Abstract:
The specification describes a high density I/O IC package in which the IC chip is bonded to a silicon intermediate interconnection substrate (IIS), and the IIS is wire bonded to a printed wiring board. This marriage of wire bond technology with high density I/O IC chips results in a low cost, high reliability, state of the art IC package.

Description:
FIELD OF THE INVENTION 
     This invention relates to ball grid array packages with high density interconnections. 
     BACKGROUND OF THE INVENTION 
     Wire bonding has been used in integrated circuit packaging since the inception of IC technology. Wire bonding techniques and wire bonding machines have been refined to the point where wire bonds are relatively inexpensive and are highly reliable. However, wire bonds are rapidly being replaced by more advanced packaging approaches, partly because wire bonds require greater pitch than is available in many state of the art packages. 
     Among the advanced IC packaging approaches is silicon on silicon technology. Use of silicon interconnection substrates is becoming attractive for high density packages wherein high pin count IC chips are flip chip bonded to a silicon intermediate interconnect substrate, and the silicon intermediate interconnect substrate is in turn ball bonded or flip-chip bonded to a printed wiring board. In many cases these packages use recessed chip arrangements to reduce the package profile. 
     In these advanced packaging approaches, interconnection pitches can be very small. The earlier technology of wire bonding has been left behind since the high density of I/O&#39;s in current IC chips presents a challenge to the capacity of wire bond techniques. However, largely due to the high I/O density of state of the art IC chips, packaging yield using advanced packaging techniques may suffer, and the complexity of the packaging process is increased. As a result the overall cost per bond may be relatively high. The low cost and high reliability of wire bonds makes them attractive if ways can be found to adapt wire bonding to packaging high density I/O chips. 
     STATEMENT OF THE INVENTION 
     We have developed an interconnection approach that utilizes wire bonding with high density I/O chips. A typical high density I/O IC chip has an area array of I/O sites that are not easily adapted for wire bonding but can be flip-chip bonded to a silicon intermediate interconnect substrate (IIS) with high reliability and exceptional thermomechanical matching. The silicon IIS is made larger than the silicon IC chip. The high density I/O pattern interconnecting the IC chip and the IIS is fanned out on the silicon IIS to perimeter sites that are then wire bonded to the next board level. This approach marries, in a simple and efficient way, the low cost and high reliability of wire bonds with the high density I/O patterns of state of the art IC chips. 
     In the preferred embodiment of the invention the fan out layer on the silicon IIS has bare runners, i.e. the conventional polyimide layer is eliminated. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     FIG. 1 is a plan view of a high density I/O integrated circuit chip; 
     FIG. 2 is a plan view of the IIS of the invention; 
     FIG. 3 is a section view of a completed package with the IIS of FIG. 2; 
     FIG. 4 is a section view of a conventional coated IIS with under bump metallization; and 
     FIG. 5 is a similar view of a simplified IIS according to the invention. 
    
    
     DETAILED DESCRIPTION 
     State of the art IC chips are now produced with I/O counts that exceed 400. When the number of required interconnections required is this large, and are arranged in an area array, wire bond interconnections are difficult if not impractical. Conventional wire bond interconnection techniques, while inexpensive and reliable, cannot meet the challenge of interconnecting these IC arrays of dense interconnections, so the art typically resorts to more advanced and more expensive techniques. 
     An IC chip with a large area array of interconnection sites is shown in FIG.  1 . The IC chip is designated  11 , and the area array interconnections sites are designated  12 . The length of the area array, which is approximately the length of the chip, is designated L 1 . The interconnection sites are shown as square but can be round. In the IC chip design of FIG. 1, there are 233 interconnection sites, which is fewer than normal for clarity in illustration. In state of the art IC chips, the combined number of I/O interconnections may be much larger, e.g. greater than 400, which more closely represents the interconnection challenge that is addressed by this invention. The effective pitch of these I/O interconnections, i.e. the spacing between interconnections (pads, runners), at the chip edge, may be in the range 20-40 μm, i.e. less than the pitch of typical wire bonded arrays. 
     The area array shown in FIG. 1 has a symmetrical array of interconnection sites filling the entire chip area. Other arrangements are equally adapted to the invention. The term area array is generally used to distinguish from edge arrays or perimeter arrays, and is defined as having interconnection sites in the area of the chip removed from the edge, e.g. at least one pitch length interior of any edge interconnection site. This definition, and this invention, includes chips with two rows of interconnection sites located around the edge of the chip. Also, in principle, the invention applies to any configuration which can be flip-chip bonded, including in some cases IC chips with edge arrays. 
     The essence of flip-chip assembly is the attachment of semiconductor IC substrates “upside down” on an interconnection substrate such as a silicon wafer, ceramic substrate, or printed circuit board. The attachment means is typically solder, in the form of balls, pads, or bumps (generically referred to hereinafter as bumps). Solder bumps may be applied to the semiconductor chip, or to the interconnection substrate, or to both. In the bonding operation, the chip is placed in contact with the substrate and the solder is heated to reflow the solder and attach the chip to the substrate. For successful bonding, it is necessary that the sites to which the solder is bonded it wettable by the solder. 
     The metal interconnection pattern typically used for integrated circuits and printed wiring boards is aluminum. While techniques for soldering directly to aluminum have been tried it is well known and accepted that aluminum is not a desirable material to solder. Consequently the practice in the industry is to apply a metal coating on the aluminum contact pads, and apply the solder bump or pad to the coating. The metal coating is typically referred to as  U nder  B ump Metallization (UBM). 
     The metal or metals used in UBM technology must adhere well to aluminum, be wettable by typical tin solder formulations, and be highly conductive. A structure meeting these requirements is a composite of chromium and copper. Chromium is deposited first, to adhere to the aluminum, and copper is applied over the chromium to provide a solder wettable surface. Chromium is known to adhere well to a variety of materials, organic as well as inorganic. However, solder alloys dissolve copper and de-wet from chromium. Therefore, a thin layer of copper directly on chromium will dissolve into the molten solder and then the solder will de-wet from the chromium layer. To insure interface integrity between the solder and the UBM, a composite or alloy layer of chromium and copper is typically used between the chromium and copper layers. 
     As used herein, the term interconnection site is intended to refer to sites that are ball or bump bonded to another substrate and is used to distinguish from bonding pads that are wire bonded. As described above the interconnection sites generally are provided with under bump metallization. Typically the bonding pads are simple aluminum pads. 
     The improved interconnection approach, according to the invention, is to use a silicon IIS for the second interconnect level, i.e. the substrate to which the IC chip is flip-chip bonded. A typical IIS following this approach is shown at  15  in FIG.  2 . Here the IC chip  11  is shown flip-chip mounted on the IIS  15 . The IC interconnection sites  12  of FIG. 1 are mated to IIS interconnection sites (not visible) on the IIS. An array of wire bonding pads  16  is provided along the outer edges of the IIS  15 . These wire bonding pads are connected to the IIS interconnection sites via runners  17 . The number of bonding pads may or may not match the number of IC interconnection sites. The pitch of the sites on the outer array is preferably greater than 40 μm, e.g. approximately 50 μm, to allow for wire bonding these sites to another level. The length of the array is designated L 2  in the figure. 
     FIG. 3 shows IC chip  11  of FIG.  1  and IIS  15  of FIG. 2 assembled together and mounted on a printed wiring board  21 . The IIS is preferably die bonded to the printed wiring board. Interconnections between the array  16  of IIS  15  and an array of bonding pads  22  on the printed wiring board are made with wire bonds  25 . The bonding pads are typically copper pads plated with nickel and gold, and the wire bonds are typically made with gold wires. 
     The printed wiring board  21  is shown in FIG. 3 ball bonded via solder balls  27  to a system printed wiring board  28 . The package of FIG. 3 will be recognized by those skilled in the art as a ball grid array (BGA) package but with the unusual features that the chip is mounted on a silicon IIS, and the silicon IIS is wire bonded to the BGA board. 
     Use of wire bonding between the IIS and the next board level simplifies the processing of the IIS. In a prior art silicon on silicon package, where the IIS is ball or bump bonded to the next level, the IIS is provided with a polyimide layer. Also the array of bonding pads  16  in the prior art arrangement are interconnection sites that are provided with UBM. The polyimide layer requires patterning to accommodate the under bump metallization. This is illustrated in FIG. 4, with the edge portion of the IIS shown at  41 , the conductive runner (e.g.  17  of FIG. 2) at  42 , the patterned polyimide layer at  43 , and the under bump metallization at  44 . The simplified structure according to the invention is shown in FIG. 5, where the terminal end of runner  42  simply has an aluminum bonding pad  46 . In this simplified process the UBM on the interconnection sites under the IC chip may be formed without using a polyimide layer. 
     The interconnection between the board level  21  and the system board level is preferably a ball grid array which provides reliable bonding from board  21  to the next board level. However, other interconnection arrangements may be used at these levels. The form of BGA package shown in the figure is but one of many BGA alternatives used in the industry. Any suitable interconnection arrangement can be used to interconnect the IIS assembly to another interconnect level. It will be noted that the solder balls interconnecting board  21  to board  28  are substantially larger than those interconnecting the IC chip to the IIS. The IC chip interconnections are flip-chip micro-joints as described above while the BGA balls are typically 10 to 30 mils in diameter. 
     In the structures illustrated herein the IC and the IIS are square in shape, however, any quadrangular-shaped chip can be packaged using the approaches described. 
     It will be noted that the IIS that forms a part of the invention is die bonded to the next board level. The die bond is typically an epoxy bond. According to the main embodiment of the invention the die bond precludes solder ball or solder bump interconnections between the IIS and the next board level. The term die bond, as used herein and in the appended claims can be taken to exclude the presence of direct interconnection across the interface between the IIS and the next board level, other than the possibility of a single power or ground plane interconnection. 
     The term printed wiring board when used to define the invention refers to standard epoxy boards, for example FR4, ball grid array interconnect substrates, and any other suitable interconnect substrate. Also for the purpose of definition, the term metallization runner is used herein to define a conventional planar metal interconnection between interconnection sites or bonding pads on a chip or interconnection substrate. Typically these runners are aluminum. 
     The material of the IIS is semiconductor, to match the coefficient of thermal expansion (CTE) of the IC chip. Most typically this will be silicon. An advantage of using silicon is that it can be sufficiently conductive to serve as the bottom conductor level. Another advantage of using silicon is that the metallization technology for forming fine patterns of runners on the silicon is well known and is used in making the IC chip itself. However, lightwave devices, based on e.g. InP, can be packaged using a III-V IIS. 
     As noted earlier, the invention primarily addresses IC packages wherein the IC has more than 400 I/Os. Also as noted earlier the size of the IIS should be substantially larger than the IC to accommodate the larger array of interconnections at the edge of the IIS. In a typical package made according to the invention the perimeter of the IIS will exceed the perimeter of the IC by at least 15%, and preferably 40% or more. In terms of the area of the IIS relative to the area of the IC chip, the IIS area will in most cases exceed the IC chip area by a factor of at least 1.3, and more preferably 2.0 or more. 
     Various additional modifications of this invention will occur to those skilled in the art. All deviations from the specific teachings of this specification that basically rely on the principles and their equivalents through which the art has been advanced are properly considered within the scope of the invention as described and claimed.