Latch-up suppression and substrate noise coupling reduction through a substrate back-tie for 3D integrated circuits
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-017/50
H01L-023/48
H01L-021/768
H01L-023/00
출원번호
US-0601394
(2012-08-31)
등록번호
US-9190346
(2015-11-17)
발명자
/ 주소
Moroz, Victor
Kawa, Jamil
출원인 / 주소
SYNOPSYS, INC.
대리인 / 주소
Haynes Beffel & Wolfeld LLP
인용정보
피인용 횟수 :
0인용 특허 :
31
초록▼
Roughly described, an integrated circuit device has a conductor extending entirely through the substrate, connected on one end to the substrate topside surface and on the other end to the substrate backside surface. In various embodiments the conductor is insulated from all RDL conductors on the bac
Roughly described, an integrated circuit device has a conductor extending entirely through the substrate, connected on one end to the substrate topside surface and on the other end to the substrate backside surface. In various embodiments the conductor is insulated from all RDL conductors on the backside of the substrate, and/or is insulated from all conductors and device features on any below-adjacent chip in a 3D integrated circuit structure. Methods of fabrication are also described.
대표청구항▼
1. A non-transitory computer-readable storage medium storing instructions that, when executed by a processor, cause a computer system to perform a method for developing a three-dimensional integrated circuit, the method comprising: writing to a non-transitory computer-readable storage medium one or
1. A non-transitory computer-readable storage medium storing instructions that, when executed by a processor, cause a computer system to perform a method for developing a three-dimensional integrated circuit, the method comprising: writing to a non-transitory computer-readable storage medium one or more layout files for a plurality of integrated circuit chips stacked vertically in a fixed structure, the plurality of integrated circuit chips including a first chip having opposite topside and backside surfaces, the layout files defining mask elements for a transistor in the first chip; andwherein the layout files further define mask elements for a first conductor extending entirely through the first chip, the first conductor being electrically connected on a first end to a first point on the first chip topside surface and on a second end to a second point on the first chip backside surface,the layout files being provided for fabrication of the plurality of integrated circuit chips. 2. The non-transitory computer storage medium according to claim 1, wherein the first chip comprises a p-type lightly doped substrate, and wherein the layout files further define a p-type heavily doped contact pad at the first chip topside surface, the first point being on the p-type heavily doped contact pad. 3. The non-transitory computer storage medium according to claim 1, wherein the layout files further define an opening in an insulating layer on the backside surface of the first chip, the opening exposing both the second end of the first conductor and a particular region of the first chip on the backside thereof such that conductive material in the opening electrically connects the second end of the first conductor with the particular region. 4. A method for designing a three-dimensional integrated circuit, comprising the steps of: using a computer system, developing a layout for a first chip of the three-dimensional integrated circuit in dependence upon a provided integrated circuit design for the first chip, the first chip having a first substrate having opposite topside and backside surfaces; andproviding the layout for fabricating the first chip, wherein the layout identifies mask features for: forming a transistor in the first chip,forming a first conductor extending entirely through the first substrate, andforming a conductive path electrically connecting a first end of the first conductor to a first point on the first substrate topside surface and a second end of the first conductor to a second point on the first substrate backside surface,wherein the first substrate comprises a p-type lightly doped substrate,wherein the layout further identifies one or more mask features for forming a p-type heavily doped contact pad at the first substrate topside surface,and wherein the first point is on the p-type heavily doped contact pad. 5. A method for designing a three-dimensional integrated circuit, comprising the steps of: using a computer system, developing a layout for a first chip of the three-dimensional integrated circuit in dependence upon a provided integrated circuit design for the first chip, the first chip having a first substrate having opposite topside and backside surfaces; andproviding the layout for fabricating the first chip, wherein the layout identifies mask features for: forming a transistor in the first chip,forming a first conductor extending entirely through the first substrate, andforming a conductive path electrically connecting a first end of the first conductor to a first point on the first substrate topside surface and a second end of the first conductor to a second point on the first substrate backside surface,wherein the first chip further comprises an insulating layer on the backside surface of the first substrate,and wherein the layout further identifies one or more mask features for forming an opening in the insulating layer, exposing both the second end of the first conductor and a particular region of the first substrate on the backside thereof. 6. The method of claim 5, wherein the layout further identifies one or more mask features for forming a conductive material in the opening electrically connecting the second end of the first conductor with the particular region. 7. A method for designing a three-dimensional integrated circuit, comprising the steps of: using a computer system, developing a layout for a first chip of the three-dimensional integrated circuit in dependence upon a provided integrated circuit design for the first chip, the first chip having a first substrate having opposite topside and backside surfaces; andproviding the layout for fabricating the first chip, wherein the layout identifies mask features for: forming a transistor in the first chip,forming a first conductor extending entirely through the first substrate, andforming a conductive path electrically connecting a first end of the first conductor to a first point on the first substrate topside surface and a second end of the first conductor to a second point on the first substrate backside surface,wherein the layout further identifies one or more mask features for forming:an additional TSV passing through the first substrate, the first chip having an insulating layer on the backside surface of the first substrate;a plurality of RDL conductors on the backside of the insulating layer; anda via in the insulating layer for electrically connecting the additional TSV to one of the RDL conductors on the backside of the insulating layer,the layout lacking mask features for forming any vias for electrically connecting the first conductor to any RDL conductors on the backside of the first chip. 8. A method for designing a three-dimensional integrated circuit, comprising the steps of: using a computer system, developing a layout for a first chip of the three-dimensional integrated circuit in dependence upon a provided integrated circuit design for the first chip, the first chip having a first substrate having opposite topside and backside surfaces; andproviding the layout for fabricating the first chip, wherein the layout identifies mask features for: forming a transistor in the first chip,forming a first conductor extending entirely through the first substrate, andforming a conductive path electrically connecting a first end of the first conductor to a first point on the first substrate topside surface and a second end of the first conductor to a second point on the first substrate backside surface,wherein the layout further identifies one or more mask features for forming:an additional TSV passing through the first chip, the first chip having an insulating layer on the backside surface of the first substrate; anda conductor electrically connecting the additional TSV to a conductor on an additional integrated circuit chip located on the backside of the insulating layer,wherein the layout does not identify any mask features for electrically connecting the first conductor to any conductor on the additional integrated circuit chip. 9. A method for designing an integrated circuit device, comprising: using a computer system, developing a layout for the device in dependence upon a provided integrated circuit design for the device, the device having a first substrate having opposite topside and backside surfaces and an insulating layer on the backside surface; andproviding the layout for fabricating the first chip, wherein the layout identifies mask features for forming: a first TSV extending entirely through the first substrate,an additional TSV passing entirely through the first substrate,a conductive path electrically connecting the first TSV on a first end to a first point on the first substrate topside surface,a plurality of RDL conductors on the backside of the insulating layer, andvias in the insulating layer for electrically connecting the additional TSV to one of the RDL conductors on the backside of the insulating layer but not for electrically connecting the first TSV to any RDL conductors on the backside of the first substrate. 10. A method for designing a first integrated circuit device having a first semiconductor substrate having opposite topside and backside surfaces, and an additional integrated circuit device on the backside of the first semiconductor substrate, comprising: using a computer system, developing a layout for the first and additional devices in dependence upon a provided integrated circuit design; andproviding the layout for fabricating the first and additional devices, wherein the layout identifies mask features for forming:a transistor in the first substrate;a first conductor extending entirely through the first substrate, anda conductive path electrically connecting a first end of the first conductor to a first point on the first substrate topside surface,wherein the layout does not identify any mask features for electrically connecting the first conductor to any conductor on the additional integrated circuit device. 11. The method of claim 10, wherein the layout further identifies one or more mask features for forming: an additional TSV passing through the first substrate;elements electrically connecting the additional TSV to a conductor on the additional device. 12. A method for designing a three-dimensional integrated circuit having a plurality of integrated circuit chips stacked vertically in a fixed structure, the plurality of chips including a first chip having a first substrate having opposite topside and backside surfaces, the method comprising: using a computer system, developing a layout for at least the first chip in the plurality of chips, in dependence upon a provided integrated circuit design; andproviding the layout for fabricating at least the first chip,wherein the layout identifies mask features for forming a transistor in the first substrate and for forming a first conductor extending entirely through the first substrate, the first conductor being electrically connected on a first end to a first point on the first substrate topside surface and on a second end to a second point on the first substrate backside surface. 13. The method of claim 12, wherein the first chip has an insulating layer on the backside of the first substrate, wherein the layout further identifies mask features for forming: an additional TSV passing entirely through the first substrate,a plurality of RDL conductors on the backside of the insulating layer, andvias in the insulating layer for electrically connecting the additional TSV to one of the RDL conductors on the backside of the insulating layer,the insulating layer having no vias for electrically connecting the first conductor to any RDL conductors on the backside of the first insulating layer. 14. A method for designing a three-dimensional integrated circuit having a plurality of integrated circuit chips stacked vertically in a fixed structure, the plurality of chips including a first chip having opposite topside and backside surfaces, the method comprising: using a computer system, developing a layout for at least the first chip in the plurality of chips, in dependence upon a provided integrated circuit design; andproviding the layout for fabricating at least the first chip,wherein the layout identifies mask features for forming: a transistor in the first chip;a first conductor extending entirely through the first chip,a conductive path electrically connecting a first end of the first conductor to a first point on the first chip topside surface;a plurality of RDL conductors on the backside of the first chip; andan insulating layer on the backside of the first chip insulating the first conductor from all RDL conductors on the backside of the first chip. 15. A method for designing a three-dimensional integrated circuit having a plurality of integrated circuit chips stacked vertically in a fixed structure, the plurality of chips including a first chip having opposite topside and backside surfaces and an additional chip stacked adjacent to the backside of the first chip, the method comprising: using a computer system, developing a layout for at least the first chip and the additional chip, in dependence upon a provided integrated circuit design; andproviding the layout for fabricating at least the first chip,wherein the layout identifies mask features for forming: a transistor in the first chip;a first conductor extending entirely through the first chip; anda conductive path electrically connecting a first end of the first conductor to a first point on the first chip topside surface,and wherein the layout does not identify any mask features for electrically connecting the first conductor to any conductor on the additional chip. 16. A method for defining a mask set for a first integrated circuit chip, comprising: a computer system developing a layout for a first chip in dependence upon a provided integrated circuit design, the first chip having opposite topside and backside surfaces,wherein the layout identifies mask features for: forming a transistor in the first chip;forming a first conductor extending entirely through the first chip, andforming a conductive path electrically connecting a first end of the first conductor to a first point on the first chip topside surface and a second end of the first conductor to a second point on the first chip backside surface,wherein the layout further identifies mask features for insulating the first conductor from any RDL conductor to be formed on the backside of the first chip and from any additional integrated circuit chip to be attached to the backside of the first chip. 17. A method for designing a three-dimensional integrated circuit, comprising the steps of: using a computer system, developing a layout for a first chip of the three-dimensional integrated circuit in dependence upon a provided integrated circuit design for the first chip, the first chip having a first substrate having opposite topside and backside surfaces; andproviding the layout for fabricating the first chip, wherein the layout identifies mask features for: forming a transistor in the first chip;forming a first conductor extending entirely through the first substrate, andforming a conductive path electrically connecting a first end of the first conductor to a first point on the first substrate topside surface and a second end of the first conductor to a second point on the first substrate backside surface,wherein the layout further identifies mask features for forming:a plurality of RDL conductors on the backside of the first chip; andan insulating layer on the backside of the first substrate insulating the first conductor from all RDL conductors on the backside of the first chip.
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