Multilayer wiring board embedded with transmission line...

Details Multilayer wiring board embedded with transmission line... Multilayer wiring board embedded with transmission line...

2001-07-03

2004-01-27

Talbott, David L. (Department: 2827)

Electricity: conductors and insulators

Conduits, cables or conductors

Preformed panel circuit arrangement

C029S830000, C174S261000

Reexamination Certificate

active

06683260

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention generally relates to a multilayer wiring board having a transmission line structure of high wiring density, and in particular to a conductor-embedded type of a multi-layer wiring board having transmission line structure composed of at least a pair of adjacent signal conductors embedded near a surface of a dielectric layer and also relates to a manufacturing method thereof.
2. Description of the Prior Art
FIG. 8
shows a wiring pattern model of a conventional multi-layer wiring board or multi-chip waveguide generally used in information equipment and the like. In this construction, a characteristic impedance representing a signal transmission characteristic of line conductors or wires for connecting semiconductor components and the like elements is defined as Z
0
={square root over (L/C)} where C is a capacity and L is an inductance per a unit length of the line conductor or wire. In this definition, the capacity C and inductance L are determined by, e.g., a width and thickness of the conductor of the wiring pattern and a thickness of an insulating layer region, and therefore the characteristic impedance Z
0
is also determined by these factors.
In designing a wiring structure, the value of the characteristic impedance Z
0
is determined in consideration of a higher-speed processing, circuit system, crosstalk value and the like of semiconductor components, and the value of the characteristic impedance of the wiring structure for use in information equipment is generally in a range of several tens &OHgr; to one hundred &OHgr;. Unification or equality of characteristic impedance values is also especially important in view of reducing noises. If there exists a discontinuous point in a wiring structure, a reflection occurs to cause an erroneous operation in the information equipment.
The following explains a typical example of a transmission waveguide structure of a printed wiring board having an insulation region composed of a dielectric layer.
FIG. 9
shows a cross section of a basic form of a microstrip waveguide, where a strip signal conductor
3
is formed on one surface (upper surface in the drawing) of the dielectric body (i.e., board or layer)
1
and a flat plane conductor
2
such as a grounding conductor layer is formed on the other surface (bottom surface in the drawing) of the dielectric board
1
so as to generate an electric field (electric power lines) across the center portion and edge portion of the dielectric body as shown by dotted lines in the drawing.
The thickness of the dielectric board
1
is T and a signal conductor
3
having a width w and thickness (i.e., height) t is formed on the upper surface thereof in the drawing. For example, approximate values thereof are used as such that, the thickness T is 220 &mgr;m, width w is 360 &mgr;m and thickness t is at least 10 &mgr;m. Thus, the characteristic impedance of the signal conductor
3
with respect to the lower plane conductor
2
is approximately determined by a dielectric constant ∈ of the dielectric material and thickness T of the dielectric board
1
and the width w of the signal conductor
3
disregarding the thickness t of the signal conductor
3
because the thickness t of the signal conductor
3
is enough small with respect to the width w (i.e., t<<w). Therefore, difference or unevenness in characteristic impedances is caused due to differences in width w and thickness T, and because of the small thickness t of the signal conductor
3
, there arises a problem that a loss increases in electric consumption as a resistance of the signal conductor increases when constructing a wiring pattern with high wiring density.
FIG. 10
shows a wiring board having a plurality of line conductors
3
a
through
3
e
. Assuming that each gap distance between adjacent two conductors is substantially equal to the width of each signal conductor
3
, three usage examples thereof will be explained as below.
In the first example, the respective conductors are used as independent five signal conductors. In the case of a wiring structure having a characteristic impedance of around 50 &OHgr; which is normally used, a coupling impedance (also regarded as a coupling capacity) between the adjacent signal conductors is fairly higher in dimension than the coupling impedance between the signal conductors and the plane conductor
2
. However, a cross-talk between the adjacent signal conductors becomes a problem.
In the second example, a shielding conductor is placed between signal conductors in order to reduce a cross-talk. For example, the line conductors
3
b
and
3
d
are used as signal conductors, and the line conductors
3
a
,
3
c
and
3
e
are used as the shielding conductors having the same potential as that of the plane conductor
2
. Generally, in order to lower the cross-talk, in comparison with the case where gaps between the signals conductors are increased, the provision of the shielding conductors makes the wiring density of the transmission line structure to be higher.
In the third example, the adjacent two line conductors
3
b
and
3
c
are used as a pair of balanced transmission line conductors, and the line conductors
3
a
and
3
d
positioned at both sides thereof are used as the shielding conductors.
FIG. 11
shows another example of a conventional microstrip waveguide structure in which the dielectric region
1
and plane conductors
2
are provided over both upper and lower surfaces of the signal conductor
3
. In this structure, in the case where the microstrip waveguide is incorporated in a multi-layer wiring board, interference with other wiring layers can be reduced, and excellent transmission characteristics can be obtained.
FIG. 12
shows an example of a conventional coplanar transmission waveguide structure, where a signal conductor
3
and a pair of plane conductors
4
are provided on the same surface of the dielectric board
1
. This coplanar type can be composed of one wiring layer, but high density of the transmission lines cannot be obtained, and the coplanar type is easily influenced by surroundings or conductors on another layer. For this reason, this coplanar transmission waveguide structure is not suitable to be incorporated into a multi-layer wiring board.
The aforementioned conventional transmission waveguides are manufactured in such a manner that a signal wiring pattern is formed by photolithographing and etching a thin copper foil which is stuck to the dielectric board
1
. Also, in a conventional planar type of a transmission waveguide structure, it is difficult to make an aspect ratio of each line conductor larger than 1 even by any method of a plating, printing or etching.
As a signal processing ability such as a microprocessor has been improved by a high-integrating technique of semiconductor IC year by year, a wiring board provided with such a microprocessor requires a severe condition for improvement of wiring density and transmission characteristics as following.
The first problem is to improve a wiring density. When a number of connection terminals of a semiconductor chip and a package is increased, a higher wiring density on the wiring board is required. The wiring density for one wiring board can be improved by multilayering, but the multilayering causes a high cost due to an increase in a number of layers and an increase in an area for via wiring. For this reason, the improvement in the wiring density for one layer is essentially required.
The second problem is to improve transmission characteristics of a transmission waveguide structure. A signal bus construction is particularly important in wiring, and an influence of a noise such as a reflection and a cross-talk becomes large due to a higher speed of a signal rate. Therefore, improvement of a wiring structure is required, reducing unevenness in characteristic impedance of the transmission line conductors when manufacturing the wiring board together with lowering a cross-talk.
In order to increase a wiring density of transmissi

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