Patent Application
20090001573
This invention is in the field of integrated circuit packaging, and more particularly to design of high-density substrate designs for OSP surface finishes on BGA IC packages.
As in every aspect of integrated circuit processing, packaging methods have of necessity been greatly affected as critical dimensions decrease and circuit speed and complexity increases. Packaging methods which are compatible with high density IC's include the use of the Ball-Grid Array (BGA) substrate. The basic process flow of the packaging is illustrated in
Contacts to certain features of the copper layers of the substrate, such as the bond fingers and the solder ball pads, are facilitated by plating or deposition of a conducting layer thereon. Ni—Au plating has traditionally been utilized. However, improved reliability and crack and drop resistance of the solder balls are achieved by using Organic Solderability Preservative (OSP) coating between the substrate and solder balls, known as “ball pad OSP”, on the substrate backside. OSP as used in BGA packages is described in “The study of OSP as reliable surface finish of BGA substrate”, Chang, D. Bai, F. Wang, Y. P. Hsiao, C. S., Siliconware Precision Ind. Co. Ltd., Taichung, Taiwan; Electronics Packaging Technology Conference, 2004. EPTC 2004.
The combination of Ni/Au plating on the front side and the OSP coating necessitates modifications to the substrate connection layout, i.e., to the connectivity between the tie bars and a grounded feature, which is generally the mold gates.
An important aspect of the wire bonding process of
A problem exists for the high density line/space PCB/substrate designs with ball pad OSP, which do not have a direct circuit connection on the top copper layer from the bond fingers to the tie bar and therefore to the grounded mold gate, whereas the layout of the bottom copper layer connects the ball pads to the bottom side tie bar. This substrate design allows for verification of via quality by inducing electrolytic Ni/Au plating current from the bottom, which will induce plating on the top side only when the copper plating on the electrically connected via to the Ni—Au plating region in question is of good quality. (Verification of via quality has become necessary, since historically, use of poor drill bits for creating the via holes could cause uneven breaking of the resin, which could in turn result in incomplete copper plating and poor electrical connectivity. As a result, the bond finger connected to that via hole would be improperly Ni—Au plated.) However, not having the bond fingers connected to the top side tie bar prevents a closed circuit which would allow for the automatic wire bonding circuit integrity check. Currently, either the sensitivity of the bond integrity check is reduced, or the function turned off entirely. Therefore, it is possible that broken wires or incomplete bonds will not be located, and go on to subsequent processes. To avoid this problem, either visual inspection or testing of 100% of the circuits is required.
A method for providing an indirect electrical connectivity pathway between the grounded feature, generally the mold gate, and the bond fingers for ball pad OSP surface finish designs, which would simultaneously enable wire bonding circuit integrity check, and also enable verification of via quality by inducing electroplating current from the substrate backside only, would be an important improvement in high density BGA IC packaging.
The present invention provides: A BGA integrated circuit package comprising:
1) a BGA substrate having conducting bond fingers and a grounded feature on a first side thereof; 2) an IC die electrically connected to the conducting bond fingers with wire bonds; the BGA substrate configured to be formed into a singulated unit with the IC die; wherein the BGA substrate does not have direct electrical connection on the first side thereof between the bond fingers and the grounded feature; 4) the BGA substrate including an indirect electrical connection pathway from each wire bond to the grounded feature that enables electrical integrity testing for the wire bonds; the indirect electrical connection pathway configured so that at least a portion of each indirect electrical connection pathway is not present on the singulated unit.
The invention further includes a method for bonding an integrated circuit (IC) die to a BGA substrate, said BGA substrate configured to be formed into a singulated unit with said IC die, said method including testing electrical integrity of a wire bond between a) a bond finger on a first side of said BGA substrate and b) a bonding pad on said IC die, wherein said substrate does not have direct electrical connections on said first side between said bond fingers and a grounded feature on said first side; the method comprising the steps of:
applying a voltage through said wire bond on said BGA substrate to said grounded feature, through an indirect electrical connection pathway at least a portion of which is not present on said singulated unit; and
measuring if there is current flow through said pathway.
The invention further includes an integrated circuit (IC) die mounted on and packaged with the BGA substrate, formed by a method comprising the steps of:
a shows a portion of a PCB/BGA substrate strip layout, top view.
b shows a detailed portion of
c shows a portion of a PCB/BGA substrate strip layout, bottom view.
d shows a detailed portion of
a shows a portion of a high density (Line and Space) and Ball Pad OSP surface finish PCB/substrate strip layout, from the top view.
b shows a detailed region of
c shows the same portion of a high density (Line and Space) and Ball Pad OSP surface finish PCB/substrate strip layout, from the bottom view.
d shows a detailed region of
a illustrates the lack of circuit connectivity through the wire bonds if there is no bypass connection.
b illustrates our inventive solution to the lack of circuit connectivity shown in
a shows a portion of a traditional PCB/substrate strip layout, from the top view. Regions 200 each comprise the substrate portion of a single BGA IC package body. Regions 200 are bordered by conducting Top Tie Bars 205. Mold gates 210 are connected to top tie bars 205, and are in a region outside BGA package body 200. When the packages are separated, also known as singulated, tie bars 205 are separated from substrate regions 200. As described in
b shows a detailed region of
a shows a portion of a high density (Line and Space) and Ball Pad OSP surface finish PCB/substrate strip layout, from the top view. Regions 400 each comprise the substrate portion of a single BGA IC package body. Regions 400 are bordered by conducting Top Tie Bars 405. Mold gates 410 are connected to top tie bars 405, and are in a region outside BGA package body 400.
b shows a detailed region of
During the Ni—Au plating of the frontside, while the solder ball pads are protected, it is preferred to send the electroplating current from the back side. Assuming the vias are complete and well plated, the current will pass through to the front side and the Ni—Au plating will proceed accordingly. If there are incomplete or poorly copper-plated vias, the electroplating current will be interrupted and Ni—Au plating will not occur properly on regions connected to the poor via. Sending the plating current from the back only, therefore, proves a test of via quality. For this reason, there are no traces electrically connecting the frontside tie bar with the vias. During Ni—Au plating, the package is held by a clamp through which the electroplating current is passed. This clamp contacts both the top and the bottom tie bars. Therefore, if the top tie bars were electrically connected to the bond fingers, electroplating current would pass current directly from the frontside and plate whether or not the vias were good. Thus, there would be no indication of via quality. In contrast, in the traditional case where Ni—Au is plated on both the front side and the back side, the symmetry of the arrangement allows for via quality testing if either the top or the bottom tie bar, but not both, are connected to the vias. Since wire bond integrity testing is straightforward if the Ni—Au electroplating current was passed to the vias from the front side, this method was traditionally used. The necessity of inducing the electroplating from the back side for the OSP design causes the complication in wire bond integrity testing which is addressed by the present invention.
c shows the same portion of a high density (Line and Space) and Ball Pad OSP surface finish PCB/substrate strip layout, from the bottom view, including bottom side tie bars 440, and
The design difference for the high density (Line and Space) and Ball Pad OSP surface finish PCB/substrate strip layout as described above, wherein there is no connection between the top side tie bars (which are connected to the mold gates) and the bond fingers, prevents the wire bond integrity check from being performed. We have developed a method to overcome this problem so as to enable the wire integrity check for the high density (Line and Space) and Ball Pad OSP surface finish PCB/substrate strip layout.
Our method provides a temporary indirect electrical connection pathway from a grounded feature, generally the mold gate, and top tie bar, to the bond fingers on the top side. This temporary connection will be severed when the packages are singulated, i.e., at least a portion of the indirect electrical connection pathway is not present on the singulated unit, so as to avoid grounding of the IC bonding pads. Therefore the connection is called a dummy connection. In order to insure that the temporary connection is severed when the packages are singulated, a portion of the connection is positioned outside the BGA IC body package. Since the temporary connection is no longer present for the final packaged IC product, the inventive product may be termed an intermediate product, which is found at an intermediate step in the processing.
a, showing the top side as in
b illustrates a preferred embodiment of our inventive solution to the lack of circuit connectivity shown in
In step 600, an integrated circuit die with bonding pads is mounted on a package substrate, which may be a BGA or FBGA substrate. The substrate is provided with conducting bond fingers on the top side, tie bars (also known as bus lines) on the top and bottom sides, solder ball pads on the back side, conducting via holes from the front side to the back side, conducting traces connecting the bond fingers with via holes and also connecting the via holes and solder ball pads with the bottom side tie bar. Also provided on the substrate are bypass via holes outside the BGA IC package body, according to the inventive method described herein.
In step 605, an automated wire bonding machine attaches one end of a bonding wire to a bonding pad, generally with a ball bond, on the integrated circuit.
In step 607, the automated wire bonding machine attaches the other end of the bonding wire to a bond finger, generally with a wedge bond, on the BGA package substrate. Note that it is possible to reverse steps 605 and 607, though that is not commonly done.
In step 610, the wire bonding machine applies a voltage pulse through the bonded wire and measures if there is any current flow between the wire bond and the grounded feature, generally the mold gate. If there is current flow, the wire bond being tested is determined to be good. If there is an incomplete wire bond, resulting in an open circuit, there is no current flow.
In step 615, if a wire bond is determined to be incomplete, the wire bonding machine stops and requests operator assistance.
In step 620, this procedure is followed for all wire bonds which connect the IC to the substrate.
The completion of the IC packaging includes:
1) forming a package mold on the substrate;
2) attaching solder balls to the bottom side of the substrate; and
3) singulating the substrate.
Upon singulation, the dummy bypass via and tie bars are severed from the IC package body, so that there is no remaining electrical connection from the IC bonding pads and bond fingers to ground, and therefore at least a portion of the indirect electrical connectivity pathway comprised in part by the dummy bypass via does not remain for the singulated unit.
Our inventive method enables electrical integrity testing of wire bonds for IC packaging substrates which do not have a direct top side connection between bond fingers and top side tie bars and/or mold gates. The exemplary substrate type described in the particular embodiments disclosed herein is high density (Line/Space) BGA substrate design with ball pad OSP finish. It should be apparent to those skilled in the art that modifications can be made to those specifics without departing from the inventive concept. By way of example, the method and structure can be applied to FBGA (Fine Pitch Ball Grid Array) packages as well as more standard BGA, Chip Scale Packaging (CSP), (package only 10-20% larger than die) and system scale PCB's. The technique is applicable to any BGA-type package which has solder balls on bottom and is over-molded on the top side with some resin, even if not entirely over-molded. The scope of the invention should be construed in view of the claims.
