 |
Claims  |
|
|
What is claimed as new and desired to be protected by Letters Patent of the
United States is:
1. A chip mounting system comprising:
a substrate for mounting at least one chip, said substrate having at least
one through-hole and at least one circuit component formed thereon;
a multi-layer structure covering both sides of said substrate and passing
through said at least one through-hole, said multi-layer structure
comprising at least one conductive plane and a signal wiring layer, said
at least one conductive plane and said signal wiring layer having an
insulating layer interposed between them; and
wherein said signal wiring layer has a first signal line in electrical
communication with said at least one circuit component.
2. The chip mounting system of claim 1, wherein said conductive plane
comprises a first ground plane.
3. The chip mounting system of claim 2, wherein said first ground plane is
at least 3 .mu.m thick.
4. The chip mounting system of claim 2, wherein the thickness of said first
ground plane is less than or equal to 5 .mu.m.
5. The chip mounting system of claim 1, wherein said conductive plane
comprises a power supply distribution plane.
6. The chip mounting system of claim 1, wherein said conductive plane
comprises a copper plane.
7. The chip mounting system of claim 1, wherein said conductive plane
comprises an aluminum plane.
8. The chip mounting system of claim 1, wherein said multi-layer structure
further comprises a first insulating layer provided on the side said
multi-layer structure directly adjacent to said substrate.
9. The chip mounting system of claim 8, wherein said first insulating layer
comprises a silicon dioxide layer.
10. The chip mounting system of claim 9, wherein the thickness of said
silicon dioxide layer is 0.1 to 0.5 .mu.m.
11. The chip mounting system of claim 8, wherein said conductive plane is
deposited over said first insulating layer.
12. The chip mounting system of claim 1, wherein said insulating layer
comprises a second insulating layer formed over said conductive plane.
13. The chip mounting system of claim 12, wherein said second insulating
layer comprises silicon dioxide.
14. The chip mounting system of claim 12, where the thickness of said
second insulating is 0.5 to 4.0 .mu.m.
15. The chip mounting system of claim 12, wherein said second insulating
layer comprises a polyimide layer.
16. The chip mounting system of claim 1, wherein said multi-layer structure
further comprises a third insulating layer formed over said signal wiring
layer.
17. The chip mounting system of claim 16, wherein said multi-layer
structure further comprises a second conductive plane formed over said
third insulating layer.
18. The chip mounting system of claim 17, wherein the thickness of said
second conductive plane is 3 .mu.m to 5 .mu.m.
19. The chip mounting system of claim 17, wherein said second conductive
plane comprises a ground plane.
20. The chip mounting system of claim 17, wherein said second conductive
plane comprises a power supply distribution plane.
21. The chip mounting system of claim 17, wherein said multi-layer
structure further comprises a fourth insulating layer formed over said
second conductive plane.
22. The chip mounting system of claim 16, wherein said third insulating
layer comprises a silicon dioxide layer.
23. The chip mounting system of claim 16, wherein said third insulating
layer comprises a silicon dioxide layer.
24. The chip mounting system of claim 16, wherein said third insulating
layer comprises a polyimide layer.
25. The chip mounting system of claim 1, wherein said signal wiring layer
comprises a second signal line.
26. The chip mounting system of claim 25, wherein said at least one signal
line is 6 to 10 .mu.m wide.
27. The chip mounting system of claim 25, wherein said second signal line
is terminated at a bond pad.
28. A chip mounting system comprising:
a substrate for mounting at least a first chip and a second chip, said
substrate having at least one through-hole;
a multi-layer structure covering both sides of said substrate and passing
through said through-hole, said multi-layer structure comprising a
conductive plane and a signal wiring layer having traces terminating in
bond pads on said both sides of said substrate, said conductive plane and
said signal wiring layer having an insulating layer interposed between
them; and
said at least first chip and second chip mounted onto said bond pads on
opposite sides of said substrate.
29. The chip mounting system of claim 28, wherein said through-hole is
rectangular in shape.
30. The chip mounting system of claim 28, wherein said through-hole is
circular in shape.
31. The chip mounting system of claim 28 further comprising interconnect
wiring to carry a signal between said bond pads and respective traces of
said signal wiring layer.
32. The chip mounting system of claim 28 further comprising interconnect
wiring to carry a signal between respective traces of said signal wiring
layer and active and/or passive components on the surface of said
substrate.
33. The chip mounting system of claim 28, wherein said conductive plane
comprises a first ground plane.
34. The chip mounting system of claim 33, wherein said first ground plane
is at least 3 .mu.m thick.
35. The chip mounting system of claim 34, wherein the thickness of said
first ground plane is less than or equal to 5 .mu.m.
36. The chip mounting system of claim 28, wherein said conductive plane
comprises a power supply distribution plane.
37. The chip mounting system of claim 28, wherein said conductive plane
comprises a copper plane.
38. The chip mounting system of claim 28, wherein said conductive plane
comprises an aluminum plane.
39. The chip mounting system of claim 28, wherein said multi-layer
structure further comprises a first insulating layer provided on the side
of said multi-layer structure directly adjacent to said substrate.
40. The chip mounting system of claim 39, wherein said first insulating
layer comprises a silicon dioxide layer.
41. The chip mounting system of claim 40, wherein the thickness of said
silicon dioxide layer is 0.1 to 0.5 .mu.m.
42. The chip mounting system of claim 39, wherein said conductive plane is
deposited over said first insulating layer.
43. The chip mounting system of claim 28, wherein said insulating layer
comprises a second insulating layer formed over said conductive plane.
44. The chip mounting system of claim 43, wherein said second insulating
layer comprises silicon dioxide.
45. The chip mounting system of claim 43, where the thickness of said
second insulating is 0.5 to 4.0 .mu.m.
46. The chip mounting system of claim 43, wherein said second insulating
layer comprises a polyimide layer.
47. The chip mounting system of claim 28, wherein said multi-layer
structure further comprises a third insulating layer formed over said
signal wiring layer.
48. The chip mounting system of claim 47, wherein said multi-layer
structure further comprises a second conductive plane formed over said
third insulating layer.
49. The chip mounting system of claim 48, wherein the thickness of said
second conductive plane is 3 .mu.m to 5 .mu.m.
50. The chip mounting system of claim 48, wherein said second conductive
plane comprises a ground plane.
51. The chip mounting system of claim 48, wherein said second conductive
lane comprises a power supply distribution plane.
52. The chip mounting system of claim 48, wherein said multi-layer
structure further comprises a fourth insulating layer formed over said
second conductive plane.
53. The chip mounting system of claim 47, wherein said third insulating
layer comprises a silicon dioxide layer.
54. The chip mounting system of claim 47, wherein said third insulating
layer comprises a silicon dioxide layer.
55. The chip mounting system of claim 47, wherein said third insulating
layer comprises a polyimide layer.
56. The chip mounting system of claim 28, wherein said signal wiring layer
comprises at least one signal line.
57. The chip mounting system of claim 56, wherein said at least one signal
line is terminated at a bond pad.
58. The chip mounting system of claim 56, wherein said at least one signal
line is 6 of 10 .mu.m wide.
59. An integrated circuit package comprising:
a substrate for mounting at least one chip, said substrate having at least
one through-hole;
a multi-layer structure covering both sides of said substrate and passing
through said through-hole, said multi-layer structure comprising a
conductive plane and a signal wiring layer, said conductive plane and said
signal wiring layer having an insulating layer interposed between them,
wherein said signal wiring layer has interconnect wiring extending to
opposite sides of said multi-layer structure; and
an integrated circuit package to encase said substrate, said multi-layer
structure and at least one circuit chip.
60. The integrated circuit package of claim 59, wherein said conductive
plane comprises a first ground plane.
61. The integrated circuit package of claim 60, wherein said first ground
plane is at least 3 .mu.m thick.
62. The integrated circuit package of claim 60, wherein the thickness of
said first ground plane is less than or equal to 5 .mu.m.
63. The integrated circuit package of claim 59, wherein said conductive
plane comprises a power supply distribution plane.
64. The integrated circuit package of claim 59, wherein said conductive
plane comprises a copper plane.
65. The integrated circuit package of claim 59, wherein said conductive
plane comprises an aluminum plane.
66. The integrated circuit package of claim 59, wherein said multi-layer
structure further comprises a first insulating layer provided on the side
of said multi-layer structure directly adjacent to said substrate.
67. The integrated circuit package of claim 66, wherein said first
insulating layer comprises a silicon dioxide layer.
68. The integrated circuit package of claim 67, wherein the thickness of
said silicon dioxide layer is 0.1 to 0.5 .mu.m.
69. The integrated circuit package of claim 66, wherein said conductive
plane is deposited over said first insulating layer.
70. The integrated circuit package of claim 59, wherein said insulating
layer comprises a second insulating layer formed over said conductive
plane.
71. The integrated circuit package of claim 70, wherein said second
insulating layer comprises silicon dioxide.
72. The integrated circuit package of claim 70, where the thickness of said
second insulating is 0.5 to 4.0 .mu.m.
73. The integrated circuit package of claim 70, wherein said second
insulating layer comprises a polyimide layer.
74. The integrated circuit package of claim 59, wherein said multi-layer
structure further comprises a third insulating layer formed over said
signal wiring layer.
75. The integrated circuit package of claim 74, wherein said multi-layer
structure further comprises a second conductive plane formed over said
third insulating layer.
76. The integrated circuit package of claim 75, wherein the thickness of
said second conductive plane is 3 .mu.m to 5 .mu.m.
77. The integrated circuit package of claim 75, wherein said second
conductive plane comprises a ground plane.
78. The integrated circuit package of claim 75, wherein said second
conductive plane comprises a power supply distribution plane.
79. The integrated circuit package of claim 75, wherein said multi-layer
structure further comprises a fourth insulating layer formed over said
second conductive plane.
80. The integrated circuit package of claim 59, wherein said signal wiring
layer comprises at least one signal line.
81. The integrated circuit package of claim 74, wherein said third
insulating layer comprises a silicon dioxide layer.
82. The integrated circuit package of claim 74, wherein said third
insulating layer comprises a silicon dioxide layer.
83. The integrated circuit package of claim 74, wherein said third
insulating layer comprises a polyimide layer.
84. The integrated circuit package of claim 80, wherein said at least one
signal line is 6 to 10 .mu.m wide.
85. The integrated circuit package of claim 80, wherein said at least one
signal line is terminated at a bond pad. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
I. Field of the Invention
The present invention relates generally to integrated circuit technology.
More specifically, the invention relates to a multi-chip system which
includes a chip carrier having a multi-layered metallized through-hole
interconnection and a method of making the same.
II. Description of the Related Art
There is a growing desire for a "system on a chip" as integrated circuit
technology enters the ultra large scale integration (ULSI ) era. Ideally,
the industry would like to build a computing system by fabricating all the
necessary integrated circuits on one substrate, as compared with today's
method of fabricating many chips of different functions on multiple
substrates. The concept of "system on a chip" has been around since the
very large scale integration (VLSI) era (early 1980s), but even today, it
is very difficult to implement such a truly high-performance system on a
single chip because of vastly different fabrication processes and
different manufacturing yields for various logic and memory circuits. With
many diverse circuits, especially with a mixture of analog and digital
circuits, a low-impedance ground is also required to suppress digital
noise. High-speed synchronous digital integrated circuits require large
switching currents which can induce noise on the power distribution
networks and ground busses due to finite resistance and inductance in
these circuits. Additionally, power supply noise can have a tremendous
effect due to simultaneous switching noise in CMOS integrated circuits.
These problems are more severe in mixed-mode analog/digital circuits and
require careful design of the power distribution systems. Thus, based on
current circuit implementation, there is a need for a built-in ground
plane adequate to handle and dissipate noise which is also difficult to
fabricate on a single chip with other components. A buried ground plane is
highly desirable to provide a flat surface to which various chips, active
circuits, and passive components can be subsequently mounted.
To overcome some of these problems, a "system module" has recently been
suggested in T. Mimura, et al, "System module: a new Chip-on-Chip module
technology," Proc. of IEEE 1997 Custom Integrated Circuit Conf., pages
437-442, 1997. This system module consists of two chips with a first chip
stacked on a second chip in a structure called Chip-on-Chip (COC) using a
micro bump bonding technology (MBB). With this technology, each chip can
be fabricated to perform specified functions with optimum processing
conditions. Then the individual chips can be combined in a single packaged
structure.
Recently, in U.S. patent application Ser. No. 09/144,307, by Ahn et al., a
compact system module with built-in thermoelectric cooling is described in
which a memory chip is directly mounted on a microprocessor chip. In U.S.
patent application Ser. No. 09/144,290, by the same inventors of the '307
application, a scheme of high-performance packaging in which individual
chips are mounted on a silicon interposer is described. In another U.S.
patent application Ser. No. 09/143,729, a built-it cooling channel was
introduced for efficient removal of heat generated by many chips mounted
on a silicon interposer. Furthermore, a silicon interposer with built-in
active devices was also recently disclosed in U.S. patent application Ser.
No. 09/144,197. Still further, an attempt to assemble a compact system
using multi-chip module technology for space-borne applications is
disclosed by R. J. Jensen et al., in "Mission: MCM, Designing for
Reliability in Harsh Environments," Advanced Packaging, January, 1998, p.
22-26, in which decoupling capacitors are an integral part of the system.
Davidson et al. in an article entitled "Long Lossy Lines and Their Impact
Upon Large chip Performance," IEEE Trans. On Component Packaging and
Manufacturing, Pt. B., vol. 20., no. 4, p. 361-375, 1997, addresses key
concerns in assembling many chips to a system module, namely, the length
and resistance of the interconnect lines. Davidson, cites an example of a
single microprocessor chip partitioned into four smaller ASIC chips for
higher production yield and consequently lower cost, and suggests mounting
them on a single multichip module, called a die pack, such as illustrated
here in FIGS. 1(a) and 1(b). With such a scheme, a long data line can be
reduced to a few millimeters. Also, see U.S. patent applications Ser. Nos.
09/009,791, 09/199,442, 09/247,680, 09/258,739 and 09/255,077 for related
discussions on mounting individual chips on a common carrier substrate.
While many improvements have been made in the multi-chip on a substrate
technology, there still remains a need for a high performance compact
system which provides controlled low-impedance wiring, including the
ground and distribution plane wiring, between chips mounted on the same
and opposite side of a common substrate.
SUMMARY OF THE INVENTION
The present invention is directed to an apparatus and method of making an
apparatus for a high-performance system module which uses multi-layer
metallized through-hole interconnections on a chip carrier substrate to
provide short wiring and controlled low-impedance wiring between chips
mounted on the carrier, the wiring including at least one of a ground
plane and a power distribution plane.
The term "substrate" used in the following description may include any
semiconductor-based structure that has an exposed silicon surface.
Structure must be understood to include silicon-on insulator (SOI),
silicon-on sapphire (SOS), doped and undoped semiconductors, epitaxial
layers of silicon supported by a base semiconductor foundation, and other
semiconductor structures. The semiconductor need not be silicon-based. The
semiconductor could be silicon-germanium, germanium, or gallium arsenide.
When reference is made to substrate in the following description, previous
process steps may have been utilized to form regions or junctions in or on
the base semiconductor or foundation.
The inventive method of the present invention comprises providing a chip
carrier substrate, typically formed of silicon, with a multi-layer
metallized through-hole interconnection. The through-hole interconnection
may be formed by: depositing a first insulating layer of silicon dioxide
over a substrate; depositing a first ground plane or power supply plane
layer over the silicon dioxide layer; depositing a second insulating layer
over the first layer; depositing a signal line wiring layer over the
second insulating layer; depositing a third insulating layer over the
signal line wiring layer; depositing another (second) ground plane or
power supply plane layer over the third insulating layer; and depositing a
fourth insulating layer over the second ground plane or power supply
layer. The carrier substrate can be used to carry and interconnect one or
more chips as part of an integrated package unit.
BRIEF DESCRIPTION OF THE DRAWINGS
The foregoing and other advantages and features of the invention will
become more apparent from the detailed description of preferred
embodiments of the invention given below with reference to the
accompanying drawings in which:
FIGS. 1(a)-1(b) illustrate an example of a prior art single microprocessor
chip partitioned into four smaller ASIC chips mounted on a multi-chip
module, called a die pack;
FIG. 2 illustrates a cross sectional view of a substrate having a
through-hole interconnection in accordance with an exemplary embodiment of
the present invention;
FIG. 3 is schematic drawing of a through-hole interconnection, top view in
accordance with an exemplary embodiment of the present invention;
FIG. 4 is a schematic drawing of a through-hole interconnection cross
sectional view along line 4--4 shown in FIG. 3;
FIG. 5(a) illustrates a cross-sectional view of a controlled impedance
interconnect system and fabrication sequence in accordance with an
exemplary embodiment of the present invention;
FIG. 5(b) illustrates a cross-sectional view of a controlled impedance
interconnect system featuring interconnect wiring in accordance with an
exemplary embodiment of the present invention;
FIG. 6 illustrates the process for forming interconnect wiring between the
signal Line wiring layer and substrate;
FIG. 7 illustrates the process for forming interconnect wiring between the
passive components and the signal line wiring layer; and
FIG. 8 illustrates a processor based system employing through-hole
interconnections in accordance with an exemplary embodiment of the present
invention.
DETAILED DESCRIPTION OF THE DRAWINGS
Referring now to the drawings, where like reference numerals designate like
elements, there is shown in FIG. 2 a chip carrier system in accordance
with an exemplary embodiment of the present invention. It includes a chip
carrier formed as a substrate 17, e.g., a silicon substrate, on which
passive or active circuit components 19, such as resistors, capacitors,
inductors, transistors, etc., can be formed, which is covered by a
multi-layer wiring/insulation layer 15 (described in greater detail
below), and on which a plurality of circuit chips are mounted. As
illustrated in FIG. 2, the circuit chips may include one or more of a
microprocessor chip 23, DRAM chip 25, SRAM chip 27, ROM chip 24, ASIC chip
28, or other chips which are mounted to the multi-layer wiring/insulation
layer 15 through a Ball Grid Array 13. The chip carrier is also provided
with one or more through-holes 29 through which the multi-layer
wiring/insulation layer 15 passes to make electrical connection between
chips mounted on opposite sides of the substrate 17. For simplicity, only
one through-hole 29 is shown, but it should be understood that any number
may be provided. Details of through-hole fabrication for a silicon
substrate were given recently in C. Christensen, et al., "Wafer
through-Hole Interconnections with High Vertical Wiring Densities," IEEE
Trans. On Components, Packing and Manufacturing Technology, Pt. A, vol.
19, no. 4, p. 516-522, 1996. Accordingly, a detailed description of how to
form a through hole in substrate 17 will not be repeated herein.
FIG. 3 is a top view of a through-hole 29 of FIG. 2 with upper layers
removed to show the signal line wiring layer 31, which pass through the
through-hole 29 and associated bond pads 33 which are connected to the
signal line wiring layer 31 through interconnect wiring 60 (FIG. 4). A
similar signal line wiring layer 31 and associated bond pads 33 are
provided on the opposite side of the substrate 17. The through-hole may be
a hollowed rectangle, circle, or any other geometric shape. The chips,
supported by substrate 17, are interconnected to input/output, ground and
power terminals by virtue of their mounting on bond pads 33. The
through-hole 29 on the top surface illustrated in FIG. 3 has sloping
sidewalls 40, as also illustrated in FIG. 2. For simplicity, only 12 bond
pads 33 are shown, but it should be appreciated that the number of bond
pads 33 and associated leads from the signal line wiring layer 31 passing
through the through-hole 29 may be larger or smaller. Typically the
through-hole 29 size is 1 mm square at its smallest opening dimension 22
(FIG. 2).
FIG. 4 is a cross sectional view along line 4--4 of FIG. 3 illustrating the
detailed multi-layer wiring/insulation layer 15. The multi-layer 15 is
formed on the substrate 17, which may also have active and/or passive
components 19 formed thereon. The multi-layer structure includes a first
insulating layer 35, e.g., a silicon dioxide layer, formed as a continuous
layer over both sides of substrate 17 and in the through-hole 29, a first
conductive ground plane layer 37a or alternatively a conductive power
supply distribution plane layer 37b formed as a continuous layer over the
first insulating layer 35, a second insulating layer 39 formed as a
continuous layer over the layer 37a or 37b, a signal line wiring layer 31
formed as a wiring pattern over the second insulating layer 39, a third
insulating layer 41 formed as a continuous layer over the signal line
wiring layer 31, another ground plane layer 43a or alternatively another
conductive power supply distribution plane layer 43b formed as a
continuous layer over the third insulating layer 41, and a fourth
insulating layer 45 formed as a continuous layer over layer 43a or 43b.
The signal line wiring layer 31 is electrically connected to interconnect
wiring 60, 62. As noted, the interconnect wiring 60 electrically connects
the signal lines of wiring layer 31 with bond pads 33. The interconnect
wiring 62 electrically connects the active and/or passive structures
formed on substrate 17 to the signal wiring layer 31. The bond pads 33
provide locations on which one or more of the chips 23, 24, 25, 27 are
mounted by for example, the Ball Grid Array technique, thereby
electrically connecting the active and/or passive components fabricated on
the substrate 17 to one or more of the chips 23, 24, 25, 27 through wiring
layer 31.
The chip carrier system illustrated in FIGS. 2-4 contains short controlled
impedance wiring paths between the chips mounted on both sides of
substrate 17 through the multi-layer wiring/insulation layer 15 which
passes through the through-hole 29.
FIG. 5(a) is a cross sectional view of a controlled impedance interconnect
system of FIG. 4 showing the fabrication sequence. In practice, the first
ground plane 37a or the power supply distribution plane 37b is first
fabricated by depositing a highly conductive layer, such as copper or
aluminum, by simple evaporation, sputtering or electroplating with a
typical thickness of about 3 to 5 .mu.m over a first insulating layer 35,
e.g. silicon dioxide, previously deposited over the substrate 17 by, for
example, CVD, typically to a thickness of about 0.1 to 0.5 .mu.m. A second
insulating layer 39 is deposited over this highly conductive layer 37a or
37b in step 2. This second insulating layer 39 preferably is silicon
dioxide deposited by chemical vapor deposition (CVD) to a thickness of
about 0.5 to 4 .mu.m. Alternatively, an insulator with a lower dielectric
constant, such as polyimide with .epsilon.=3, may be deposited by spin
coating followed by curing, if required by the electrical design. The next
step is to fabricate the patterned signal lines 31, which are typically
about 6 to 10 .mu.m wide, by employing optical lithography of a
photoresist followed by additive metallization, such as liftoff by
evaporation or electroplating, both of which are low-temperature
processing techniques. In step 4 a third insulating layer 41 is deposited
over the signal lines 31. Once again, the third insulating layer 41 is
preferably a layer of silicon dioxide deposited by CVD to a thickness of
at least 50% greater than the signal line wiring layer 31 conductor
thickness to ensure good step coverage at the signal line 31 conductor
corners. If a lower dielectric constant is desired, a lower dielectric
constant polymer, such as polyimide, can be deposited by spin coating. In
step 5 a planar conductor, as another ground plane 43a or alternatively
another conductive power supply distribution plane 43b, is deposited over
the third insulating layer 41 to a thickness of 3 to 5 .mu.m as was done
in step 1. It may also be desirable to planarize the third insulating
layer 41 to provide a flat surface so that when planar conductor 43a or
43b is formed it is substantially planar. The final step is to deposit a
fourth insulating layer 45 over the planar conductor 43a or 43b.
FIG. 5(b) illustrates a cross sectional view of the controlled impedance
interconnect system of FIG. 5(a) with the interconnect wiring 60,62 and
bond pads 33. FIGS. 6 and 7 illustrate the steps needed to provide
interconnect wiring 60, 62 (FIG. 5(b)) between: (i) the active and/or
passive components 19 formed on substrate 17 and the signal line wiring
layer 31 and (ii) the signal line wiring layer 31 and the circuit chips
23, 24, 25, 27.
In order to get a signal from the active and/or passive components 19 to
the signal lines 31, interconnect wiring 62, a signal conductor, must be
fabricated. Materials and techniques for forming such interconnect wiring
62 are commonly known in the art. However, FIG. 6 provides a flow chart
illustration of one exemplary technique in accordance with this invention.
After step 2 of FIG. 5(a) is completed, one or more holes are etched
through the second insulating layer 39, layers 37a/37b and 35 to the
active and/or passive components 19. Based upon the size of interconnect
wiring (conductor) 62 needed the hole may be formed by wet etching or dry
etching, such as reactive ion or plasma etching, see step 502. Next, in
step 504, an hole insulator 72 is deposited using CVD. This is to shield
the soon to be deposited interconnect wiring 62 from the layers which are
between the signal line wiring layer 31 and the substrate 17. The hole
insulator 72 can be SiO.sub.2, Si.sub.3 N.sub.4 or other commonly known
oxides. Lastly, the interconnect wiring 62 is deposited in step 506. The
interconnect wiring can be aluminum or copper, for example. The
interconnect wiring 62 is deposited in the insulated hole by any commonly
known process, e.g. evaporation, electroplating, etc. Step 506 can occur
at the same time as deposition of the signal wiring layer 31 (step 3 of
FIG. 5(a)) in order to increase efficiency and attain maximum
conductivity. The interconnect wiring 62 is then used to carry a signal
from the active and/or passive components 19 to the signal wiring layer
31.
FIG. 7 illustrates a similar process as that described in FIG. 6 with the
exception that FIG. 7 relates to depositing interconnect wiring 60 from
the bond pads 33 of circuit chips 23, 24, 25, 27, 28 to the signal line
wiring layer 31. For interconnect wiring 60 one or more holes are etched
in step 602 and a hole insulator 70 is deposited in step 604 as in the
fabrication of interconnect wiring 62. However, this process is performed
after the deposition of the fourth insulating layer 45 (step 6, FIG.
5(a)). The last step, again, is to deposit the interconnect wiring 62 in
step 606. When interconnect wiring 62 is deposited, the bonds pads 33 may
all be fabricated in a one step metallization to increase efficiency and
conductivity.
The substrate 17 with multi-layer wiring/insulation layer 15 and associated
circuit chips 23, 24, 25, 27, 28 may all be encapsulated in a single
integrated package unit composed of a plastic composite. In such an
implementation multiple exterior pins are needed to interface the
integrated package unit to a circuit board for communication with other
components of a system.
FIG. 8. illustrates a processor-based system 102, including central
processing unit (CPU) 112, memory devices 108, 110, input/output (I/O)
devices 104, 106, floppy disk drive 114 and CD ROM drive 116. All of the
above components communicate with each other over bus 118. The central
processing unit (CPU) 112, and one or more of the memory devices 108, 110
are fabricated as one or more chips which can be mounted onto a chip
carrier 17, as illustrated in FIG. 2, with through-hole interconnections
in accordance with the present invention as described above.
As noted, the present invention provides for an apparatus and method of
making the same which results in a chip carrier system with short
through-hole interconnections and with a low impedance.
It is to be understood that the above description is intended to be
illustrative and not restrictive. Many variations to the above-described
method and structure will be readily apparent to those having ordinary
skill in the art. For example, the conducting and insulting layers can be
constructed of many different commonly known materials. In addition,
alternative insulating and conducting layers can be formed within the
multi-layer wiring/insulating layer 15 and any number of conductive and
insulating layers can be used.
Accordingly, the present invention is not to be considered as limited by
the specifics of the particular structures which have been described and
illustrated, but is only limited by the scope of the appended claims.
* * * * *
|
|
|
|
|
|
|
Description |
|
