U.S. patent application number 11/321744 was filed with the patent office on 2006-10-26 for folded interposer.
Invention is credited to Charles E. Larson.
Application Number | 20060242477 11/321744 |
Document ID | / |
Family ID | 25213195 |
Filed Date | 2006-10-26 |
United States Patent
Application |
20060242477 |
Kind Code |
A1 |
Larson; Charles E. |
October 26, 2006 |
Folded interposer
Abstract
A folded interposer used to achieve a high density semiconductor
package is disclosed. The folded interposer is comprised of a thin,
flexible material that can be folded around one or multiple
semiconductor dice in a serpentine fashion. The semiconductor dice
are then attached to a substrate through electrical contacts on the
interposer. The folded interposer allows multiple semiconductor
dice to be efficiently stacked in a high density semiconductor
package by reducing the unused or wasted space between stacked
semiconductor dice. Vias extending through the folded interposer
provide electrical communication between the semiconductor dice and
the substrate. The present invention also relates to a method of
packaging semiconductor dice in a high density arrangement and a
method of forming the high density semiconductor package.
Inventors: |
Larson; Charles E.; (Nampa,
ID) |
Correspondence
Address: |
TRASK BRITT
P.O. BOX 2550
SALT LAKE CITY
UT
84110
US
|
Family ID: |
25213195 |
Appl. No.: |
11/321744 |
Filed: |
December 29, 2005 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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10291076 |
Nov 7, 2002 |
6982869 |
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11321744 |
Dec 29, 2005 |
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09813724 |
Mar 21, 2001 |
6884653 |
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10291076 |
Nov 7, 2002 |
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Current U.S.
Class: |
714/704 |
Current CPC
Class: |
H05K 1/147 20130101;
H01L 25/0657 20130101; H01L 2225/06517 20130101; H01L 2225/06579
20130101; H05K 2201/10378 20130101; H01L 23/5387 20130101; H01L
23/4985 20130101; H01L 2224/16 20130101 |
Class at
Publication: |
714/704 |
International
Class: |
G06F 11/00 20060101
G06F011/00 |
Claims
1. A folded interposer comprising: a thin, flexible material
comprised of a first surface and a second surface, the material for
folding around at least one semiconductor die, the material having
substantially the same width as the at least one semiconductor die;
a plurality of vias extending from the first surface to the second
surface; and a plurality of electrical contacts on the first
surface of the material.
2. The interposer of claim 1, wherein the material comprises an
insulative polymer.
3. The interposer of claim 2, wherein the material further
comprises a thermally conductive material.
4. The interposer of claim 1, wherein the second surface surrounds
at least three sides of the at least one semiconductor die around
which the interposer is folded.
5. The interposer of claim 1, wherein the second surface surrounds
at least two sides of the at least one semiconductor die around
which the interposer is folded.
6. The interposer of claim 1, wherein each of the plurality of
electrical contacts is applied to the second surface of the
material.
7. A high density semiconductor package having at least two
semiconductor dice comprising: a substrate having at least one
contact pad on a surface thereof; and a flexible interposer folded
around a first semiconductor die of the at least two semiconductor
dice, the interposer including a first surface having a plurality
of electrical contacts for electrically connecting the first
semiconductor die to the substrate, a second surface, and a
plurality of vias extending through the interposer from the first
surface to the second surface, the first semiconductor die having a
plurality of bond pads on a surface thereof and a back surface, the
first semiconductor die positioned in a back-to-back configuration
with another semiconductor die of the at least two semiconductor
dice and attached to the interposer to form an intermediate
packaging structure; at least one electrical contact of the
plurality of electrical contacts of the flexible interposer
connected to the at least one contact pad of the substrate.
8. The package of claim 7, wherein each of the plurality of vias is
filled with conductive metal.
9. The package of claim 7, wherein the second surface surrounds at
least three sides of the first semiconductor die around which the
interposer is folded.
10. The package of claim 7, wherein the second surface surrounds at
least two sides of the first semiconductor die around which the
interposer is folded.
11. The package of claim 7, wherein at least one bond pad of the
plurality of bond pads of the first semiconductor die is in
electrical communication with at least one electrical contact of
the plurality of electrical contacts of the flexible interposer
through the plurality of vias therein.
12. The package of claim 7, wherein the interposer folds around
more than two semiconductor dice by weaving in a serpentine fashion
around groups of semiconductor dice, each group including two
semiconductor dice.
13. The package of claim 7, wherein the substrate comprises a
semiconductor device.
14. The package of claim 7, wherein the substrate further comprises
a printed circuit board.
15. The package of claim 7, further comprising electrical contacts
applied to a top surface of the package.
16. An interposer comprising: a thin, flexible material comprised
of a first surface and a second surface, the material for folding
around at least one semiconductor die, the material having
substantially the same width as the at least one semiconductor die;
a plurality of vias extending from the first surface to the second
surface; and a plurality of electrical contacts on the first
surface of the material.
17. The interposer of claim 16, wherein the material comprises an
insulative polymer.
18. The interposer of claim 17, wherein the material further
comprises a thermally conductive material.
19. The interposer of claim 16, wherein the second surface
surrounds at least three sides of the at least one semiconductor
die around which the interposer is folded.
20. The interposer of claim 16, wherein each of the plurality
electrical contacts is applied to the second surface of the
interposer.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation of application Ser. No.
10/291,076, filed Nov. 7, 2002, now U.S. Pat. No. 6,982,869,
issuing Jan. 3, 2006, which is a divisional of application Ser. No.
09/813,724, filed Mar. 21, 2001, now U.S. Pat. No. 6,884,653,
issued Apr. 26, 2005.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates to a semiconductor die
package. More particularly, the present invention relates to a
folded interposer used to increase the semiconductor die density of
a high density semiconductor package.
[0004] 2. Background of Related Art
[0005] As electronic devices, such as cell phones and personal
digital assistants ("PDAs"), become smaller, more portable, and
more technologically advanced, there is an increasing need for high
density semiconductor die packages that can provide the necessary
memory for these devices. New, high density semiconductor packages
must be easily and cheaply manufactured with existing equipment. In
addition, the package must maintain the reliability and quality of
the semiconductor die. A semiconductor die package contains many
electrical circuit components that must be interconnected to form
functional, integrated circuits.
[0006] Consumers want their portable devices to perform the same
functions as their desktop computers, therefore requiring large
amounts of memory in a much smaller electronic device. One way of
accomplishing this is to increase the density of a semiconductor
die package by using the package's real estate more efficiently.
One advantage of high density packaging is that it decreases the
length of the connections between the semiconductor die and the
package, allowing the semiconductor die to respond faster. Also,
reducing the length of the connections reduces the signal
propagation time and makes the signal paths less vulnerable to the
effects of noise.
[0007] Numerous high density semiconductor packages exist in the
art. However, these packages are ill-suited for use in small,
portable electronic devices because they inefficiently use their
real estate, which unnecessarily adds to the overall size of the
package. For instance, U.S. Pat. No. 5,128,831 issued to Fox, III
et al. teaches a high density package composed of multiple
submodules, each of which contains a chip bonded to a substrate. A
spacer, which is at least as thick as the chip, is adhesively
bonded to the peripheral upper surface of each submodule before the
submodules are stacked to form the high density package. The
thickness of the spacer causes a gap between each submodule. When
multiple submodules are needed, the cumulative effect of these gaps
makes the package significantly larger than the size of the
components used in the package.
[0008] A multichip module comprised of stacked semiconductor dice
is disclosed in U.S. Pat. No. 5,323,060, issued to Fogal et al. The
semiconductor dice are electrically connected to a substrate by
extending long bond wires from bond pads on each semiconductor die
to the substrate. In order to accommodate the loop height of the
bond wires, a thick adhesive layer is applied between the
semiconductor dice. The adhesive layer must be thick enough that
the bond wires of the lower semiconductor die do not contact the
upper semiconductor die. This multichip module is not suited for
small electronic devices because the adhesive layer between the
dice increases the overall thickness of the semiconductor
package.
[0009] U.S. Pat. No. 5,604,377 issued to Palagonia teaches a stack
of semiconductor chips designed to be lightweight and to provide
better cooling, mechanical shock, and vibration protection. The
chips are separated by rigid, insulating interposers formed from a
rack structure that contains shelves. The shelves provide
electrical insulation and mechanical protection to the chips. The
rigid shelves also prevent undue movement of the chips, while the
spacing between shelves allows for adequate heat dissipation. Since
the shelves are rigid and provide space between the chips, the
packaging scheme is not suited for use in small electronic
devices.
[0010] U.S. Pat. No. 5,818,107 issued to Pierson et al. teaches an
integrated circuit package that utilizes metallization features,
located at opposite edges of each chip, to attach a stack of chips
to a substrate. The chips are bonded together through their
metallization features to form a chip stack, which is then bonded
to the substrate. The thickness of the metallization features, in
addition to the bonding material used, provides a "stand off" or
separation between chips. This separation adds to the overall
thickness of the integrated circuit package, making it incompatible
for use in electronic devices that require small semiconductor
packages.
[0011] In U.S. Pat. No. 5,994,166 issued to Akram et al., a dense
semiconductor package comprising multiple substrates with attached
flip-chips is disclosed. The substrates are stacked on top of one
another. Column-like connections positioned between the stacked
substrates provide electrical communication. The electrical
connections must be of sufficient height to provide enough
clearance between substrates to mount components and also must be
of sufficient strength to provide support between the substrates.
Since the column-like connections cause unused space between the
substrates, this semiconductor package is incompatible with
electronic devices that require small semiconductor packages.
[0012] While numerous high density semiconductor packages exist,
they share a common disadvantage in that they inefficiently use the
space of the semiconductor package. The unused or wasted space may
be the result of thick adhesive layers between semiconductor dice
or may be caused by rigid interposers or other spacers. Small
electronic devices, such as cell phones and PDAs, have very limited
space and cannot afford to waste any of this space. Reducing the
wasted or unused space in a semiconductor die package is essential
because large packages occupy too much of this limited space. It
would be preferable to reduce the unused or wasted space in a stack
of semiconductor dice by more closely spacing the semiconductor
dice. It would be more preferable for the semiconductor dice to be
spaced substantially one on top of another. It would be most
preferable for the overall size of a high density semiconductor
package to be caused only by the thickness of the semiconductor die
and a substrate, without substantial thickness coming from
additional packaging or unused space.
[0013] Methods for connecting dice to a substrate are well known in
the art. For example, wire bonding, tape automated bonding ("TAB"),
and controlled collapse chip connection ("C4") are commonly used to
physically and electrically connect semiconductor dice to a
substrate. Wire bonding utilizes fine wire conductors bonded on one
end to the substrate and on the other end to electrical contacts on
the semiconductor die. Because wire bonding requires wires to be
welded to the die, there must be adequate space to accommodate the
wires. TAB utilizes patterned metal on a polymeric tape to join
dice together. The joined semiconductor dice are attached to a
substrate by outer lead bonding. C4, or flip-chip, bonding uses
solder balls on the surface of a semiconductor die to bond the
semiconductor die to a substrate.
[0014] In addition to the above-mentioned methods, the prior art
also discloses using vias to attach a semiconductor die to a
substrate and to provide electrical communication between the
semiconductor die and substrate. The vias may be filled with
conductive metal or flexible leads may be run through the vias to
provide electrical communication. As mentioned above, U.S. Pat. No.
5,128,831 issued to Fox, III et al. teaches a high density package
composed of multiple submodules, each of which contains a chip
bonded to a substrate. Each substrate has a metallization pattern,
which comprises multiple conductive traces. A spacer is adhesively
bonded to the peripheral upper surface of each submodule before the
submodules are stacked. Both the substrate and spacer contain vias
that are coincident and substantially coaxial with each other when
the package is assembled. The vias are filled with solder to
electrically connect the traces of all the submodules. Similarly,
U.S. Pat. No. 5,148,266 issued to Kane et al., mentioned in more
detail below, uses solid vias to electrically interconnect two
chips on opposite sides of a flexible carrier.
[0015] U.S. Pat. Nos. 5,252,857 and 5,682,061 issued to Khandros et
al. disclose a semiconductor chip assembly containing a
semiconductor chip and a substrate that are separated by an
interposer. The interposer contains multiple apertures that extend
from the first surface to the second surface of the interposer.
Flexible leads extending through the apertures are used to connect
the chip to terminals on the interposer. The interposer terminals
are then connected to contact pads on the substrate. The flexible
leads allow for movement of the contacts on the chip relative to
the contacts on the substrate, thereby reducing the stresses caused
by thermal cycling.
[0016] The semiconductor die industry has commonly used flexible
components to ameliorate the problems associated with differential
thermal expansion of a semiconductor die and substrate. If a die
and substrate have different coefficients of thermal expansion, the
heat generated by operating an electronic device causes the die and
substrate to expand at different rates. When the electronic device
is turned off, the semiconductor die and substrate contract at
different rates. Over time, these heat cycles place a large amount
of mechanical stress on the electrical contacts and solder
connections between the semiconductor die and substrate. After
repeated cycles, the contacts and connections may fail. The
semiconductor die industry has recognized two ways around this
problem. First, the mechanical stress on the electrical contacts
and solder connections can be minimized by using components that
have similar coefficients of thermal expansion. However, this
severely limits the types of components that can be used together.
A second way around this problem is to incorporate flexible
components into the die package. Flexible components known in the
art include interposers, circuits, circuit boards, and leads. For
example, U.S. Pat. No. 4,851,613 issued to Jacques teaches a
flexible circuit board that can be bent, rolled, or folded into a
desired shape. The circuit board comprises a substrate, a layer of
conductive material in which a circuit is formed, and an insulating
layer. Surface mount devices, such as resistors, capacitors, and
integrated circuits, can be mounted to the flexible circuit board.
Use of the flexible circuit board allows for thermal expansion
between the surface mount devices and the circuit board without
cracking solder joints or breaking electrical and physical
connections.
[0017] In U.S. Pat. Nos. 5,148,266 and 5,682,061 issued to Khandros
et al., a semiconductor chip assembly containing an interposer and
flexible leads is disclosed. The interposer separates a
semiconductor chip and a substrate. The chip and substrate
electrically communicate through flexible leads that run through
apertures in the interposer. The leads connect the chip to
terminals on the interposer, which are then connected to contact
pads on the substrate. The flexible leads allow for movement of the
contacts on the chip and, therefore, reduce the stresses caused by
thermal cycling.
[0018] U.S. Pat. No. 5,889,652 issued to Turturro teaches an
integrated circuit package comprising an integrated circuit
attached to a substrate. The substrate includes two portions, a
bond portion and a contact portion, separated by a flexible
portion. The integrated circuit is attached to the bond portion of
the substrate, while the contact portion is attached to a printed
circuit board. The flexible portion of the substrate allows for
relative movement between the package and the circuit board,
minimizing thermal expansion stress on the solder joints.
[0019] U.S. Pat. No. 6,002,590 issued to Farnworth et al. teaches a
printed circuit board that contains traces attached to a flexible
trace surface. Components, such as ball grid array ("BGA")
components, are attached to the traces. The flexible trace surface
may be created by the top surfaces of flexible protuberances, which
are formed by etching away the substrate not covered by the traces.
Alternatively, the flexible trace surface may be formed by
depositing a flexible layer onto the printed circuit board. The
flexible trace surface allows the traces to be displaced in a
direction of thermal expansion of the attached components, thus
preventing cracking of solder joints between the trace and
component.
[0020] U.S. Pat. No. 6,014,320 issued to Mahon et al. teaches a
high density circuit module that is comprised of a flex circuit
attached to a substrate. The flex circuit is attached to one side
of the substrate and folded over to the other side of the
substrate. The resulting module includes integrated circuits on one
side of the substrate and input/output pads on the opposite
side.
[0021] While the above-mentioned inventions disclose flexible
components in semiconductor die packages, they only disclose
attaching one semiconductor die to a substrate. Since high density
semiconductor packages are necessary for new generations of
electronic devices, it would be preferable to combine flexible
components with semiconductor die packages that can accommodate
multiple semiconductor dice.
[0022] U.S. Pat. No. 5,252,857 issued to Kane et al. discloses both
of these features. A dense memory package is disclosed where two
memory chips are mounted face-to-face on opposite sides of a
flexible carrier or interposer. The two chips contain solder bumps
that align when the chips are placed face to face. In addition, the
interposer contains pads that are coated with low melting point
solder. The bumps on the chips contact the pads on the interposer
and are soldered together. Kane also discloses a plurality of pairs
of chips mounted on opposite sides of a flexible carrier. The
flexible carrier with the attached chips can be folded to connect
with substrates, such as printed circuit boards. While Kane
discloses a flexible carrier that can be used to connect multiple
dice to a printed circuit board or backplane, the pairs of dice are
mounted face-to-face on opposite sides of the flexible carrier.
[0023] The present invention solves the above-mentioned problems.
The present invention discloses a high density semiconductor
package that has reduced or eliminated the unused space between
stacked semiconductor dice. The resulting high density
semiconductor package of the present invention is small and is,
therefore, useful in portable electronic devices such as cell
phones and PDAs.
SUMMARY OF THE INVENTION
[0024] The present invention relates to a folded interposer and a
high density semiconductor package that utilizes the folded
interposer. The folded interposer is comprised of a thin, flexible
material that can be folded around one or multiple semiconductor
dice. The folded interposer allows multiple semiconductor dice to
be efficiently stacked in a high density semiconductor package by
reducing the unused or wasted space between stacked semiconductor
dice. The present invention also relates to a method of packaging
semiconductor dice in a high density arrangement and a method of
forming the high density semiconductor die package. Finally, the
present invention relates to a computer system that incorporates
the folded interposer in a high density semiconductor die
package.
BRIEF DESCRIPTION OF THE DRAWINGS
[0025] While the specification concludes with claims particularly
pointing out and distinctly claiming the present invention, the
advantages of the invention can be more readily ascertained from
the following detailed description of the invention when read in
conjunction with the accompanying drawings in which:
[0026] FIG. 1 is a side view of an interposer of the present
invention;
[0027] FIG. 2 is a side view of an interposer of the present
invention folded around one semiconductor die;
[0028] FIG. 3 is a side view of an interposer of the present
invention folded around two semiconductor dice;
[0029] FIG. 4 is a side view of an interposer of the present
invention folded around two semiconductor dice and attached to a
substrate;
[0030] FIG. 5 is a side view of an interposer of the present
invention folded in a serpentine fashion around more than two
semiconductor dice; and
[0031] FIG. 6 is a side view of an interposer of the present
invention showing electrical contacts on the top surface of the
structure.
DETAILED DESCRIPTION OF THE INVENTION
[0032] Illustrated in drawing FIG. 1 is an interposer 10, which
includes a first surface 16 and a second surface 18. The first
surface 16 includes electrical contacts 20 for attaching the
interposer 10 to a substrate (not shown), such as a printed circuit
board. Vias 24 extend through the interposer 10 from the first
surface 16 to the second surface 18 and are in communication with
the electrical contacts 20. The folded interposer 10 is comprised
of a thin, flexible material, such as an insulative polymer. The
material has substantially the same width as a semiconductor die so
that the material covers the surface of the semiconductor die.
Preferably, the material should also be thermally conductive to
allow for adequate dissipation of heat generated by the electrical
circuitry.
[0033] As illustrated in drawing FIGS. 2 and 3, the interposer 10
is flexible enough to fold around one or multiple semiconductor
dice 12. Preferably, the semiconductor dice 12 are bare, unpackaged
dice. As is illustrated in drawing FIG. 2 (vias not shown), the
interposer 10 surrounds at least three sides of one semiconductor
die 12 to form an intermediate packaging structure 28. Illustrated
in drawing FIG. 3 (vias not shown) is an intermediate packaging
structure 28 containing multiple semiconductor dice 12, wherein the
interposer 10 surrounds at least two sides of each semiconductor
die.
[0034] Methods of attaching a semiconductor die to a substrate are
well known in the art. Any means known in the art for attaching the
semiconductor die to the interposer may be used in the present
invention. Intermediate packaging structure 28, which includes the
interposer 10 and attached semiconductor dice 12, is attached to a
substrate to form a high density semiconductor package 14 (see FIG.
4).
[0035] The present invention also relates to a high density
semiconductor die package 14 utilizing the folded interposer 10. As
is best illustrated in drawing FIGS. 4 through 6, the folded
interposer 10 is used to attach one or multiple semiconductor dice
12 to a substrate 22, thus forming the high density semiconductor
package 14. The interposer 10, which has two surfaces, is folded
around the semiconductor dice 12 to form intermediate packaging
structure 28. Since the bond pads 26 (FIGS. 2-3) of each
semiconductor die 12 must be in contact with vias 24 (FIG. 1),
multiple semiconductor dice 12 must be positioned in groups of two
in a back-to-back configuration so that all semiconductor dice 12
are in electrical communication with substrate 22. Intermediate
packaging structure 28 is then attached to the substrate 22 through
the electrical contacts 20 on the first surface 16 of the
interposer 10. The substrate 22 may be any type of semiconductor
substrate known in the art, such as a printed circuit board. The
semiconductor dice 12 and substrate 22 are in electrical
communication through the bond pads 26 and the electrical contacts
20, which are in contact with the vias 24. The vias 24 may be
filled with a conductive material to provide electrical
communication between the semiconductor dice 12 and substrate
22.
[0036] The high density semiconductor die package 14 accommodates
more than two semiconductor dice by weaving the flexible interposer
10 around groups of two semiconductor dice. Since the bond pads 26
of each die must be in contact with vias 24, the two semiconductor
dice 12 must be positioned in a back-to-back configuration so that
all semiconductor dice 12 are in electrical communication with
substrate 22. As is illustrated in drawing FIG. 5 (bond pads and
vias not shown), the interposer 10 weaves in a serpentine fashion
between groups of two semiconductor dice 12.
[0037] As is illustrated in drawing FIG. 5 (electrical contacts 20,
vias 24, and substrate 22 not shown), the present invention also
relates to a method of packaging semiconductor dice in a high
density arrangement. The semiconductor dice are packaged by
providing at least one semiconductor die 12, a flexible interposer
10, and a substrate 22. The interposer 10 is folded around and
attached to the semiconductor dice 12. The interposer 10 has a
first surface 16, a second surface 18, and vias 24 that extend
through the interposer 10 from the first surface 16 to the second
surface 18. The first surface 16 includes electrical contacts 20.
The semiconductor dice 12 are attached to the interposer 10 through
bond pads 26 on the active surface of the semiconductor die 12 to
form intermediate packaging structure 28. Intermediate packaging
structure 28 is then attached to substrate 22 through the
electrical contacts 20 to form a high density semiconductor package
14. This attachment also results in electrical communication
between the semiconductor die 12 and the substrate 22. In a high
density semiconductor package 14 containing one semiconductor die
12, the interposer 10 is folded around the semiconductor die 12 so
that at least three sides of the semiconductor die are surrounded,
as is illustrated in drawing FIG. 2 (vias and substrate not shown).
In a high density semiconductor package 14 containing two
semiconductor dice 12, the interposer 10 surrounds at least two
sides of each semiconductor die 12, as is illustrated in drawing
FIG. 3 (vias and substrate not shown). Illustrated in drawing FIG.
5 (bond pads, vias, and substrate not shown) is that the interposer
10 weaves in a serpentine fashion between semiconductor dice 12
stacked in groups of two when a high density semiconductor package
14 containing more than two semiconductor dice 12 is desired.
Additionally, electrical contacts 20 may be applied to a top
surface 30 of the package 14, as is shown in drawing FIG. 6 (bond
pads, vias, and substrate not shown), so that the package 14 can be
attached to other semiconductor devices, depending on the desired
application.
[0038] The present invention also relates to a method of forming a
high density semiconductor die package 14. The high density
semiconductor die package 14 is formed by providing the interposer
10 and at least one semiconductor die 12. The at least one
semiconductor die 12 is attached to the interposer 10 to form
intermediate packaging structure 28. The intermediate packaging
structure 28 is attached to substrate 22 through methods well known
in the art, such as wire bonding, C4, TAB, and bonding through
vias. In applications where more than two semiconductor dice are
desired, the semiconductor dice 12 are attached to the interposer
10 in groups of two in a back-to-back configuration. Electrical
connection between the substrate 22 and semiconductor dice 12 is
established through the electrical contacts 20 and vias 24 on the
interposer 10. Additionally, electrical contacts 20 may be applied
to a top surface 30 of the high density semiconductor die package
14, as is shown in drawing FIG. 6 (bond pads and vias not shown),
so that the high density semiconductor die package 14 can be
attached to other semiconductor devices, depending on the desired
application.
[0039] The present invention also relates to a computer system
using the folded interposer 10 and high density semiconductor die
package 14. The computer system is comprised of an input device, an
output device, a processor, and a memory module. The processor is
coupled to the input and output devices. The memory module is
coupled to the processor. The memory module includes a module board
and the high density semiconductor package 14, which are in
electrical contact with each other. The high density semiconductor
package 14 utilizes the folded interposer 10 as has been described
above.
[0040] Although specific examples demonstrating the present
invention have been described, it is to be understood that the
invention defined by the appended claims is not to be limited by
the particular details set forth in the above description. One of
ordinary skill in the art would understand that many apparent
variations are possible without departing from the scope of the
appended claims. For example, varying the number of semiconductor
dice in the high density semiconductor die package would be
understood to be within the scope of the appended claims. In
addition, varying the methods of attaching the dice to the
interposer and/or the substrate and the methods of achieving
electrical communication between the semiconductor dice and the
substrate would be understood to be within the scope of the
appended claims.
* * * * *