The embodiment of the invention is about a novel via structure which can be incorporated into printed circuit boards, integrated circuit packages, and integrated circuits in order to reduce crosstalk, to improve signal integrity and to achieve EM emission compliance. A 4-layer (2 signal layers and 2 power layers or 2 signal layers and 2 ground layers) circuit board assembly was used for demonstrating the effect of the novel via structure. The same concept can be applied to any multi-layer circuit board. layers that have an electrical property can be added above, under, or within the basic 4-layer circuit board to achieve a multi-layer circuit board. For 2-layer and 3-layer circuit boards, a deformed version of the proposed via structure based upon the same concept will be needed for a coplanar waveguide configuration.
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7. A via structure, comprising:
a circuit board having multiple power planes, ground planes and medium layers, wherein a power via or a ground via passes through the power planes, ground planes and medium layers along a same axis, and wherein a signal via passes through the medium layers around a power or the ground via;
one of the multiple power planes or the ground planes connects with a different power plane or the ground via plane through the power via or the ground via;
the power via or the ground via may connect all of the multiple power planes or the ground planes with same potential;
the power via or the ground via is cylindrical and the thickness of the power via or the ground via is larger than the skin depth at the frequency of the signal; and
when a signal going through the signal via, the signal goes through the signal via with complete impedance continuity.
1. A via structure in a circuit board or substrate having multiple layers, from top to bottom comprising:
a first power plane or a first ground plane in the first layer;
a first medium in a second layer;
a first signal trace in a third layer;
a second medium in a fourth layer;
a second signal trace in a fifth layer;
a third medium in a sixth layer;
a second power plane or a second ground plane in a seventh layer;
a power via or a ground via passing through the first medium, the first signal trace, the second medium, the second signal trace, and the third medium, wherein the first power plane or the first ground plane is connected with the second power plane or the second ground plane through the power via or the ground via;
a signal via passing through the second medium around the power via or the ground via, and the first signal trace is connected with the second signal trace through the signal via; and
an anti-pad is located between the signal via and the power via or a ground via,
wherein the power via or the ground via is cylindrical and the thickness of the power via or the ground via is larger than the skin depth at the frequency of the signal; and
when a signal going through a path from the first signal trace through the signal via to the second signal trace, the signal goes through the path with complete impedance continuity.
2. The via structure of
3. The via structure of
4. The via structure of
5. The via structure of
6. The via structure of
8. The via structure of
9. The via structure of
10. The via structure of
11. The via structure of
12. The via structure of
13. The via structure of
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The invention relates to an application that is entitled “Circuit Board Via Structure for High Speed Signaling,” (Publication NO.: US 20006/0237227 A1), which is filed presently with the U.S. Patent & Trademark Office, and which is used herein for reference in its entirety.
The embodiments of this invention relate to printed circuit boards and integrated circuit packaging boards, and in particular to a novel via structure for improving the signal integrity and reducing the EMC/EMI problem. The novel via structure can be incorporated into a variety of integrated, as well as other types of circuits.
In multilayer printed circuit boards, integrated circuit packages, and integrated circuits on dies, there are many situations in which signals need to switch from layer to layer.
This impedance discontinuity will affect the signal quality as well. The dashed lines of
From
Again, the impedance along the signal trace will be different from that along the signal via. This impedance discontinuity will also affect the signal quality. The dashed lines of
The embodiment of the invention is about a novel via structure which can be incorporated into printed circuit boards, integrated circuit packages, and integrated circuits in order to reduce crosstalk, to improve signal integrity and to achieve EM emission compliance. A 4-layer (2 signal layers and 2 power layers or 2 signal layers and 2 ground layers) circuit board assembly was used for demonstrating the effect of the novel via structure. The same concept can be applied to any multi-layer circuit board. Layers that have an electrical property can be added above, under, or within the basic 4-layer circuit board to achieve a multi-layer circuit board. For 2-layer and 3-layer circuit boards, a deformed version of the proposed via structure based upon the same concept will be needed for a coplanar waveguide configuration.
The 4-layer circuit board can be separated into 3 types of circuit structures.
Type A (see
Type B (see
Type C (see
TABLE 1
The elements of FIG. 1
Printed circuit board (PCB) or substrate or die
1
The first signal trace in first layer
2
The signal via
3
The first medium in the second layer
4
The second medium in the fourth layer
5
The third medium in the sixth layer
6
The first power plane or ground plane in the third layer
7
The second power plane or ground plane in the fifth layer
8
The second signal trace in the seventh layer
9
Anti-pad
10
TABLE 2
The elements of FIG. 2
Printed circuit board (PCB) or substrate or die
11
The first signal trace in the first layer
12
The signal via
13
The power via (or ground via)
14
The first medium in the second layer
15
The second medium in the fourth layer
16
The third medium in the sixth layer
17
The first power plane (or ground plane) in the third layer
18
The second power plane (or ground plane) in the fifth layer
19
The second signal trace in the seventh layer
20
Anti-pad
21
TABLE 3
The elements of FIG. 3
Printed circuit board (PCB) or substrate or die
22
The first signal trace in the third layer
23
The signal via
24
The first medium in the second layer
25
The second medium in the fourth layer
26
The third medium in the sixth layer
27
The first power plane or ground plane in the first layer
28
The second power plane or ground plane in the seventh layer
29
The second signal trace in the fifth layer
30
TABLE 4
The elements of FIG. 4
Printed circuit board (PCB) or substrate or die
31
The first power plane (or ground plane) in the first layer
32
The signal via
33
The power via (or ground via)
34
The first medium in the second layer
35
The second medium in the fourth layer
36
The third medium in the sixth layer
37
The first signal trace in the third layer
38
The second signal trace in the fifth layer
39
The second power plane (or ground plane) in the seventh layer
40
Anti-pad
41
The purpose of the invention is to provide a novel via structure that can reduce via-to-via crosstalk, the impedance discontinuity, and EMC radiation. In particular, the signal integrity will be improved and the edge radiation of the PCB board or IC packaging will be minimized.
A 4-layer (2 signal layers and 2 power layers or 2 ground layers) circuit board with a single via structure is used for demonstrating the interest of the invention. The 4-layer circuit board is comprised of 2 signal layers, 3 medium layers, 2 power layers (or 2 ground layers), and a via structure. The signal via electrically connects the signal traces on the different layers. The power via or ground via could be built outside the signal via (see
Four circuit structures (
The via structures that passes through the substrate 11 can be formed by mechanical Or laser drilling. The via hole can be a “blind hole” or “through hole”. First, the power blind via (or ground blind via) 14 is formed in order to connect the two power layers (or the two ground layers). The material of the power via (or ground via) can be any highly conductive alloy or metal such as Tin (Sn), silver (Ag), copper (Cu), gold (Au). The signal layer 12 is then electrically connected with the signal layer 20 through the signal via 13. Any techniques such as casting, plating, or non-plating can be adapted for the formation of any via in the embodiments of the invention.
The power via (or ground via) 14 is plated with copper in this example of the invention. The signal via 13 and the power via (or ground via) 14 are circular and concentric. However, they do not necessarily have to be circular or concentric. For example, the signal via 13 can be a solid cylinder or a hollow cylinder non-centric with the power via (ground via) 14. Also, the signal via 13 must be kept at least a distance equal to the size of the anti-pad from the power via (or ground via) 14. The thickness of the power via (or ground via) 14 must be larger than the “skin depth” associated with the frequency of the signal propagating along the signal via 13. The skin depth describes the fact that any current flowing in a conductor will migrate toward the surface or “skin” of the conductor when the signal frequency gets higher. As a result, most of the current will be concentrated within the skin depth of the conductor. The skin depth δs=(2/ωμσ){circumflex over (0)}(½), where ω is the frequency of the signal, μ is the permeability of the conductor, and σ is the conductivity of the conductor. Therefore, if the conductor is thick enough, the EM wave generated by the signal via will not penetrate through the power via (or ground via). As a result, the insertion loss (S21) due to radiation emitted by the signal via will be minimized and, consequently, the via-to-via coupling will be reduced. Therefore, the signal integrity will be improved.
Again, the via structures passing through the substrate 31 can be formed by mechanical or laser drilling. The via hole can be a “blind hole” or a “through hole”. First, the signal blind via 33 is formed to connect electrically the signal layer 38 and the signal layer 39. The power through via (or ground through via) 34 then is formed to connect the two power layers (or the two ground layers) 32 and 40. The power via (or ground via) 34 can be plated to form a circular annular tube or filled with copper to form a solid cylinder. The material of the power via (or ground via) can be any conductive alloy or metal such as Tin (Sn), silver (Ag), copper (Cu), gold (Au). Any standard technique such as casting, plating, or non-plating can be adapted for the formation of any via in the embodiments of the invention.
The signal via 33 is plated with copper in this example. The signal via 33 and the power via (or ground via) 34 are circular and concentric. However, it is not necessary that they be a circular annular tube or that they be concentric. For example, the power via (ground via) 34 can be a cylindrical ring, solid cylinder, or polygon ring which can be concentric or not with the signal via 33. Also, the signal via 33 must be kept at least a distance equal to the size of the anti-pad from the power via (or ground via) 34. The thickness of the power via (or ground via) 34 must be larger than the “skin depth” associated with the frequency of the signal propagating along the signal via 33. Therefore, most of the return current induced by the signal via will propagate along the power via (or ground via) 34 instead of propagating partially along the power via (or ground via) 34 and partially through the medium (not shown). The insertion loss (S21) due to the metal losses in the power via (or ground via) will be minimized The via-to-via EM coupling will be reduced as well. Finally, the signal integrity will be improved.
The construction of the novel via structure shown in
Simulations were explored with printed circuit board (PCB) and integrated circuit packaging to confirm the performance of the two types of via structures that comprise the invention: type A (see
Similarly,
The embodiments of the invention comprise the improved via structures (the additional power via or ground via), both via types having the same method of fabrication. The power via (or ground via) will connect the two power planes (or the two ground planes). It provides the shortest current return path and reduces the impedance discontinuity. The thickness of the power via (or ground via) must be larger than the skin depth associated with the frequency of the signal. Therefore, the EM waves generated by the signal via will not penetrate through the power via (or ground via). Therefore, the insertion loss will be improved. Also, the EM field will be concentrated between the signal via and power via (or ground via) and, consequently, the signal via will couple less energy with any other via. As a result, the signal integrity will be improved.
In short, the inventive concepts unveiled herein are the basic examples and can be modified. Any modification based any extension of the inventive concepts fall within the scope of the appended claims and their equivalents; and consequently, they should be covered by this patent.
Hsu, Hsiuan-ju, Ziolkowski, Richard Walter
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