Claims
- 1. An acceleration sensor chip comprising a support frame part, and a sensor structure including at least one displaceable weight part and a beam part for connecting said weight part to said support frame part, said support frame part and said sensor structure being formed on a silicon substrate through an insulating layer,
wherein said insulating layer between said sensor structure and said silicon substrate is removed, said beam part comprising a plurality of sets of beams which are parallel to each other, said weight part is connected to said support frame part by said plurality of sets of parallel beams, and at least two semiconductor strain gauges are formed on the surface of at least one set of said plurality of sets of parallel beams.
- 2. The acceleration sensor chip as claimed in claim 1, wherein said weight part is one unit, said plurality of sets of parallel beams are protrudingly formed to four corner parts of said weight part, four semiconductor strain gauges are respectively formed on the surfaces of said plurality of sets of beams, whereby forming a Wheatstone bridge.
- 3. The acceleration sensor chip as claimed in claim 1, wherein two units of said weight parts are provided, said plurality of sets of parallel beams are formed between said two weight parts and said support frame part, and between said two weight parts,
characterized in that at least one semiconductor strain gauge is formed on each surface of at least one of beams between one of said two weight parts and said support frame part of said plurality of sets of parallel beams, at least one of beams between the other of said two weight parts and said support frame part of said plurality of sets of parallel beams, and a beam between said two weight parts, thereby forming a Wheatstone bridge.
- 4. The acceleration sensor chip as claimed in claim 1, wherein thickness of said beam part is smaller than that of said weight part.
- 5. An acceleration sensor chip comprising a support frame part, and a sensor structure including a displaceable weight part having a magnetic thin film formed on the surface and at least one beam part for connecting said weight part to said support frame part, said support frame part and said sensor structure being formed on a silicon substrate through an insulating layer,
wherein said insulating layer between said sensor structure and said silicon substrate is removed, and on said support frame part on the periphery of said weight part, a coil is formed to surround said weight part.
- 6. An acceleration sensor chip comprising a support frame part, and a plurality of sensor structures including displaceable weight parts respectively having magnetic films formed on the surfaces and beam parts for connecting said weight parts to said support frame part, said support frame part and said sensor structures being formed on a silicon substrate through an insulating layer,
wherein said insulating layer between said plurality of sensor structures and said silicon substrate is removed, coils are respectively formed surrounding said weight parts on said support frame part on the periphery of said respective weight parts, and said plurality of coils are connected in series.
- 7. An acceleration sensor chip comprising a plurality of sensor groups formed on a same semiconductor chip, wherein said plurality of sensor groups respectively comprising said plurality of sensor structures and said plurality of detection coils connected in series described in claim 6 and differing in numbers of sensor structures and detection coils between said plurality of sensor groups.
- 8. The acceleration sensor chip as claimed in any one of claims 1, 5 and 6, further comprising means for performing a self diagnosis.
- 9. The acceleration sensor chip as claimed in any one of claims 1, 5 and 6, wherein an amplifier circuit and a digital adjustment circuit are formed on said semiconductor chip on which said acceleration sensor chip is formed.
- 10. An angular acceleration sensor chip comprising a first sensor group including a first support frame part, and a plurality of first sensor structures comprising displaceable first weight parts having magnetic thin films formed on the respective surfaces and first beam parts for connecting said first weight parts to said first support part, said first support frame part and said first sensor structures being formed on a silicon substrate through an insulating layer, wherein said insulating layer between said plurality of first sensor structures and said silicon substrate is removed, first detection coils are respectively formed surrounding said first weight parts on said first support frame part at the respective periphery of said first weight parts, and said plurality of first detection coils are connected in series;
a second sensor group including a second support frame part, and a plurality of second sensor structures comprising displaceable second weight parts having magnetic thin films formed on the respective surfaces and second beam parts for connecting said second weight parts to said second support frame part, said second support frame part and said second sensor structures being formed on said silicon substrate through an insulating layer, wherein said insulating layer between said plurality of second sensor structures and said silicon substrate is removed, second detection coils are respectively formed surrounding said second weight parts on said second support part at the respective periphery of said second weight parts, and said plurality of second detection coils are connected in series, said first and second sensor groups being formed into a chip; wherein said first sensor group and said second sensor group are equal in number of sensor structures, and said first sensor group and said second sensor group are disposed symmetrically about a detection axis as an axis of symmetry; said first and second detection coils of said first and second sensor groups form closed loops so that currents flowing through said plurality of first and second detection coils of said first and second sensor groups are same in direction when an angular acceleration generates about said detection axis; and means for amplifying signals from said plurality of first and second detection coils and means for integrating outputs from said plurality of detection coils to output an angular acceleration signal.
- 11. An acceleration sensor chip characterized in that a third layer is formed on a first layer of a support substrate through an insulating second layer, said third layer having a sensor structure,
said second layer between a detection surface of said sensor structure and said first layer is removed, and a beam part having a detection device, and a weight part having a plurality of cutouts of a same width formed over the entire surface are provided on said detection surface of said sensor structure with said second layer removed.
- 12. The acceleration sensor chip as claimed in claim 11, wherein a film of a material smaller in thermal expansion coefficient than material of said first layer is formed on a backside of said first layer.
- 13. The acceleration sensor chip as claimed in claim 11, wherein said same width of said plurality of cutouts formed on said sensor structure is 2 μm or less.
- 14. The acceleration sensor chip as claimed in claim 11, wherein as a substrate comprising said first layer, said second layer and said third layer, an SOI (silicon-on-insulator) wafer is used, or a wafer having polysilicon formed as said third layer on a single crystal silicon substrate through an insulation layer is used.
- 15. A production method of an acceleration sensor chip characterized by comprising:
(a) a step for preparing a SOI wafer comprising a silicon substrate, a SiO2 layer and a silicon thin film; (b) a step for ion implanting a dopant at a position corresponding to a semiconductor strain gauge of said silicon thin film to form a diffusion resistor, and forming devices necessary for circuit construction on said silicon thin film; (c) a step for providing a protective film on the entire surface of said wafer, opening a plurality of through holes penetrating said silicon thin film by patterning and etching, and forming a weight part and a beam part connecting to a support frame part remained on the periphery; (d) while remaining said protective film, as is, for forming said plurality of through holes, a step for removing by wet etching said SiO2 layer under said weight part and said beam part; (e) a step for removing said protective film, and coating a resist over the entire surface of said wafer; (f) a step for forming a slit by dicing for dividing said chip while remaining a small thickness of said wafer; (g) a step for removing by ashing said resist on said wafer by an O2 plasma; and (h) a step for dividing said chip at concentrating a stress on said slit.
- 16. A production method of an angular acceleration sensor chip characterized by comprising:
(a) a step for preparing a SOI wafer comprising a silicon substrate, a SiO2 layer and a silicon thin film; (b) a step for ion implanting a dopant at a position corresponding to a semiconductor strain gauge of said silicon thin film to form a diffusion resistor, forming a magnetic thin film at a position corresponding to a weight part, forming a detection coil surrounding said magnetic thin film, and forming devices necessary for circuit construction on said silicon thin film; (c) a step for providing a protective film on the entire surface of said wafer, opening a plurality of through holes penetrating said silicon thin film by patterning and etching, and forming a beam part connecting to said weight part and a support frame part remained on the periphery; (d) while remaining said protective film, as is, for forming said plurality of through holes, a step for removing by wet etching said SiO2 layer under said weight part and said beam part; (e) a step for removing said protective film, and coating a resist over the entire surface of said wafer; (f) a step for forming a slit by dicing for dividing said chip while remaining a small thickness of said wafer; (g) a step for removing by ashing said resist on said wafer by an O2 plasma; and (h) a step for dividing said chip by concentrating a stress on said slit.
- 17. A production method of an acceleration sensor chip for constructing a sensor structure on a third layer provided on a first layer of support substrate through an insulating second layer, characterized by comprising:
a first step for forming a plurality of cutouts of a same width on said third layer to form a detection surface of said sensor structure having a beam part and a weight part for displacing said beam part which are separated from each other; a second step for filling said plurality of cutouts of said same width of said sensor structure with a sealing agent to flatten the surface of said third layer including said sensor structure; a third step for forming a circuit part connected electrically to said sensor structure in the periphery of said surface-flattened third layer; and a fourth step for removing said sealing agent filled in said plurality of cutouts of said same width and removing said second layer located beneath a detection surface of said sensor structure to make said beam part and said weight part provided on said detection surface of said sensor structure displaceable.
- 18. The production method of acceleration sensor chip as claimed in claim 17, further comprising:
a fifth step for coating a protective film on the surface of said third layer including said sensor structure after said fourth step, forming a slit in said protective film-coated third layer, and performing dicing, and a sixth step for removing said protective film of said third layer after dicing.
- 19. The production method of acceleration sensor chip as claimed in claim 17, wherein in any one of said first step to said fourth step, a film smaller in thermal expansion coefficient than material of said first layer is formed on a backside of said first layer.
- 20. The production method of acceleration sensor chip as claimed in claim 17, wherein said same width of said plurality of cutouts formed on said sensor structure is 2 μm or less.
- 21. The production method of acceleration sensor chip as claimed in claim 17, wherein as a substrate comprising said first layer, said second layer and said third layer, an SOI (silicon-on-insulator) wafer is used, or a wafer having polysilicon formed as said third layer on a single crystal silicon substrate through an insulation layer is used.
- 22. A semiconductor sensor comprising:
a semiconductor sensor chip for detecting a physical value applied in a direction perpendicular to the chip surface; and a package for incorporating said semiconductor sensor chip, wherein a main surface for mounting said semiconductor sensor chip is formed to have a predetermined angle with respect to the surface of a printed circuit board for mounting said package, said main surface is provided with a plurality of terminals along two opposite sides thereof for connecting with input/output terminals of said semiconductor sensor chip, a bottom surface perpendicular to said main surface is provided with a plurality of pins respectively formed along the two sides parallel to said main surface, so that said plurality of pins are inserted into mounting holes formed in said printed circuit board, said plurality of terminals and said plurality of pins are electrically connected, and said input/output terminals of said semiconductor sensor chip mounted on said main surface are electrically connected with said plurality of terminals of said package.
- 23. The semiconductor sensor as claimed in claim 22, wherein said main surface for mounting said semiconductor sensor chip is formed substantially perpendicular to the surface of a printed circuit board for mounting said package.
- 24. The semiconductor sensor as claimed in claim 22, wherein said semiconductor sensor chip is the acceleration sensor chip described in any one of claims 1, 5 and 11.
- 25. The semiconductor sensor as claimed in claim 22, wherein said semiconductor sensor chip is the angular acceleration sensor chip described in claim 10.
- 26. A semiconductor sensor package for incorporating a semiconductor sensor chip characterized in that a main surface for mounting said semiconductor sensor chip is formed at a predetermined angle with respect to the surface of a printed circuit board mounting said package, said main surface is provided with a plurality of terminals along two opposite sides thereof for connecting with input/output terminals of said semiconductor sensor chip, a bottom surface perpendicular to said main surface is provided with a plurality of pins respectively formed along two sides parallel to said main surface, which plurality of pins are inserted into mounting holes formed in said printed circuit board, and said plurality of terminals provided along parallel sides and said plurality of pins are electrically connected.
- 27. The semiconductor sensor package as claimed in claim 26, wherein said main surface for mounting said semiconductor sensor chip is formed substantially perpendicular to the surface of printed circuit board mounting said package.
- 28. The semiconductor sensor package as claimed in claim 26, wherein wiring for connecting said plurality of terminals and said plurality of pins is buried in said package.
Priority Claims (3)
Number |
Date |
Country |
Kind |
107,537/1997 |
Apr 1997 |
JP |
|
261,369/1997 |
Sep 1997 |
JP |
|
019,086 |
Jan 1998 |
JP |
|
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This is a continuation-in-part of application Ser. No. 09/160,189 filed on Sep. 25, 1998.
Divisions (1)
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Number |
Date |
Country |
Parent |
09241096 |
Feb 1999 |
US |
Child |
09956969 |
Sep 2001 |
US |
Continuation in Parts (2)
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Number |
Date |
Country |
Parent |
09160189 |
Sep 1998 |
US |
Child |
09241096 |
Feb 1999 |
US |
Parent |
09061876 |
Apr 1998 |
US |
Child |
09160189 |
Sep 1998 |
US |