Abstract:
A multi-chip semiconductor package using a lead-on-chip lead frame. The lead-on-chip package places two or more lead-on-chip dice into one package that are either attached to their own lead-on-chip lead frame or are mounted to the same lead-on-chip lead frame and subsequently wire bonded to provide electrical connection from the dice to the lead frame while in substantially the same arrangement without requiring the assembly of the multiple semiconductor dice and lead frame to be flipped for additional wire bonding attachment of the dice to the lead frame.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of application Ser. No. 09/836,609, filed Apr. 17, 2001, now U.S. Pat. No. 6,458,625 B2, issued Oct. 1, 2002, which is a continuation of application Ser. No. 09/167,258, filed Oct. 6, 1998, now U.S. Pat. No. 6,261,865 B1, issued Jul. 17, 2001. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to semiconductor packaging and, more particularly, to a method and apparatus for providing multi-chip semiconductor device (die) packages. 
     2. Statement of the Art 
     Integrated circuit devices proceed through a complicated and time-consuming fabrication routine before being completed and ready for packaging. Once this integrated circuit device passes final inspection for acceptability, it is passed to packaging. The integrated circuit device (IC) then is typically encapsulated in a protective package made of plastic, metal, ceramic material, or combinations thereof. The package is sealed to insulate the semiconductor die from the effects of temperature extremes, humidity and unintentional electrical contacts. The package has a plurality of conductive leads protruding from the encapsulation material for connecting to external devices on a printed circuit board. Various types of semiconductor packages include sealed metal cans, plastic and ceramic dual in-line packages, small outlining packages, single in-line packages, surface mount packages, and various other flat packages. 
     One type of semiconductor device assembly is a lead-on-chip (LOC) assembly as shown in the prior art drawing FIG.  1 . In drawing FIG. 1, a strip  10  of lead frames  12  is provided. Located in a center portion of each lead frame  12  is a semiconductor die  14  attached to the lead fingers  16 , typically by way of wire bonds. An example of a single semiconductor die  14  being attached to a lead frame  12  is shown in prior art drawing FIG.  2 . The wire bonds  18  connect the semiconductor die  14  to the lead fingers  16  of the lead frame  12 . Next, the lead fingers  16  are trimmed and an encapsulant material is applied over the semiconductor die  14  and portions of lead fingers  16  to completely encapsulate and seal wire bonds  18 , portions of lead fingers  16 , and semiconductor die  14 , making a single chip package. 
     There is a need to increase the semiconductor die density of a semiconductor package to include two or more semiconductor dice in one package. A high density package having multiple semiconductor dice therein increases the electronic component density on a printed circuit board. Such a high density semiconductor package also maximizes space utilization on a printed circuit board and further increases the number of active elements on the printed circuit board. U.S. Pat. No. 5,483,024, entitled “High Density Semiconductor Package,” issued Jan. 9, 1996, discloses a high density semiconductor package, an example of which is depicted in the prior art drawing FIG.  3 . In the &#39;024 Patent, two semiconductor dice  14  are fixed on the lead fingers  16  of a corresponding one of two lead frames  12 . The semiconductor dice  14  and the lead frames  12  are then encapsulated (not shown) wherein a portion of the lead frames protrude and extend from the package. Wire bonds  18  electrically connect each semiconductor die  14  to its respective lead frame  12 . An adhesive material  20  is used to bond the back surfaces of semiconductor dice  14  to one another. The high density semiconductor package illustrated in the &#39; 024  patent does achieve a multi-chip package, but there are shortcomings in the manufacture of the same. 
     One problem is that a first semiconductor die must be attached to its lead frame and then electrically connected with the wire bonds  18 . The two or more semiconductor dice  14  are adhered one to another. Once they are attached, the semiconductor dice  14  must be carried in an open basket that does not provide great rigidity that otherwise leads to poor wire bonding during the wire bonding process. A strong base support is necessary in order to provide a wire bond application that does not have weaknesses that lead to subsequent electrical or mechanical failure. 
     Another disadvantage with the &#39;024 Patent disclosure is that the semiconductor device assembly must be flipped in order to do the wire bonding on the second surface. This exposes the delicate wire bonds on the first surface of the first semiconductor die to risks of detachment that may occur due to the stressing that results while wire bonding the second surface of the second semiconductor die as the assembly is held in a less than desirable open support structure. Thus, it would be desirable to be able to use a wire bonding process where the wire bonds are made between both the first semiconductor die and the second semiconductor die and their respective lead frames from the same access point. 
     Other types of multiple chip modules have been developed in the prior art. Another example is shown in U.S. Pat. No. 5,422,435, entitled “Stacked Multi Chip Modules and Method of Manufacturing,” issued Jun. 6, 1995. The &#39;435 Patent discloses a circuit assembly that includes a semiconductor die having substantially parallel opposing first and second surfaces and at least one electrical contact mounted on the first surface. The multiple semiconductor dice are stacked one on top another or adjacent one another in a tandem position and then are electrically connected using wire bonds to a lead frame attached to a base substrate. The &#39;435 patent allows the wire bonding between multiple semiconductor dice to be performed during the same operation, but the use of a very complicated substrate with a lead frame assembly requires a larger semiconductor die than otherwise desired as well as a much more complicated assembly process of attaching the semiconductor devices and any other intervening elements in a stack arrangement to the carrier substrate that includes the lead frame. No lead fingers of the lead frame are directly connected to the semiconductor die, such as in the &#39;024 Patent previously described. Thus, the &#39;435 Patent does not have the same advantages as using a lead-on-chip configuration as is achieved in the &#39;024 Patent. 
     Another multi-chip stacked device arrangement is depicted in U.S. Pat. No. 5,291,061, entitled “Multi Chip Stacked Devices,” issued Mar. 1, 1994, and commonly assigned with the present invention. The &#39;061 Patent discloses multiple stacked die devices attached to a main substrate. Each stacked semiconductor die device is then electrically connected using wire bonds to a separate lead frame, which is not attached to the main substrate. The &#39;061 Patent suffers from the same problem previously described in that it is not easily assembled using the improved lead-on-chip lead frame and the devices are stacked one on top another so as to make wire bonding difficult or done in stages after the addition of each subsequent die device. 
     SUMMARY OF THE INVENTION 
     The present invention is directed to a multi-chip semiconductor device package using a lead-on-chip lead frame configuration. The lead-on-chip multi-chip semiconductor device package places two or more lead-on-chip semiconductor dice into one package that are either attached to their own lead-on-chip lead frame or are mounted to the same lead-on-chip lead frame and subsequently wire bonded to provide electrical connection from the dice to the lead frame while in substantially the same arrangement without requiring the assembly of the multiple semiconductor dice and lead frame to be flipped for additional wire bonding attachment of the dice to the lead frame. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic diagram of a prior art assembly of a lead frame tape; 
     FIG. 2 is a cross-sectional schematic diagram of a prior art package of a lead-on-chip assembly having a single semiconductor device; 
     FIG. 3 is a cross-sectional schematic diagram of a multi-chip lead-on-chip assembly according to the prior art; 
     FIG. 4 illustrates a cross-sectional schematic diagram of a pair of semiconductor devices mounted in tandem according to the present invention; 
     FIG. 5 is an alternative embodiment of a multi-chip lead-on-chip assembly according to the present invention; 
     FIG. 6 is an alternative embodiment of a pair of semiconductor devices attached using lead-on-chip lead frames; 
     FIG. 7 is an alternative embodiment of a plurality of semiconductor devices interconnected to a lead-on-chip lead frame structure; 
     FIG. 8 is an alternative embodiment of a pair of semiconductor devices attached to a single in-line lead-on-chip lead frame; 
     FIG. 9 depicts an alternative embodiment of the lead-on-chip multi-chip package according to the present invention; 
     FIG. 10 depicts an alternative embodiment of a lead-on-chip lead frame package according to the present invention; 
     FIG. 11 depicts a schematic diagram of a single in-line memory module utilizing a multi-chip package according to the present invention; 
     FIG. 12 depicts a schematic diagram of multiple multi-chip assemblies in a lead frame tape strip according to the present invention; and 
     FIG. 13 depicts a computer system incorporating the multi-chip package according to the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring to drawing FIG. 4, illustrated is a semiconductor device assembly  100  of the present invention. The assembly  100  comprises a conductor carrying substrate  102  and a first and second semiconductor die  104 , which are both attached to the conductor-carrying substrate  102 . Each semiconductor die  104  is further attached to the leads of a lead-over-chip (LOC) lead frame  106 , the leads of the lead frame  106  being mechanically attached, by adhesive  112  bonding either directly to the active surface of the semiconductor die  104  or through the use of an adhesively coated tape  112  located between the active surface of the die  104  and the leads of the lead frame  106 , along a portion of a respective die  104 . Next, a wire bond  108  is attached to extend between a bond pad  110  on each semiconductor die  104  and a lead of the lead frame  106 . Since a plurality of bond pads  110  are located on the active surface of a semiconductor die  104 , a plurality of wire bonds  108  will thus be provided to connect to a plurality of leads of the lead frame  106 . Next, an encapsulant material, shown by dotted line  101 , is used to seal the substrate  102 , the multiple semiconductor dice  104 , and wire bonds  108 . Subsequently, the leads of lead frame  106  are trimmed and formed into any variety of shapes, such as that depicted in FIG. 4 or, alternately, a J-shaped lead, a Z-shaped lead, an S-shaped lead, or the like. 
     Each semiconductor die  104  attaches to the carrier substrate  102  using an appropriate adhesive  112  or any other well known standard die attach processes. The adhesive  112  is selected to have an appropriate coefficient of thermal expansion (CTE) to closely match the coefficient of thermal expansion of the carrier substrate  102  and the semiconductor die  104  as well as to provide good heat-conductive properties while providing electrical insulation between the active surface of a die  104  and the substrate  102 . Adhesive  112  may alternately be an adhesively coated tape. The adhesive  112  may be composed of an electrically insulating material or a heat dissipating material such as a heat sink or combinations of both. A conductive epoxy, such as a silver type die attach epoxy, may also be employed to attach the die  104  to the substrate  102 . 
     After the wire bonding process, typically, the semiconductor device assembly  100  is encapsulated using a suitable encapsulation material, shown by outline  101 . One type of encapsulation material is molded plastic filled with inert material, which is commonly used for encapsulating semiconductor die and the like. Other encapsulation materials may also be used, such as ceramics or metal enclosures or combinations of both. The encapsulation material does not cover the outer ends of the leads of the lead frame  106 , which protrude from the encapsulation material. The protruding portions of outer ends of the leads of the lead frame  106  provide electrical connection of the semiconductor die  104  encapsulated in the semiconductor device assembly  100  to a printed circuit board (not shown). 
     Referring to drawing FIG. 5, an alternative embodiment of the semiconductor device assembly  100  is depicted. In the alternative embodiment illustrated in drawing FIG. 5 of the present invention, no carrier substrate  102  is used, but rather the two semiconductor dice  104  are attached to each other with the back side of one die  104  mating to the active surface of the other die  104 . The active surface of the semiconductor die  104  is protected by an oxide coating or other protective coating, such as the adhesive layer  112 , or adhesively coated tape  112 . This allows one semiconductor die  104  to have its active region attached to a back side of another die  104  with adhesive  112  or adhesive coated tape  112  therebetween. Wire bonds  108  are attached to individual leads of the lead frame  106  and attached to the bond pads  110  on each of the semiconductor dice  104 . The leads of the lead frame  106  are attached by adhesive  112  or adhesively coated tape  112  to an edge of the active surface of each semiconductor die  104 . The leads of the lead frame  106  are not spaced relatively close to the bond pads  110  on the semiconductor die  104 , thereby allowing for easy attachment of the wire bonds  108  during the wire bonding process. The semiconductor device assembly  100  is encapsulated in a suitable encapsulation material as shown by outline  101 . 
     Referring to drawing FIG. 6, yet an alternative embodiment of the semiconductor device assembly  100  of the present invention is depicted where a portion of the leads of a lead frame  106  is attached by adhesive  112  or adhesively coated tape  112  to a portion of the active surface of a semiconductor die  104 , while another portion of the leads of lead frame  106  is attached by adhesive  112  or adhesively coated tape  112  to the back side of another semiconductor die  104 . Alternately, well known standard die attach processes using a conductive epoxy, such as a silver based epoxy, may also be used. Wire bonds  108  are then used to electrically connect the bond pads  110  of each semiconductor die  104  to the leads of the lead frame  106 . The back side of one semiconductor die  104  is attached to a portion of the active surface of another semiconductor die  104  by a suitable adhesive  112  or adhesively coated tape  112 . The semiconductor device assembly  100  is encapsulated in a suitable encapsulation material shown by outline  101 . 
     Referring to drawing FIG. 7, yet another alternative embodiment of the semiconductor device assembly  100  of the present invention is illustrated. In this alternative embodiment of the semiconductor device assembly  100  of the present invention, two semiconductor dice  104 , located in a common horizontal plane, each have a portion of the active surface thereof attached to a portion of the back side of a third semiconductor die  104  located thereabove through the use of a suitable adhesive  112  or adhesively coated tape  112 . A portion of the leads of the lead frame  106  is attached using an adhesive  112  or adhesively coated tape  112  to a portion of the active surface of the semiconductor die  104  while another portion of the leads of the lead frame  106  is attached by an adhesive  112  or adhesively coated tape  112  to a portion of the adjacent semiconductor die  104 . A plurality of wire bonds  108  is then used to attach the bond pads  110  of each semiconductor die  104  to the leads of the lead frame  106 . In this case, preferably, the top semiconductor die  104  has bond pads  110  fabricated along the outside edges of the die  104  while the bottom two dice  104  have substantially center-aligned bond pads  110  formed thereon. If desired, the bond pads  110  on the top semiconductor die  104  may be at any location thereon; however, the wire bonds  108  may increase in length between the bond pads  110  and the leads of the lead frame  106 . The leads of the lead frame  106  attach to the edge of the active surface of each of the semiconductor dice  104  located below the upper dice  104  in the configuration. Alternatively, as illustrated in dotted lines, the leads of the lead frame  106  may be attached on the back side of the lower semiconductor die  104  with wire bonds  108  extending between the bond pads  110  of each die  104  and the leads of the lead frame  106 . The semiconductor device assembly  100  is encapsulated in a suitable encapsulation material as shown by outline  101 . 
     Referring to drawing FIG. 8, yet another alternative embodiment of the semiconductor device assembly  100  of the present invention is depicted that includes two semiconductor dice  104  and a plurality of leads of a lead frame  106 . A first semiconductor die  104  has a portion of the back side thereof attached to a portion of the upper surfaces of the leads of the lead frame  106  by a suitable adhesive  112  or adhesively coated tape  112  or well known standard die attach epoxies or conductive epoxy, such as a silver based epoxy, while a second semiconductor die  104  has a portion of the active surface thereof attached to the lower surfaces of the leads of the lead frame  106  by a suitable adhesive  112  or adhesively coated tape  112 . The first semiconductor die  104  is positioned so that an exposed portion of lead frame  106  extends a sufficient enough distance beneath the back side of the first die  104  to allow a plurality of wire bonds  108  to connect the bond pads  110  of each die  104  to the leads of the lead frame  106 . This is advantageous in that a single in-line module may be formed utilizing the advantage of placing two or more, or any desired number of, semiconductor dice  104  in a substantially adjacent configuration with the active surface of each die  104  and their associated bond pads  110  thereon facing the same direction for forming wire bonds  108  during a wire bond process. The semiconductor device assembly  100  is encapsulated in a suitable encapsulation material as shown by outline  101 . 
     Referring to drawing FIG. 9, an alternative embodiment of the semiconductor device assembly  100  of the present invention is illustrated. The semiconductor device assembly  100  includes the leads of a lead frame  106  attached through the use of a suitable adhesive  112  or adhesively coated tape  112  or other well standard die attach epoxies to the back side of the first or top semiconductor die  104  and other leads of the lead frame  106  attached through the use of a suitable adhesive  112  or adhesively coated tape  112  to a portion of the active surface of a second or bottom semiconductor die  104 . The first semiconductor die  104  has a portion of the back side thereof attached to a portion of the active surface of the second semiconductor die  104  using a suitable adhesive  112  or adhesively coated tape  112 . Such a semiconductor device assembly  100  of the present invention provides a more compact design since the profile height of the overall structure is reduced. In this embodiment of the semiconductor device assembly  100  of the present invention, preferably, the one semiconductor die  104  has bond pads  110  on the edge of the active surface thereof while the other semiconductor die  104  has generally centered or centrally-oriented bond pads  110  on the active surface thereof. Wire bonds  108  extend between the bond pads  110  of the semiconductor die  104  and the leads of the lead frame  106 . The semiconductor device assembly  100  is encapsulated in a suitable encapsulation material as shown by outline  101 . 
     Referring to drawing FIG. 10, another alternative embodiment of the semiconductor device assembly  100  of the present invention includes the leads of the lead frame  106  attached to the back side of each semiconductor die  104  using a suitable adhesive  112  therebetween or an adhesively coated tape  112  or well known standard die attach epoxies or conductive epoxies as described hereinbefore located therebetween while a portion of the back side of the first semiconductor die  104  is attached to a portion of the active surface of the second semiconductor die through the use of a suitable adhesive  112  or an adhesively coated tape  112 . In this manner, each semiconductor die  104 , the first semiconductor die and the second semiconductor die, preferably has edge-oriented bond pads  110  on the active surface thereof for the wire bonds  108  extending between the leads of the lead frame  106  and the bond pads  110  of the die  104  for a rapid wire bonding process during the wire bonding stage. In all but the embodiment shown in drawing FIG. 8, the resulting semiconductor device assembly  100  produces a dual in-line parallel lead configuration for the semiconductor die  104 . The semiconductor device assembly  100  is encapsulated in a suitable encapsulation material as shown by outline  101 . 
     Once the assembly  100  has been encapsulated, it then may be installed on a circuit board, such as shown in drawing FIG.  11 . As illustrated in drawing FIG. 11, a single inline memory module (SIMM)  120  includes a plurality of semiconductor device assemblies  100  electrically and mechanically attached to a printed circuit board  122 . Printed circuit board  122  further includes a plurality of edge connectors  124 , which are electrically connected to the plurality of semiconductor device assemblies  100 . A pair of clip holes  126  are provided on either end of circuit board  122 , and are used to securely fasten the SIMM  120  within a memory slot on a computer system. 
     Referring to drawing FIG. 12, a plurality of semiconductor device assemblies  100  are illustrated in a tape array format  130 . Each semiconductor device assembly  100  includes a pair of semiconductor dice  104 , attached one over the other denoted by the dotted line  132 . The two semiconductor dice  104  are mechanically attached to the leads of lead frames  106 , forming a portion of the tape assembly  130 . Next, the wire bonding process is performed that attaches wire bonds  108  from each semiconductor die  104  to the leads of the lead frames  106 . Then, the leads of the lead frames  106  are severed, such as shown along the dotted line  134 , during a trimming operation. The leads of the lead frames  106  are formed into a desired shape after the encapsulation of the leads of the lead frames  106  and semiconductor dice  104 . 
     Referring to drawing FIG. 13, a computer system  140  is illustrated. The computer system  140  includes one or more semiconductor device assemblies  100  manufactured according to the present invention as described hereinbefore. Computer system  140  includes a microprocessor unit  142 , which may utilize the multi-chip packaging semiconductor device assembly  100 . Computer  140  further comprises an input device  144  and an output device  146 , which are both attached to a bus system  150 . Bus system  150  is attached further to microprocessor unit  142  and to a memory system  148 . Memory system  148  may also incorporate the multi-chip semiconductor device assembly  100  according to the present invention. 
     Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions, and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.