Systems and methods for blocking microwave propagation in parallel plate structures utilizing cluster vias
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H01P-007/00
H05K-007/00
출원번호
US-0828542
(2004-04-19)
발명자
/ 주소
McKinzie, III,William E.
출원인 / 주소
Wemtec, Inc.
대리인 / 주소
Heller Ehrman LLP
인용정보
피인용 횟수 :
15인용 특허 :
38
초록▼
Systems and methods are taught for blocking the propagation of electromagnetic waves in parallel-plate waveguide (PPW) structures. Periodic arrays of resonant vias are used to create broadband high frequency stop bands in the PPW, while permitting DC and low frequency waves to propagate. Particula
Systems and methods are taught for blocking the propagation of electromagnetic waves in parallel-plate waveguide (PPW) structures. Periodic arrays of resonant vias are used to create broadband high frequency stop bands in the PPW, while permitting DC and low frequency waves to propagate. Particular embodiments include clusters of small vias that effectively function as one large via, thereby increasing stop band bandwidth and maximizing parallel plate capacitance. Cluster vias can be configured to additionally provide a shielded and impedance matched route within the interior area of the cluster through which signal vias can connect transmission lines disposed in planes lying above and below the PPW. Important applications include electromagnetic noise reduction in layered electronic devices such as circuit boards, ceramic modules, and semiconductor chips.
대표청구항▼
What is claimed: 1. A cluster resonator, comprising: a first conducting plane; a second substantially parallel conducting plane; a cluster of vias of essentially uniform length oriented substantially normal to the conducting planes each via in the cluster comprising a first end and a second end; a
What is claimed: 1. A cluster resonator, comprising: a first conducting plane; a second substantially parallel conducting plane; a cluster of vias of essentially uniform length oriented substantially normal to the conducting planes each via in the cluster comprising a first end and a second end; a first conducting pad disposed in a third plane substantially parallel and capacitively coupled to the first conducting plane and physically coupled with the vias of the cluster of vias proximate their first ends; and a second conducting pad disposed in a fourth plane substantially parallel and capacitively coupled to the second conducting plane and physically coupled with the vias of the cluster of vias proximate their second ends, wherein the vias are physically connected to only the first and second conducting pads; and wherein a combined inductance and capacitance of the cluster of vias form an electromagnetically resonant shunt circuit between the first and second conducting planes; and wherein the vias of the cluster of vias are disposed along a perimeter that defines an interior region and one or more interior vias are routed within the interior region of the cluster of vias; and wherein the interior vias comprise portions of transmission lines passing electrical signals through the cluster resonator. 2. A cluster resonator, comprising: a first conducting plane; a second substantially parallel conducting plane; a cluster of vias of essentially uniform length oriented substantially normal to the conducting planes, each via in the cluster comprising a first end and a second end; a first conducting pad disposed in a third plane substantially parallel and capacitively coupled to the first conducting plane and physically coupled with the vias of the cluster of vias proximate their first ends; and a second conducting pad disposed in a fourth plane substantially parallel and capacitively coupled to the second conducting plane and physically coupled with the vias of the cluster of vias proximate their second ends, wherein the vias are physically connected to only the first and second conducting pads; and wherein the first or second conducting pad is external relative to the first and second conducting planes. 3. The cluster resonator of claim 1, wherein the first or second conducting pad is internal relative to the first and second conducting planes. 4. The cluster resonator of claim 1, wherein the first and second conducting pads are internal relative to the first and second conducting planes. 5. The cluster resonator of claim 1, wherein the first and second conducting pads are external relative to the first and second conducting planes. 6. The cluster resonator of claim 1 or 2, wherein its topology comprises a mechanically balanced structure. 7. The cluster resonator of claim 1 or 2, wherein the first and second conducting planes are metallic layers incorporated with a multi-layered panel circuit. 8. The cluster resonator of claim 7, wherein the multi-layered panel circuit is a multi-layered printed circuit board and the cluster resonator comprises an array of plated through holes. 9. The cluster resonator of claim 7, wherein the multi-layered panel circuit is a multi-chip module. 10. The cluster resonator of claim 7, wherein the multi-layered panel circuit is a semiconductor chip. 11. The cluster resonator of claim 1, wherein the cluster of vias is disposed along a circular path. 12. The cluster resonator of claim 1, wherein the cluster of vias is disposed along an elliptical path. 13. The cluster resonator of claim 1, wherein the cluster of vias is disposed along a polygonal path. 14. The cluster resonator of claim 1, wherein spacing of vias within the cluster of vias effects a Faraday cage that substantially shields the interior region from RF fields propagating within the first and second conducting planes. 15. The cluster resonator of claim 14, wherein spacing of the vias within the cluster of vias in relation to the interior vias effects a predetermined line impedance in the interior vias. 16. A cluster resonator, comprising: a first conducting plane; a second substantially parallel conducting plane; a cluster of vias of essentially uniform length oriented substantially normal to the conducting planes, each via in the cluster comprising a first end and a second end; first ends of each via in the cluster of vias coupled with the first conducting plane; and a first conducting pad disposed in a third plane parallel and external to the region between the first and second conducting planes and capacitively coupled to the second conducting plane and physically coupled to each via in the cluster of vias proximate their second ends, wherein the vias in the cluster of vias are physically connected to only the first conducting plane and the first conducting pad. 17. The cluster resonator of claim 16, wherein a combined inductance and capacitance of the cluster of vias form an electromagnetically resonant shunt circuit between the first and second conducting planes. 18. The cluster resonator of claim 16, wherein the vias of the cluster of vias are disposed along a perimeter that defines an interior region. 19. The cluster resonator of claim 18, wherein one or more interior vias are routed within the internal region of the cluster of vias. 20. The cluster resonator of claim 19, wherein the interior vias comprise portions of transmission lines passing electrical signals through the resonant element. 21. The cluster resonator of claim 16 comprising a second cluster of vias, each via in the second cluster of vias comprising a first end and a second end, wherein the vias in the second cluster of vias are coupled proximate their first ends to the second conducting plane and proximate their second ends to a second conducting pad disposed in a fourth plane parallel and external to the region between the first and second conducting planes and capacitively coupled to the first conducting plane, wherein the vias in the cluster of vias are physically connected to only the second conducting plane and the second conducting pad. 22. The cluster resonator of claim 21 wherein its topology comprises a mechanically balanced structure. 23. The cluster resonator of claim 16, wherein the first and second conducting planes are metallic layers incorporated with a multi-layered panel circuit. 24. The cluster resonator of claim 23, wherein the multi-layered panel circuit is a multi-layered printed circuit board and the cluster resonator comprises an array of plated through holes. 25. The cluster resonator of claim 16, wherein the multi-layered panel circuit is a multi-chip module. 26. The cluster resonator of claim 16, wherein the multi-layered panel circuit is a semiconductor chip. 27. The cluster resonator of claim 18, wherein the cluster of vias is disposed along a circular path. 28. The cluster resonator of claim 18, wherein the cluster of vias is disposed along an elliptical path. 29. The cluster resonator of claim 18 wherein the cluster of vias is disposed along a polygonal path. 30. The cluster resonator of claim 19, wherein spacing of the vias of the cluster of vias effects a Faraday cage that substantially shields the interior region from RF fields propagating within the first and second conducting planes. 31. The cluster resonator of claim 30, wherein spacing of the vias of the cluster of vias in relation to the interior vias effects a predetermined line impedance in the interior vias. 32. The cluster resonator of claims 1 or 6, further comprising a plurality of resonant vias and associated first and second conducting pads disposed in a periodic array associated with the first and second conducting planes. 33. The cluster resonator of claim 16, further comprising a plurality of resonant vias and associated first conducting pads disposed in a periodic array associated with the first and second conducting planes. 34. The cluster resonator of claims 1 or 6, wherein a diameter of the vias of the cluster of vias is selected to effect a predetermined inductance. 35. The cluster resonator of claim 16, wherein a diameter of the vias of the cluster of vias is selected to effect a predetermined inductance. 36. A cluster resonator comprising: a first conducting plane; a second substantially parallel conducting plane; a first conducting pad disposed in a third substantially parallel plane internal to the region between the first and second conducting planes; a first cluster of vias oriented substantially normal to the first conducting plane and first conducting pad and disposed therebetween, each via of the cluster having a first end and a second end, wherein the first and second ends are physically connected respectively to the first conducting plane and first conducting pad; and a second conducting pad disposed in a fourth substantially parallel plane internal to the region between the first and second conducting planes; a second cluster of vias oriented substantially normal to the second conducting plane and second conducting pad and disposed therebetween, each via of the cluster having a first end and a second end, wherein the first and second ends are physically connected respectively to the second conducting plane and second conducting pad; and wherein the first and second conducting pads are proximate and capacitively coupled to each other; and wherein the vias of the clusters of vias are disposed along a common perimeter thereby forming substantially field free interior regions therewithin; and wherein one or more electrically isolated interior vias traverse the interior regions of the clusters of vias, the interior vias comprising portions of transmission lines for passing electrical signals therethrough. 37. The cluster resonator of claim 36, wherein a spacing of the vias of the clusters of vias in relation to the interior vias is selected to effect a predetermined line impedance in the interior vias. 38. The cluster resonator of claim 36, wherein a diameter of the vias of the clusters of vias is selected to effect a predetermined inductance. 39. The cluster resonator of claim 36, wherein the common perimeter is circular. 40. The cluster resonator of claim 36, wherein the common perimeter is elliptical. 41. The cluster resonator of claim 36, wherein the common perimeter is polygonal. 42. The cluster resonator of claim 36, wherein the first and second conducting planes are metallic layers incorporated within a multi-layered panel circuit. 43. The cluster resonator of claim 42, wherein the multi-layered panel circuit is a multi-layered printed circuit board and the cluster resonator comprises an array of plated through holes. 44. The cluster resonator of claim 42, wherein the multi-layered panel circuit is a multi-chip module. 45. The cluster resonator of claim 42, wherein the multi-layered panel circuit is a semiconductor chip.
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