downward into the deflection pocket  155 . In one embodiment, the resilient deflected cantilever  160  applies a pressure on the solder bump  125  that is directed towards the surface of the solder bump  125 . 
     FIG. 5 illustrates a cross-sectional view of the package  200  after reflow of the solder in the solder bump  125 . When the solder in the solder bump  125  reflows, it applies less surface tension to the cantilever  160 , allowing the cantilever  160  to spring back in the direction of the original position of the cantilever  160 . As the cantilever  160  returns, it is at least partially absorbed by the reflowing solder. Thus, in one embodiment, the cantilever  160  applies an inwardly directed pressure to the solder bump  125  the urges the cantilever  160  into the solder bump  125 . 
     It will be understood that the die  115 , the solder bump  125 , the adhesive  130 , the interposer  135 , the interconnect  140 , and the solder ball  145 , could have a variety of sizes and thicknesses. As mentioned, the die  115  can be from a wide range of integrated circuit products. For this reason, the type of integrated circuit product will dictate the thickness of the die  115 . In one embodiment, the die  115  is a dynamic memory device with a thickness of approximately  280  microns. Also, in one embodiment, the thickness of the interconnect  140  and the cantilever  160  is approximately 15 microns, the thickness of the interposer  135  is approximately 48 microns, and the diameter of the solder ball  145  is approximately 400 microns. 
     One advantage of the cantilever  160  is that the diameter of the solder bump  125  and the thickness of the adhesive  130  can vary over wider ranges. For example, when the diameter of the solder bump  125  is larger than the thickness of the adhesive  130 , the cantilever  160  is deflected into the deflection pocket  155 . Thus, in order to create an electrical connection, the diameter of the solder bump  125  in the package  200  can be as thick or thicker than the adhesive  130 . In one embodiment, the diameter of the solder bump  125  is approximately 200 microns and the thickness of the adhesive  130  is approximately 176 microns. 
     The embodiment of FIGS. 2-5 thus provides the package  200  that has electrical connections from the pads  120  on the die  115 , through the solder bumps  125  and the interconnects  140 , to the solder balls  145 . The solder bumps  125  deflect the cantilevers  160  when the die  115  is affixed to the adhesive  130 . During reflow, the cantilevers  160  spring back toward their original position and are thereby partially absorbed by the solder bump  125 . Deflection allows for relaxed tolerance requirements between the diameter of the solder bump  125  and the thickness of the adhesive  130 . Partial absorption allows for formation of an electrical connection. These characteristics improve yield rates and thereby decrease the cost of package manufacture. 
     FIGS. 6-9 illustrate a package  600  according to yet another embodiment of the invention. In particular, FIGS. 6 and 8 illustrate a process of combining elements of the package  600  in order to deflect dual cantilevers  605  and  610  into a deflection pocket  615 , while FIG. 7 illustrates a top view of the dual cantilevers  605  and  610 . FIG. 9 illustrates the package  600  after reflow of the solder in the solder bump  125 . It will be understood that for clarity, FIGS. 6-9 illustrate only one electrical connection made from the die  115 , through the solder bump  125  and interconnect  140 , to the solder ball  145 . As mentioned above, the die  115  may have many electrical connections through many solder bumps  125  and interconnects  140 , to many solder balls  145 . 
     Accordingly, FIG. 6 illustrates a cross-sectional view of the package  600  before attachment of the die  115 . As shown in FIG. 6, the solder bump  125  is attached to the die  115 . Furthermore, the interposer  135  includes the interconnect  140  traced on at least the die-facing side of the interposer  135 . In one embodiment, the interconnect  140  is deposited on the interposer  135 . Typical etching techniques are used to create a desired pattern for the interconnect  140 . 
     The interposer  135  also includes the via  150  and the deflection pocket  615 . In one embodiment, the solder ball  145  has not yet been attached to the via  150 . The adhesive  130  is then added in order to cover both the interposer  135  and the interconnect  140 . The adhesive pockets  133  are added, punched, drilled and screen printed. In certain embodiments, the pocket  615  and the via  150  comprise openings formed in the interposer  135 . 
     FIG. 7 illustrates a top view of the interposer  135  and the interconnect  140 . The interposer  135  includes the deflection pocket  615  surrounded by the interconnect  140 . In one embodiment, the deflection pocket  615  is approximately square in shape and does not extend entirely through the interposer  135 . However, it will be understood that a wide variety of shapes could be used to form the deflection pocket  615 . Furthermore, it will be understood that a wide variety of shapes of the interconnect  140  could be used to surround the deflection pocket  615 . For example, the deflection pocket  615  could be polygonal in shape and be surrounded by the interconnect  140  in a circular fashion. 
     FIG. 7 also illustrates the deflection pocket  615  as an alternative to the deflection pocket  155  of FIGS. 2-5. The deflection pocket  615  extends through the interposer  135 . It will be understood that a skilled artisan would recognize that the deflection pocket  615  could be used with the embodiment of FIGS. 2-5, and likewise, the deflection pocket  155  could be adapted for use in FIG.  6 . 
     FIG. 7 also illustrates the dual cantilevers  605  and  610  extending over the deflection pocket  615  from opposite sides. Each of the dual cantilevers  605  and  610  is similar in composition and material considerations as those mentioned in reference to the cantilever  160 . In one embodiment, each of the dual cantilevers  605  and  610  has a length which is approximately half the diameter or width of the deflection pocket  615 . In other embodiments, the first cantilever  605  may be approximately a third of the width of the deflection pocket  615  while the second cantilever  610  may be approximately two-thirds the width of the deflection pocket  615 . In yet other embodiments, the dual cantilevers  605  and  610  may each be less than approximately half the width of the deflection pocket  615 . 
     It will be understood that a skilled artisan would recognize a wide range of lengths and designs for the dual cantilevers  605  and  610 . For example, directly opposite cantilevers may have a lower bound on their lengths being dictated only by the desire for some deflection therein. Moreover, the dual cantilevers  605  and  610  may be of different lengths in order to exhibit different deflection distances. Thereby, the dual cantilever  605  and  610  would be absorbed into different areas of the solder bump  125 . 
     Also, the dual cantilevers  605  and  610  could have lengths longer than half the diameter, or half the width, of the deflection pocket  615  by being offset from direct opposition of each other. In addition to the embodiments mentioned above, it is understood that a skilled artisan may use other designs for the dual cantilevers  605  and  610  directed to needs recognizable to such an artisan. Also, it is understood that one skilled in the art could manipulate the flexibility and spring constant of each of the dual cantilevers  605  and  610  by adjusting the widths and lengths thereof. 
     FIG. 8 illustrates a cross-sectional view of the package  600 , after the die  115  and the solder bump  125  are affixed to the adhesive  130 . In one embodiment, the diameter of the solder bump  125  is larger than the thickness of the adhesive  130 , and therefore, the solder bump  125  applies a surface tension to the dual cantilevers  605  and  610 . The surface tension deflects the dual cantilevers  605  and  610  downward into the deflection pocket  615 . 
     FIG. 9 illustrates a cross-sectional view of the package  600  after reflow of the solder in the solder bump  125 . When the solder in the solder bump  125  reflows, it applies less surface tension to the dual cantilevers  605  and  610 , allowing each of the dual cantilevers  605  and  610  to spring back in the direction of their original position. As the dual cantilevers  605  and  610  return, they are at least partially absorbed by the reflowing solder. Partial absorption creates an electrical connection in spite of possible air pockets or bubbles. 
     Similar to FIGS. 2-5, use of the dual cantilevers  605  and  610  in the package  600  allows the diameter of the solder bump  125  and the thickness of the adhesive  130  to have a more relaxed relationship. For example, when the diameter of the solder bump  125  is larger than the thickness of the adhesive  130 , the dual cantilevers  605  and  610  are deflected into the deflection pocket  615 . Thus, in order to create an electrical connection, the diameter of the solder bump  125  in the package  600  need only be as thick as the adhesive  130 . On the other hand, the diameter of the solder bump  125  may be as large as the maximum deflection of the dual cantilevers  605  and  605 . In one embodiment, the diameter of the solder bump  125  is approximately  200  microns and the thickness of the adhesive  130  is approximately  176  microns. 
     The embodiment of FIGS. 6-9 thus provides the package  600  that has electrical connections from the pads  120  on the die  115 , through the solder bumps  125  and the interconnects  140 , to the solder balls  145 . The solder bumps  125  deflect the dual cantilevers  605  and  610  when the die  115  is affixed to the adhesive  130 . During reflow, the dual cantilevers  605  and  610  spring back toward their approximate original position and are thereby partially absorbed by the solder bumps  125 . Deflection allows for relaxed tolerance requirements between the diameter of the solder bumps  125  and the thickness of the adhesive  130 . Partial absorption allows for formation of an electrical connection. These characteristics improve yield rates and thereby decrease the cost of package manufacture. 
     FIG. 10 illustrates a top view of yet another embodiment of the invention. Similar to FIGS. 3 and 7, FIG. 10 includes the interposer  135  having a deflection pocket  1010  (shown in broken lines) surrounded by the interconnect  140 . As with the deflection pocket  155 , it will be understood that the deflection pocket  1010  could be many shapes and the interconnect  140  may or may not correspond to such shapes. Furthermore, the deflection pocket  1010  could extend entirely through the interposer  135 . However, in one embodiment, the deflection pocket  1010  is approximately square and extends only partially through the interposer  135 . 
     As further illustrated by FIG. 10, the interconnect  140  includes a series of flaps  1005  extending over and partially covering the deflection pocket  1010 . The flaps  1005  are made by depositing the interconnect  140  over the deflection pocket  1010  and then etching openings  1015  therein. The deposition and etching are done by typical methods known to one of ordinary skill in the art of package design. The openings  1015  define the shape of the flaps  1005  and provide the ability of the flaps  1005  to deflect downward into the deflection pocket  1010 . It will be understood that the flaps  1005  could be a wide variety of shapes and sizes. However, in one embodiment, the flaps  1005  comprise four triangular-shaped flaps  1005 , with each of the flaps  1005  having one vertice in the approximate center of the deflection pocket  1010 . 
     Although the foregoing invention has been described in terms of certain preferred embodiments, other embodiments will be apparent to those of ordinary skill in the art. For example, a wide variety of shapes and sizes of both the pockets and corresponding deflectable interconnect portions may be combined to provide electrical connections within a package. Additionally, other combinations, omissions, substitutions and modifications will be apparent to the skilled artisan, in view of the disclosure herein. Accordingly, the present invention is not intended to be limited by the recitation of the preferred embodiments, but is instead to be defined by reference to the appended claims.