WO2013109547A1 - Time domain switched gyroscope - Google Patents
Time domain switched gyroscope Download PDFInfo
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- WO2013109547A1 WO2013109547A1 PCT/US2013/021595 US2013021595W WO2013109547A1 WO 2013109547 A1 WO2013109547 A1 WO 2013109547A1 US 2013021595 W US2013021595 W US 2013021595W WO 2013109547 A1 WO2013109547 A1 WO 2013109547A1
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- Prior art keywords
- mass
- drive
- gyroscope
- sense
- support structure
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- 230000005641 tunneling Effects 0.000 claims description 21
- 230000010355 oscillation Effects 0.000 claims description 8
- 238000012544 monitoring process Methods 0.000 claims description 6
- 230000004044 response Effects 0.000 claims description 5
- 235000012431 wafers Nutrition 0.000 claims description 5
- 230000001133 acceleration Effects 0.000 claims description 4
- PLFFHJWXOGYWPR-HEDMGYOXSA-N (4r)-4-[(3r,3as,5ar,5br,7as,11as,11br,13ar,13bs)-5a,5b,8,8,11a,13b-hexamethyl-1,2,3,3a,4,5,6,7,7a,9,10,11,11b,12,13,13a-hexadecahydrocyclopenta[a]chrysen-3-yl]pentan-1-ol Chemical compound C([C@]1(C)[C@H]2CC[C@H]34)CCC(C)(C)[C@@H]1CC[C@@]2(C)[C@]4(C)CC[C@@H]1[C@]3(C)CC[C@@H]1[C@@H](CCCO)C PLFFHJWXOGYWPR-HEDMGYOXSA-N 0.000 claims description 3
- 238000006073 displacement reaction Methods 0.000 description 4
- 230000008859 change Effects 0.000 description 3
- 125000006850 spacer group Chemical group 0.000 description 3
- 208000003251 Pruritus Diseases 0.000 description 2
- 230000009977 dual effect Effects 0.000 description 2
- 230000007246 mechanism Effects 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 230000003287 optical effect Effects 0.000 description 2
- 241000030538 Thecla Species 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
- 230000000737 periodic effect Effects 0.000 description 1
- 230000001603 reducing effect Effects 0.000 description 1
- 230000035945 sensitivity Effects 0.000 description 1
Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C19/00—Gyroscopes; Turn-sensitive devices using vibrating masses; Turn-sensitive devices without moving masses; Measuring angular rate using gyroscopic effects
- G01C19/56—Turn-sensitive devices using vibrating masses, e.g. vibratory angular rate sensors based on Coriolis forces
- G01C19/5719—Turn-sensitive devices using vibrating masses, e.g. vibratory angular rate sensors based on Coriolis forces using planar vibrating masses driven in a translation vibration along an axis
- G01C19/5733—Structural details or topology
- G01C19/5755—Structural details or topology the devices having a single sensing mass
- G01C19/5762—Structural details or topology the devices having a single sensing mass the sensing mass being connected to a driving mass, e.g. driving frames
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
- G01C19/00—Gyroscopes; Turn-sensitive devices using vibrating masses; Turn-sensitive devices without moving masses; Measuring angular rate using gyroscopic effects
- G01C19/56—Turn-sensitive devices using vibrating masses, e.g. vibratory angular rate sensors based on Coriolis forces
- G01C19/5719—Turn-sensitive devices using vibrating masses, e.g. vibratory angular rate sensors based on Coriolis forces using planar vibrating masses driven in a translation vibration along an axis
Definitions
- the invention described and claimed herein relates to the field of detecting rotation of a structure about an axis.
- the cla imed invention relates to the field of monol ithical ly integrated gyroscopes.
- a gyroscope in a first aspect includes: (i) a support structure, ( ii) a drive mass coupled to the support structure, (iii) a drive mass driver configured to cause the drive mass to oscillate with respect to the support structure in a first direction, (iv ) a first sense mass coupled to the drive mass, and (v) a first digital trigger comprising a first proximity switch coupled between the drive mass and the first sense mass.
- movement of the drive mass with respect to the support structure is substantially restricted to movement in the first direction.
- the drive mass driver is configured to cause the drive mass to oscillate with respect to the support structure in the first d irection.
- the movement of the sense mass with respect to the drive mass is substantially restricted to movement in a second direction, which is orthogonal to the first direction.
- the first switch is configured to switch from an open state to a c losed state each time the sense mass is in a reference position with respect to the drive mass.
- a monol ithic gyroscope in a second aspect, includes a support structure, a drive mass, a drive mass driver, a sense mass, and a trigger.
- the drive mass is springedly coupled to the support structure.
- the drive mass driver is configured to drive the drive mass to osci llate w ith respect to the support structure in approximately only an x-direction.
- the sense mass is springedly coupled to the drive mass and is configured to move w ith respect to the drive mass in approximately only a z-direction, which is orthogonal to the x-direction, in response to Corioiis forces from rotation of the support structure about a y-axis, which is orthogonal to both the z- and x-directions.
- the trigger comprises in another variant a digital trigger with proximity switch, the latter wh ich is coupled between the drive mass and the sense mass and is configured to pass from an open state to a closed state when the sense mass passes through a reference pos ition such that rotation of the support structure about the y-axis may be determ ined by mon itoring the state of the proximity switch with respect to time.
- the force sensing apparatus is based on. inter alia, a drive mass, a sense mass, and a digital trigger.
- Figure 1 is a perspective v ie of an embodiment of a gyroscope.
- Figures 2A-2C are cross-sectional side views of a dual-tipped electron tunneling proximity switch in various reference positions.
- Figure 3 is a perspective view of a dual-sense-mass embodiment of a gyroscope.
- Figures 4A-4C are perspective views of a dual-tipped, laterally-stacked electron tunneling proximity switch in various reference positions.
- Figures 5A-5C are top views of another dual-tipped, lateral ly-stacked electron tunnel ing proximity switch in various reference positions.
- Figure 6 is a cross-sectional view of a sense mass.
- Figure 7 is a perspective view of another dual-sense-mass embodiment of a gyroscope.
- Figure 8 is a perspective view of another dual-sense-mass embodiment of a gyroscope.
- FIG. 1 is a perspective view of an embodiment of a time domain switched gyroscope 10.
- the gyroscope 1 0 is a vibrating-proof-mass-based gyroscope that util izes at least one digital trigger to produce a signal each time a proof mass passes a known location.
- the gyroscope 10 comprises a rigid support structure 12, a drive mass 14, a drive mass driver 1 6, a first sense mass 18, and a first digital trigger 20.
- the drive mass 14 is springedSy coupled to the support structure 12 such that movement of the drive mass 14 with respect to the support structure 12 is substantially restricted to movement in a first direction.
- the first direction corresponds to an x-direction of three, mutually-orthogonal axes x-y-z.
- the drive mass driver 1 6 is configured to cause the drive mass 14 to oscillate with respect to the support structure 12 in the x-direction.
- the first sense mass 1 8 is springed ly coupled to the drive mass 1 4 such that movement of the first sense mass 1 8 with respect to the drive mass 14 is substantially restricted to movement in a second direction, wh ich, in Fig. 1 , corresponds to the z-direction.
- the first sense mass 1 8 is decoupled from the drive mass 1 8 in the sense direction ( i.e., the z-direction).
- the first sense mass 1 8 moves in the z-direction with respect to the drive mass 14 in response to Corioiis forces from rotation of the support structure 12 about the y-axis.
- the first digital trigger 20 comprises a first proximity switch 22. which is coupled between the drive mass 14 and the first sense mass 18.
- the first proxim ity switch 22 passes through closed and open states with each osci llation of the first sense mass 1 8 with respect to the drive mass 14.
- d isplacement from the first reference position of the first sense mass 1 8 with respect to the drive mass 14 may be discovered by monitoring the state of the first proxim ity switch 22.
- the gyroscope 10 may be manufactured on any scale.
- the gyroscope 10 may be monolithic-ally integrated into a micro-electromechan ical system (MEMS) device.
- MEMS micro-electromechan ical system
- the gyroscope 1 0 may be used in any orientation.
- the x-y-z coordinate system is depicted in the drawings and referred to herein, it is to be understood that the first, second, and third directions/axes, as used herein, may correspond to any three mutual ly orthogonal directions/axes in any three-dimensional coordinate system.
- the support structure 12 may be any size and shape, and be made of any material capable of providing rigid support for the gyroscope 10 such that the support structure 1 2 does not significantly flex and/or deform when exposed to lateral and rotational accelerations of the gyroscope 10.
- the drive mass 14 may be coupled to the support structure 1 2 in any manner wh ich restricts movement of the drive mass with respect to the support structure ! 2 in the y- and z- d irections and rotations about the x-y-z axes, but yet al lows the drive mass 14 to elastically move with respect to the support structure 12 in the x-direction.
- the embod iment of the gyroscope 1 0 shown in Fig. 1 portrays the drive mass 14 as being coupled to the support structure ⁇ 2 by compliant spring members 24, which are designed to flex in only the x- direction.
- the drive mass driver 1 6 may be any apparatus capable of causing the drive mass 14 to oscil late at any desired frequency in the x-direction with respect to the support structure 12.
- Suitable examples of the drive mass driver 16 include, but are not l im ited to, variable area actuators, such as electrostatic comb drives (such as are portrayed in Fig. 1 ).
- variable gap actuators such as paral lel plate actuators, and other eiectro-magnetic or piezoelectric mechanisms of actuation.
- the drive mass 14 may be driven using a continuous oscillating force or by periodic "delta function" forces in phase with the drive mass 14 harmon ic resonance.
- the first sense mass 1 8 may be coupled to the drive mass 1 4 in any manner which restricts movement of the sense mass 1 8 with respect to the drive mass 1 4 in the x- and y- directions and from rotating about the x-y-z axes, but yet al lows the first sense mass 1 8 to elastically move with respect to the drive mass 14 in the z-direction.
- the embodiment of the gyroscope 1 0 shown in Fig. 1 portrays the first sense mass 18 as being coupled to the drive mass 14 by a canti lever spring which is designed to flex in only the z-d!rection.
- the first digital trigger 20 may be any apparatus capable of producing digital signals corresponding to various positions of the first sense mass i 8 with respect to the drive mass 1 4.
- the first proximity switch 22 may be any dev ice capable of experiencing a change in state based on positional changes of the first sense mass 18 relative to the drive mass 14.
- the reference position in wh ich the first proxim ity switch 22 is in a closed state may be a zero force position or any other desired reference position.
- a purpose of the first digital trigger 20 is to localize the position of the first sense mass 18 and the drive mass 14 such that an accurate acceleration- independent phase measurement can be performed— thereby i ncreasing stability of a phased-iocked loop closure and reduc ing overall phase noise and j itter of the gyroscope 1 0.
- the first proximity switch 22 may be an electron tunneling switch capable of generating a fin ite width current pulse.
- the first proximity switch 22 comprises a pair of electron tunneling tips, one tip positioned on the first sense mass 1 8 and the other positioned on the drive mass 14. When the first sense mass is in the first reference position with respect to the drive mass 1 4 the tunneling tips are aligned and the first proxim ity switch 22 is in a closed state such that a current pu lse may pass between the tips.
- the current pu!se itself can be amplified to the rails v ia a transimpedance amplifier and the leading and or trailing edges of the pu lse may be used to localize the position of the first sense mass 1 8 with respect to the drive mass 14.
- a transimpedance amplifier and the leading and or trailing edges of the pu lse may be used to localize the position of the first sense mass 1 8 with respect to the drive mass 14.
- Other examples of the first proximity switch 22 include a capacitive switch, an optical shutter switch, and a magnetic switch.
- the first proximity switch 22 may be configured to pass through multiple closed states corresponding to mu ltiple reference positions during a single oscillation period.
- Figures 2A-2C illustrate an embodiment of the first proximity switch 22 where the first proximity switch 22 is configured to pass through multiple closed states corresponding to multiple reference positions of the first sense mass 1 8 with respect to the drive mass 14 during a single oscil lation period.
- the first proximity sw itch 22 comprises first and second electron tunneling tips 26 and 28 mounted on the drive mass 14.
- the first and second tips 26 and 28 are aligned with each other in the z-direction and separated from each other in the z-d irection by a distance d l .
- the first proximity switch 22 i n th is embodiment also comprises third and forth electron tunneling tips 30 and 32 mounted to the first sense mass 1 8.
- the third and forth tips 30 and 32 are aligned with each other in the z-direction and separated from each other in the z-d irection by the distance d l .
- the first and second tips 26 and 28 and the third and fourth tips 30 and 32 can be separated from each other by a dielectric spacer 34.
- the first, second, th ird, and fourth tips 26, 28, 30. and 32 are positioned with respect to each other such that when the first sense mass 1 8 is in the first reference position, such as is depicted in Fig. 2A, a current pulse passes from the first and second tips 26 and 28 over a gap 36 to the third and fourth tips 30 and 32 respectively.
- This embodiment of the first proxim ity switch 22 also comprises second and th ird reference positions of the first sense mass 1 8 with respect to the drive mass 1 4.
- the first sense mass 1 8 is in the second reference pos ition when the first sense mass 1 8 is d isplaced from the first reference position in the z-direction by the distance -d l , such as is shown in Fig. 2B.
- the first proximity switch 22 is in a closed state such that a current pulse may pass from the first tip 26 to the fourth tip 32.
- the first sense mass 1 8 is in the third reference position when the first sense mass 1 8 is d isplaced in the z-direction by the d istance +d l , such as is shown in Fig. 2C.
- the first proximity switch ⁇ 8 is in a closed state such that a current pulse passes from the second tip 28 to the t ird tip 30.
- Figure 3 is a perspective view of another embodiment of the gyroscope 1 0, which further comprises a second sense mass 38.
- the second, sense mass 38 is springedly coupled to the drive mass 1 4 such that movement of the second sense mass 38 with respect to the drive mass 14 is substantially restricted to movement in the y-d irection.
- the second sense mass 38 is configured to move in the y-direction with respect to the drive mass 1 4 in response to Coriol is forces from rotation of the support structure i 2 about the z-axis.
- the second sense mass 38 is shown as being coupled to the drive mass 14 by compliant spring members 24.
- a lso shown is a second digital trigger 40, which comprises a second proximity switch 42 coupled between the drive mass 1 4 and the second sense mass 38.
- the second proxim ity switch 42 is configured to be in a closed state each time the second sense mass 38 is in a fourth reference position with respect to the drive mass 1 4.
- the second digital trigger 40 may be any apparatus capable of producing digital signals corresponding to various positions of tiie second sense mass 38 with respect to the drive mass 14.
- the second proximity switch 42 may be any device capable of experiencing a change in state based on positional changes of the second sense mass 38 relative to the drive mass 14. In the embodiment of the gyroscope 1 0 depicted in Fig. 3. the second proximity switch 42 is shown as four electron tunnel ing tips. Further detail regarding the electron-tunneling-tip embodiment of the second proximity switch 42 may be found below in the description of Figs. 4A-4C.
- the reference position in which the second proximity switch 42 is in a closed state may be a zero force position or any other desired reference position.
- Rotation of the support structure 1 2 about the z-axis may be determined by monitoring the state of the second proxim ity switch 42.
- this embod iment of the gyroscope 1 0 provides a gyroscope with a single drive mass and two sense masses (uncoupled in their respective sense directions) configured to measure two orthogonal rotational forces.
- Figures 4A-4C are il lustrations depicting the second proximity switch 42 in various reference positions of the second sense mass 38 with respect to the drive mass 14.
- Fig. 4A portrays the second proximity switch 42 in the fourth reference position, in the embodiment of the second proximity switch 42 shown in Figs. 4A-4C, the second proximity switch 42 comprises fifth and sixth electron tunneling tips 44 and 46 mounted on the second sense mass 38.
- the fifth and sixth electron tips 44 and 46 are aligned with each other in the y-direction and separated from each other in the y-direction by a d istance d2.
- the second proximity switch 42 in this embodiment also comprises seventh and eighth electron tunneling tips 48 and 50 mounted to the drive mass 1 4.
- the seventh and eighth electron tips 48 and 50 are al igned w ith each other in the y-direction and separated from each other in the y-d irection by a d istance d2.
- the fifth and sixth electron tips 44 and 46 and the seventh and eighth electron tips 48 and 50 can be separated from each other by a second dielectric spacer 52.
- the fifth, sixth, seventh, and eighth tips 44. 46. 48, and 50 are positioned with respect to each other such that when tiie second sense mass 38 is in the fourth reference position, such as is depicted in Fig. 4A, a current pu lse passes from the fi fth and sixth tips 44 and 46 over a second gap 54 to the seventh and eighth tips 48 and 50 respectively.
- Fig. 4B shows the second proximity switch 42 with the second sense mass 38 in a fifth reference position.
- the second proximity switch 42 is in the fifth reference position when the second sense mass 38 is displaced from the fourth reference position in the y- direction by the distance +d2, such as is shown in Fig. 4B.
- the second proxim ity switch 42 is in a closed state such that a current pulse may pass from the fifth tip 44 to the eighth tip 50.
- the second sense mass 38 is in the seventh reference position when the second sense mass 38 is displaced in the y-direction by the distance -d2, such as is shown in Fig. 4C.
- the second proximity switch 42 In the sixth reference position, the second proximity switch 42 is in a closed state such that a currentmodule passes from the sixth tip 46 to the seventh tip 48.
- the time intervals between the fourth, fifth, and sixth reference pos itions may be measured to determine displacement and the amplitude of such displacement of the second sense mass 38 with respect to the drive mass 14.
- this embodiment may also comprise a third digital trigger 56 comprising a th ird proximity switch coupled 58 between the drive mass 1 4 and the support structure d.
- the third switch 58 is configured to switch from an open state to at least one closed state each time the drive mass 14 passes through a reference position with respect to the support structure 1 2.
- the third proximity switch 58 functions as an acceierometer configured to detect acceleration of the support structure 12 in the x-direction.
- the th ird proximity switch 58 may be any device capable of experienc ing a change in state based on positional changes of the drive mass 1 4 relative to the support structure 1 2.
- the reference position in which the third proximity switch 58 is in a c losed state may be a zero force position or any other desired reference position.
- Figures 5 A-5C are top views of the embodi ment of the third proximity switch 58 depicted in Fig. 3 with the drive mass 14 in various reference positions with respect to the support structure 12.
- the third proximity switch 58 is an electron tunneling switch capable of generating a fin ite width currenttransporte.
- Other examples of the third proximity switch 58 inc lude a capacitive sw itch, an optical shutter switch, and a magnetic switch.
- the th ird proximity switch 58 may be configured to pass through multiple closed states corresponding to multiple reference positions during a single oscil lation period.
- the th ird proximity switch 58 comprises a pair of electron tunneling tips (n inth and tenth tips 60 and 62) positioned on the drive mass 14 and another pair of tunnel ing tips (eleventh and twelfth tips 64 and 66) positioned on the support structure 12.
- the n inth and tenth tips 60 and 62 are aligned with each other in the x-direction and are separated from each other in the x-direction by a distance d3.
- the eleventh and tweifth tips 64 and 66 are also al igned with each other in the x-d irection and separated from each other in the x-direction by the distance d3.
- the ninth and tenth tips 60 and 62 and the eleventh and twelfth tips 64 and 66 can be separated from each other by a third dielectric spacer 68.
- the third switch 58 is in a closed state such that a currentmodule may pass between the ninth tip 60 and the eleventh tip 64 as wei! as between the tenth tip 62 and the twelfth tip 66.
- the drive mass 14 is in an eighth reference position with respect to the support structure 1 2 when the drive mass 14 is d isplaced from the seventh reference position in the x-direction by the distance +d3, such as is depicted in Fig. 5B.
- the third switch 58 When the drive mass 1 4 is in the eighth reference pos ition the third switch 58 is in a closed state such that a current pulse may pass between the n inth tip 60 and the twelfth tip 66.
- the drive mass 14 is in a ninth reference position with respect to the support structure 12 when the drive mass 14 is displaced from the seventh reference position in the x-d irection by the distance -d3, such as is depicted in Fig. 5C.
- the third switch 58 When the drive mass 14 is in a ninth reference position with respect to the support structure 12 the third switch 58 is in a closed state such that a current pu lse may pass between the tenth tip 62 and the eleventh tip 64.
- Figure 6 shows a cross-sectional perspective view of an alternative embodiment of the first sense mass 1 8, which further comprises a first sense mass driver 70 configured to drive the first sense mass 1 8 to oscil late in the z-direction at a resonant frequency of the first sense mass 1 8.
- the first sense mass driver 70 may be any device capable of causing controlled movement of the first sense mass 1 in the z-direction with respect to the drive mass 14.
- Suitable examples of the first sense mass driver 70 include, but are not lim ited to variable area actuators, such as electrostatic comb drives, and variable gap actuators, such as parallel plate actuators, as wel l as other electro-magnetic or piezoelectric mechanisms of actuation.
- the first sense mass driver 70 may comprise a symmetric pair of upper and lower overlapped capacitive electrodes on either side of the first sense mass 1 8, such as is depicted in Fig. 6, that can be used to create a veloc ity vector in the first sense mass 1 8.
- Fig. 6 also shows a way to couple the first sense mass 18 to the drive mass 14 with monolithically- integrated dual springs 72.
- an offset modu lation mode may be employed to determ ine displacement and amplitude information of the first sense mass 1 8 in the z- direction with respect to the drive mass 14.
- the sense mass(es) are capacitiveiy "pinged" to initiate harmon ic oscil lation. For example, see operation of the time domain accelerometer d iscussed in U.S. Patent Application Serial No. 1 3/276,948, previously incorporated by reference herein.
- an amplitude modulation mode may be employed to determine displacement and amplitude information of the first sense mass 1 8 in the z-d irection with respect to the drive mass 14.
- the sense mass(es) do not require pinging since the Corio!is forces wil l in itiate harmonic oscillation.
- the open loop embod iment of a sense mass in U.S. Patent Application Serial No. 13/167,539, filed 23 June 20 ! 1 by Charles H. Tally et ai., which is incorporated by reference herein in its entirety.
- Figure 7 shows another embodiment of the gyroscope 10 featuring multiple iterations of each of the first, second, and th ird proximity switches 22. 42, and 58. Multiple digital triggers/proximity switches may be used with each of the masses in the gyroscope 10.
- FIG. 8 is an illustration of an embodiment of the gyroscope 10 showing the support structure 12.
- the drive mass 1 4, the first sense mass 1 8, and the second sense mass 38 vacuum sealed between a top cap wafer 74 and a bottom cap wafer 76.
- the top and bottom cap wafers 74 and 76 are depicted in Fig. 8 as transparent with dotted outl ines in order to facilitate viewing of the internal features of the gyroscope 1 0.
- techn iques may be used for implementing the concepts of gyroscope 10 without departing from its scope.
- the described embod iments are to be considered in all respects as i llustrative and not restrictive. It shou ld also be understood that gyroscope 10 is not limited to the particular embodiments described herein, but is capable of many embodiments without departing from the scope of the claims.
Abstract
A gyroscope comprising: a support structure: a drive mass springedly coupled to the support structure such that movement of the drive mass with respect to the support structure is substantially restricted to movement in a first direction; a driver configured to cause the drive mass to oscillate with respect to the support structure in the first direction; a sense mass springedty coupled to the drive mass such that movement of the sense mass with respect to the drive mass is substantially restricted to movement in a second direction, which is orthogonal to the first direction; and a digital trigger comprising a proximity switch coupled between the drive mass and the sense mass, wherein the switch is configured to switch from an open state to a closed state each time the sense mass is in a reference position with respect to the drive mass.
Description
TIME DOMAIN SWITCHED GYROSCOPE
Priority
This appl ication claims priority to U.S. Patent Appl ication Serial No. 13/353,205 fi led January 1 8, 201 2 of the same title, which is incorporated herein by reference in its entirety.
Background of the invention
The invention described and claimed herein relates to the field of detecting rotation of a structure about an axis. In particular, the cla imed invention relates to the field of monol ithical ly integrated gyroscopes.
Summary
In a first aspect a gyroscope is disclosed. In an embodiment the gyroscope includes: (i) a support structure, ( ii) a drive mass coupled to the support structure, (iii) a drive mass driver configured to cause the drive mass to oscillate with respect to the support structure in a first direction, (iv ) a first sense mass coupled to the drive mass, and (v) a first digital trigger comprising a first proximity switch coupled between the drive mass and the first sense mass.
I n a variant, movement of the drive mass with respect to the support structure is substantially restricted to movement in the first direction. The drive mass driver is configured to cause the drive mass to oscillate with respect to the support structure in the first d irection. The movement of the sense mass with respect to the drive mass is substantially restricted to movement in a second direction, which is orthogonal to the first direction. The first switch is configured to switch from an open state to a c losed state each time the sense mass is in a reference position with respect to the drive mass.
In a second aspect, a monol ithic gyroscope is disclosed. I n an embodiment, the monolith ic gyroscope includes a support structure, a drive mass, a drive mass driver, a sense mass, and a trigger. In one variant, the drive mass is springedly coupled to the support structure. The drive mass driver is configured to drive the drive mass to osci llate w ith respect to the support structure in approximately only an x-direction. The sense mass is springedly coupled to the drive mass and is configured to move w ith respect to the drive mass in approximately only a z-direction, which is orthogonal to the x-direction, in response to Corioiis forces from rotation of the support structure about a y-axis, which is orthogonal to
both the z- and x-directions. The trigger comprises in another variant a digital trigger with proximity switch, the latter wh ich is coupled between the drive mass and the sense mass and is configured to pass from an open state to a closed state when the sense mass passes through a reference pos ition such that rotation of the support structure about the y-axis may be determ ined by mon itoring the state of the proximity switch with respect to time.
i n a third aspect, method of force sensing apparatus is disclosed. The force sensing apparatus is based on. inter alia, a drive mass, a sense mass, and a digital trigger.
Other features and advantages of the present invention wi ll immediately be recognized by persons of ord inary skill in the art with reference to the attached drawings and detailed description of exemplary embodiments as given below.
Brief Description of the Drawings
Throughout the several views, like elements are referenced using l ike references. The elements in the figures are not drawn to scale and some dimensions are exaggerated for clarity.
Figure 1 is a perspective v ie of an embodiment of a gyroscope.
Figures 2A-2C are cross-sectional side views of a dual-tipped electron tunneling proximity switch in various reference positions.
Figure 3 is a perspective view of a dual-sense-mass embodiment of a gyroscope.
Figures 4A-4C are perspective views of a dual-tipped, laterally-stacked electron tunneling proximity switch in various reference positions.
Figures 5A-5C are top views of another dual-tipped, lateral ly-stacked electron tunnel ing proximity switch in various reference positions.
Figure 6 is a cross-sectional view of a sense mass.
Figure 7 is a perspective view of another dual-sense-mass embodiment of a gyroscope.
Figure 8 is a perspective view of another dual-sense-mass embodiment of a gyroscope.
Detai led Description of the Embodiments
Figure 1 is a perspective view of an embodiment of a time domain switched gyroscope 10. The gyroscope 1 0 is a vibrating-proof-mass-based gyroscope that util izes at least one digital trigger to produce a signal each time a proof mass passes a known location.
The gyroscope 10 comprises a rigid support structure 12, a drive mass 14, a drive mass driver 1 6, a first sense mass 18, and a first digital trigger 20. The drive mass 14 is springedSy coupled to the support structure 12 such that movement of the drive mass 14 with respect to the support structure 12 is substantially restricted to movement in a first direction. In Fig, 1 , the first direction corresponds to an x-direction of three, mutually-orthogonal axes x-y-z. The drive mass driver 1 6 is configured to cause the drive mass 14 to oscillate with respect to the support structure 12 in the x-direction. The first sense mass 1 8 is springed ly coupled to the drive mass 1 4 such that movement of the first sense mass 1 8 with respect to the drive mass 14 is substantially restricted to movement in a second direction, wh ich, in Fig. 1 , corresponds to the z-direction. Th us, the first sense mass 1 8 is decoupled from the drive mass 1 8 in the sense direction ( i.e., the z-direction). The first sense mass 1 8 moves in the z-direction with respect to the drive mass 14 in response to Corioiis forces from rotation of the support structure 12 about the y-axis. The first digital trigger 20 comprises a first proximity switch 22. which is coupled between the drive mass 14 and the first sense mass 18. The first proxim ity switch 22 passes through closed and open states with each osci llation of the first sense mass 1 8 with respect to the drive mass 14. Each time the first sense mass 1 8 passes a first reference position with respect to the drive mass 1 4 the first proximity switch 22 passes through a closed state. Thus, d isplacement from the first reference position of the first sense mass 1 8 with respect to the drive mass 14 may be discovered by monitoring the state of the first proxim ity switch 22.
The gyroscope 10 may be manufactured on any scale. For example, in one embodiment the gyroscope 10 may be monolithic-ally integrated into a micro-electromechan ical system (MEMS) device. The gyroscope 1 0 may be used in any orientation. Although the x-y-z coordinate system is depicted in the drawings and referred to herein, it is to be understood that the first, second, and third directions/axes, as used herein, may correspond to any three mutual ly orthogonal directions/axes in any three-dimensional coordinate system.
The support structure 12 may be any size and shape, and be made of any material capable of providing rigid support for the gyroscope 10 such that the support structure 1 2 does not significantly flex and/or deform when exposed to lateral and rotational accelerations of the gyroscope 10.
The drive mass 14 may be coupled to the support structure 1 2 in any manner wh ich restricts movement of the drive mass with respect to the support structure ! 2 in the y- and z-
d irections and rotations about the x-y-z axes, but yet al lows the drive mass 14 to elastically move with respect to the support structure 12 in the x-direction. The embod iment of the gyroscope 1 0 shown in Fig. 1 portrays the drive mass 14 as being coupled to the support structure \ 2 by compliant spring members 24, which are designed to flex in only the x- direction. The drive mass driver 1 6 may be any apparatus capable of causing the drive mass 14 to oscil late at any desired frequency in the x-direction with respect to the support structure 12. Suitable examples of the drive mass driver 16 include, but are not l im ited to, variable area actuators, such as electrostatic comb drives (such as are portrayed in Fig. 1 ). variable gap actuators, such as paral lel plate actuators, and other eiectro-magnetic or piezoelectric mechanisms of actuation. The drive mass 14 may be driven using a continuous oscillating force or by periodic "delta function" forces in phase with the drive mass 14 harmon ic resonance.
The first sense mass 1 8 may be coupled to the drive mass 1 4 in any manner which restricts movement of the sense mass 1 8 with respect to the drive mass 1 4 in the x- and y- directions and from rotating about the x-y-z axes, but yet al lows the first sense mass 1 8 to elastically move with respect to the drive mass 14 in the z-direction. The embodiment of the gyroscope 1 0 shown in Fig. 1 portrays the first sense mass 18 as being coupled to the drive mass 14 by a canti lever spring which is designed to flex in only the z-d!rection.
The first digital trigger 20 may be any apparatus capable of producing digital signals corresponding to various positions of the first sense mass i 8 with respect to the drive mass 1 4. The first proximity switch 22 may be any dev ice capable of experiencing a change in state based on positional changes of the first sense mass 18 relative to the drive mass 14. The reference position in wh ich the first proxim ity switch 22 is in a closed state may be a zero force position or any other desired reference position. A purpose of the first digital trigger 20 is to localize the position of the first sense mass 18 and the drive mass 14 such that an accurate acceleration- independent phase measurement can be performed— thereby i ncreasing stability of a phased-iocked loop closure and reduc ing overall phase noise and j itter of the gyroscope 1 0. !n one embodiment, such as is depicted in Fig. 1 , the first proximity switch 22 may be an electron tunneling switch capable of generating a fin ite width current pulse. In Fig. 1 , the first proximity switch 22 comprises a pair of electron tunneling tips, one tip positioned on the first sense mass 1 8 and the other positioned on the drive mass 14. When the first sense mass is in the first reference position with respect to the drive mass 1 4 the tunneling tips are aligned and the first proxim ity switch 22 is in a closed state such that a current pu lse may
pass between the tips. The current pu!se itself can be amplified to the rails v ia a transimpedance amplifier and the leading and or trailing edges of the pu lse may be used to localize the position of the first sense mass 1 8 with respect to the drive mass 14. A more detailed description of how this can be performed may be found in U. S. Patent Appl ication Serial No. 1 3/276,948, entitled "Resonator with Reduced Acceleration Sensitivity and Phase Noise Using Time Domain Switch," fi led 1 9 October 201 1 , which is incorporated by reference herein in its entirety. Other examples of the first proximity switch 22 include a capacitive switch, an optical shutter switch, and a magnetic switch. In addition, in alternate embodiments, the first proximity switch 22 may be configured to pass through multiple closed states corresponding to mu ltiple reference positions during a single oscillation period.
Figures 2A-2C illustrate an embodiment of the first proximity switch 22 where the first proximity switch 22 is configured to pass through multiple closed states corresponding to multiple reference positions of the first sense mass 1 8 with respect to the drive mass 14 during a single oscil lation period. In the embodiment of the first proxim ity switch 22 shown in Figs. 2A- 2C, the first proximity sw itch 22 comprises first and second electron tunneling tips 26 and 28 mounted on the drive mass 14. The first and second tips 26 and 28 are aligned with each other in the z-direction and separated from each other in the z-d irection by a distance d l . The first proximity switch 22 i n th is embodiment also comprises third and forth electron tunneling tips 30 and 32 mounted to the first sense mass 1 8. The third and forth tips 30 and 32 are aligned with each other in the z-direction and separated from each other in the z-d irection by the distance d l . The first and second tips 26 and 28 and the third and fourth tips 30 and 32 can be separated from each other by a dielectric spacer 34. The first, second, th ird, and fourth tips 26, 28, 30. and 32 are positioned with respect to each other such that when the first sense mass 1 8 is in the first reference position, such as is depicted in Fig. 2A, a current pulse passes from the first and second tips 26 and 28 over a gap 36 to the third and fourth tips 30 and 32 respectively. This embodiment of the first proxim ity switch 22 also comprises second and th ird reference positions of the first sense mass 1 8 with respect to the drive mass 1 4. The first sense mass 1 8 is in the second reference pos ition when the first sense mass 1 8 is d isplaced from the first reference position in the z-direction by the distance -d l , such as is shown in Fig. 2B. In the second reference position, the first proximity switch 22 is in a closed state such that a current pulse may pass from the first tip 26 to the fourth tip 32. The first sense mass 1 8 is in the third reference position when the first sense mass 1 8 is d isplaced in the z-direction by the d istance +d l , such as is shown in Fig. 2C. In the th ird
reference position, the first proximity switch ί 8 is in a closed state such that a current pulse passes from the second tip 28 to the t ird tip 30.
Figure 3 is a perspective view of another embodiment of the gyroscope 1 0, which further comprises a second sense mass 38. The second, sense mass 38 is springedly coupled to the drive mass 1 4 such that movement of the second sense mass 38 with respect to the drive mass 14 is substantially restricted to movement in the y-d irection. Thus, the second sense mass 38 is configured to move in the y-direction with respect to the drive mass 1 4 in response to Coriol is forces from rotation of the support structure i 2 about the z-axis. In Fig. 3. the second sense mass 38 is shown as being coupled to the drive mass 14 by compliant spring members 24. A lso shown is a second digital trigger 40, which comprises a second proximity switch 42 coupled between the drive mass 1 4 and the second sense mass 38. The second proxim ity switch 42 is configured to be in a closed state each time the second sense mass 38 is in a fourth reference position with respect to the drive mass 1 4. The second digital trigger 40 may be any apparatus capable of producing digital signals corresponding to various positions of tiie second sense mass 38 with respect to the drive mass 14. The second proximity switch 42 may be any device capable of experiencing a change in state based on positional changes of the second sense mass 38 relative to the drive mass 14. In the embodiment of the gyroscope 1 0 depicted in Fig. 3. the second proximity switch 42 is shown as four electron tunnel ing tips. Further detail regarding the electron-tunneling-tip embodiment of the second proximity switch 42 may be found below in the description of Figs. 4A-4C. The reference position in which the second proximity switch 42 is in a closed state may be a zero force position or any other desired reference position. Rotation of the support structure 1 2 about the z-axis may be determined by monitoring the state of the second proxim ity switch 42. Thus, this embod iment of the gyroscope 1 0 provides a gyroscope with a single drive mass and two sense masses (uncoupled in their respective sense directions) configured to measure two orthogonal rotational forces.
Figures 4A-4C are il lustrations depicting the second proximity switch 42 in various reference positions of the second sense mass 38 with respect to the drive mass 14. Fig. 4A portrays the second proximity switch 42 in the fourth reference position, in the embodiment of the second proximity switch 42 shown in Figs. 4A-4C, the second proximity switch 42 comprises fifth and sixth electron tunneling tips 44 and 46 mounted on the second sense mass 38. The fifth and sixth electron tips 44 and 46 are aligned with each other in the y-direction and separated from each other in the y-direction by a d istance d2. The second proximity
switch 42 in this embodiment also comprises seventh and eighth electron tunneling tips 48 and 50 mounted to the drive mass 1 4. The seventh and eighth electron tips 48 and 50 are al igned w ith each other in the y-direction and separated from each other in the y-d irection by a d istance d2. The fifth and sixth electron tips 44 and 46 and the seventh and eighth electron tips 48 and 50 can be separated from each other by a second dielectric spacer 52. The fifth, sixth, seventh, and eighth tips 44. 46. 48, and 50 are positioned with respect to each other such that when tiie second sense mass 38 is in the fourth reference position, such as is depicted in Fig. 4A, a current pu lse passes from the fi fth and sixth tips 44 and 46 over a second gap 54 to the seventh and eighth tips 48 and 50 respectively.
Fig. 4B shows the second proximity switch 42 with the second sense mass 38 in a fifth reference position. The second proximity switch 42 is in the fifth reference position when the second sense mass 38 is displaced from the fourth reference position in the y- direction by the distance +d2, such as is shown in Fig. 4B. In the fifth reference position, the second proxim ity switch 42 is in a closed state such that a current pulse may pass from the fifth tip 44 to the eighth tip 50. The second sense mass 38 is in the seventh reference position when the second sense mass 38 is displaced in the y-direction by the distance -d2, such as is shown in Fig. 4C. In the sixth reference position, the second proximity switch 42 is in a closed state such that a current puise passes from the sixth tip 46 to the seventh tip 48. The time intervals between the fourth, fifth, and sixth reference pos itions may be measured to determine displacement and the amplitude of such displacement of the second sense mass 38 with respect to the drive mass 14.
Referring now back to the dual sense mass embodiment of the gyroscope 1 0 shown in Fig, 3, this embodiment may also comprise a third digital trigger 56 comprising a th ird proximity switch coupled 58 between the drive mass 1 4 and the support structure d. The third switch 58 is configured to switch from an open state to at least one closed state each time the drive mass 14 passes through a reference position with respect to the support structure 1 2. The third proximity switch 58 functions as an acceierometer configured to detect acceleration of the support structure 12 in the x-direction. The th ird proximity switch 58 may be any device capable of experienc ing a change in state based on positional changes of the drive mass 1 4 relative to the support structure 1 2. The reference position in which the third proximity switch 58 is in a c losed state may be a zero force position or any other desired reference position.
Figures 5 A-5C are top views of the embodi ment of the third proximity switch 58 depicted in Fig. 3 with the drive mass 14 in various reference positions with respect to the support structure 12. In this embodiment, the third proximity switch 58 is an electron tunneling switch capable of generating a fin ite width current puise. Other examples of the third proximity switch 58 inc lude a capacitive sw itch, an optical shutter switch, and a magnetic switch. In addition, the th ird proximity switch 58 may be configured to pass through multiple closed states corresponding to multiple reference positions during a single oscil lation period. In the embodiment shown, the th ird proximity switch 58 comprises a pair of electron tunneling tips (n inth and tenth tips 60 and 62) positioned on the drive mass 14 and another pair of tunnel ing tips (eleventh and twelfth tips 64 and 66) positioned on the support structure 12. The n inth and tenth tips 60 and 62 are aligned with each other in the x-direction and are separated from each other in the x-direction by a distance d3. The eleventh and tweifth tips 64 and 66 are also al igned with each other in the x-d irection and separated from each other in the x-direction by the distance d3. The ninth and tenth tips 60 and 62 and the eleventh and twelfth tips 64 and 66 can be separated from each other by a third dielectric spacer 68. When the drive mass 14 is in a seventh reference position with respect to the support structure 1 2, such as is depicted in Fig. 5A, the third switch 58 is in a closed state such that a current puise may pass between the ninth tip 60 and the eleventh tip 64 as wei! as between the tenth tip 62 and the twelfth tip 66. The drive mass 14 is in an eighth reference position with respect to the support structure 1 2 when the drive mass 14 is d isplaced from the seventh reference position in the x-direction by the distance +d3, such as is depicted in Fig. 5B. When the drive mass 1 4 is in the eighth reference pos ition the third switch 58 is in a closed state such that a current pulse may pass between the n inth tip 60 and the twelfth tip 66. The drive mass 14 is in a ninth reference position with respect to the support structure 12 when the drive mass 14 is displaced from the seventh reference position in the x-d irection by the distance -d3, such as is depicted in Fig. 5C. When the drive mass 14 is in a ninth reference position with respect to the support structure 12 the third switch 58 is in a closed state such that a current pu lse may pass between the tenth tip 62 and the eleventh tip 64.
Figure 6 shows a cross-sectional perspective view of an alternative embodiment of the first sense mass 1 8, which further comprises a first sense mass driver 70 configured to drive the first sense mass 1 8 to oscil late in the z-direction at a resonant frequency of the first sense mass 1 8. The first sense mass driver 70 may be any device capable of causing controlled movement of the first sense mass 1 in the z-direction with respect to the drive mass 14.
Suitable examples of the first sense mass driver 70 include, but are not lim ited to variable area actuators, such as electrostatic comb drives, and variable gap actuators, such as parallel plate actuators, as wel l as other electro-magnetic or piezoelectric mechanisms of actuation. For example, the first sense mass driver 70 may comprise a symmetric pair of upper and lower overlapped capacitive electrodes on either side of the first sense mass 1 8, such as is depicted in Fig. 6, that can be used to create a veloc ity vector in the first sense mass 1 8. Fig. 6 also shows a way to couple the first sense mass 18 to the drive mass 14 with monolithically- integrated dual springs 72.
In embodiments of the gyroscope 10 where the first sense mass 1 8 is driven to osc il late and where the resonant frequency of the first sense mass 1 8 is substantially larger than a drive frequency of the drive mass 1 4 an offset modu lation mode may be employed to determ ine displacement and amplitude information of the first sense mass 1 8 in the z- direction with respect to the drive mass 14. In this embod iment the sense mass(es) are capacitiveiy "pinged" to initiate harmon ic oscil lation. For example, see operation of the time domain accelerometer d iscussed in U.S. Patent Application Serial No. 1 3/276,948, previously incorporated by reference herein.
In embodiments of the gyroscope 10 where the resonant frequency of the first sense mass 1 8 is approximately equal to the drive frequency of the drive mass 14 an amplitude modulation mode may be employed to determine displacement and amplitude information of the first sense mass 1 8 in the z-d irection with respect to the drive mass 14. In this embod iment, the sense mass(es) do not require pinging since the Corio!is forces wil l in itiate harmonic oscillation. For example, see the open loop embod iment of a sense mass in U.S. Patent Application Serial No. 13/167,539, filed 23 June 20 ! 1 by Charles H. Tally et ai., which is incorporated by reference herein in its entirety.
Figure 7 shows another embodiment of the gyroscope 10 featuring multiple iterations of each of the first, second, and th ird proximity switches 22. 42, and 58. Multiple digital triggers/proximity switches may be used with each of the masses in the gyroscope 10.
Figure 8 is an illustration of an embodiment of the gyroscope 10 showing the support structure 12. the drive mass 1 4, the first sense mass 1 8, and the second sense mass 38 vacuum sealed between a top cap wafer 74 and a bottom cap wafer 76. The top and bottom cap wafers 74 and 76 are depicted in Fig. 8 as transparent with dotted outl ines in order to facilitate viewing of the internal features of the gyroscope 1 0.
From the above description of the gyroscope 1 0, it is manifest that various techn iques may be used for implementing the concepts of gyroscope 10 without departing from its scope. The described embod iments are to be considered in all respects as i llustrative and not restrictive. It shou ld also be understood that gyroscope 10 is not limited to the particular embodiments described herein, but is capable of many embodiments without departing from the scope of the claims.
Claims
1 . A gyroscope comprising:
a support structure;
5 a drive mass coupled to the support structure;
a drive mass driver configured to cause the drive mass to osci llate with respect to the support structure in a first direction;
a first sense mass coupled to the drive mass: and
a first digital trigger comprising a first proxim ity switch coupled between the drive 10 mass and the first sense mass.
2. The gyroscope of Claim 1 , wherein movement of the drive mass with respect to the support structure is substantially restricted to movement in the first direction.
3. The gyroscope of Claim 2. wherein movement of the first sense mass with respect to the drive mass is substantial ly restricted to movement in a second direction; and i 5 wherein the second direction is orthogonal to the first direction.
4. The gyroscope of Claim 3, wherein the first switch is configured to switch from an open state to a closed state each time the first sense mass is in a first reference position with respect to the drive mass.
5. The gyroscope of Claim 3, wherein the first switch is further configured to 0 switch from an open state to a closed state each time the first sense mass is in a second
reference position with respect to the drive mass.
6. The gyroscope of Claim 3 further comprising:
a second sense mass springedly coupled to the drive mass such that movement of the second sense mass with respect to the drive mass is substantially restricted to movement in a5 third direction, wherein the third direction is orthogonal to the first and second d irections; and a second d igital trigger comprising a second proximity switch coupled between the drive mass and the second sense mass, wherein the second switch is configured to switch from an open state to a closed state each time the second sense mass is in a third reference position with respect to the drive mass.
0 7. The gyroscope of Claim 6 further comprising a th ird d igital trigger comprising a third proximity switch coupled between the drive mass and the support structure, wherein the third switch is configured to switch from an open state to a closed state each time the drive mass is in a fourth reference position with respect to tiie support structure.
- 1 ! -
8. The gyroscope of Claim 7. wherein for each respective oscil lation period, each of the first, second, and t ird proximity switches is configured to switch from an open state to a c losed state at least twice corresponding to at least two relative positions between the two elements to which each respective switch is attached.
9. The gyroscope of Claim 8, where in the first switch comprises:
first and second electron tunneling tips mounted on the drive mass, wherein the first and second tips are al igned with each other in the second direction and separated from each other in the second direction by a distance d i ;
third and forth electron tunneling tips mounted to the first sense mass, wherein the third and fourth tips are aligned with each other in the second direction and separated from each other in the second direction by the d istance d l ; and
wherein the firs second, third, and fourth tips are positioned with respect to each other such that when the first sense mass is in the first reference position, a current pulse passes from the first and second tips over a gap to the th ird and fourth tips respectively, and such that when the first sense mass is displaced from the first reference position in the second direction by the distance +d l a current pu lse passes from the second tip to the third tip, and such that when the first sense mass is displaced from the first reference position in the second direction by the d istance -d 1 a current pulse passes from the first tip to the fourth tip.
1 0. The gyroscope of Claim 9, wherein the second switch comprises:
fifth and sixth electron tunneling tips mounted on the drive mass, wherein the fifth and sixth tips are aligned with each other in the th ird direction and separated from each other in the third direction by a distance d2;
seventh and eighth electron tunneling tips mounted to the second sense mass, wherein the seventh and eighth tips are aligned with each other in the third d irection and separated from each other in the th ird direction by the distance d2; and
wherein the fifth, sixth, seventh, and eighth tips are positioned with respect to each other such that when the second sense mass is in the third reference position, a current pulse passes from the fifth and sixth tips over a gap to the seventh and eighth tips respectiveiy, and such that when the second sense mass is displaced from the third reference position in the third direction by the distance +d2 a current pulse passes from the sixth tip to the seventh tip, and such that when the second sense mass is displaced from the third reference position in the th ird direction by the distance ~d2 a current pulse passes from the fifth tip to the eighth tip.
1 1 . The gyroscope of Claim 1 0, wherein the third switch comprises: n inth and tenth electron tunnel ing tips mounted on the support structure, wherein the ninth and tenth tips are aligned with each other in the first direction and separated from each other in the first d irection by a distance d3;
eleventh and twelfth electron tunneling tips mounted to the drive mass, wherein the eleventh and twelfth tips are aligned with each other i n the first d irection and separated from each other in the first direction by the distance d3; and
wherein the ninth, tenth, eleventh, and twelfth tips are positioned with respect to each other such that when the drive mass is in the fourth reference position with respect to the support structure, a current pulse passes from the ninth and tenth tips over a gap to the eleventh and twelft!i tips respectively, and such that when the drive mass is displaced from the fourth reference position in the first direction by the distance +d3 a current pulse passes from the tenth tip to the eleventh tip, and such that when the drive mass is displaced from the fourth reference position in the first direction by the distance -d3 a current pu lse passes from the n inth tip to the twelfth tip.
12. The gyroscope of Claim 1 1 wherein the gyroscope is monolithically integrated.
1 3. The gyroscope of Claim 12, wherein the support structure, the drive mass, the first sense mass, and the second sense mass are vacuum-sealed between top and bottom cap wafers.
14. The gyroscope of Claim 13, wherein the drive mass driver comprises capacitive comb drives.
1 5. The gyroscope of Claim 3, further comprising a first sense mass driver configured to drive the first sense mass to oscillate in the second direction at the resonant frequency of the first sense mass, and wherein the resonant frequency of the first sense mass is substantially larger than a drive frequency of the drive mass.
1 6. The gyroscope of Claim 3, wherein the resonant frequency of the first sense mass is approximately equal to a drive frequency of the drive mass.
1 7. A monol ithic gyroscope comprising:
a support structure;
a drive mass springed!y coupled to the support structure;
a drive mass driver configured to drive the drive mass to oscillate with respect to the support structure in a first direction;
a first sense mass springedly coupled to the drive mass, wherein the first sense mass is configured to move with respect to the drive mass in a second d irection which is substantial ly orthogonal to the first direction;
and
a first trigger configured to pass from an open state to a closed state when the first sense mass passes through a first reference position such that rotation of the support structure about an axis may be determined by monitoring the state of the first proximity switch w ith respect to time.
I 8. The gyroscope of Ciaim 1 7, wherein the first direction comprises an x- direction, the second direction comprises a y-direction. and the axis comprises a y-axis.
19. The gyroscope of Claim 1 8. wherein the first sense mass is configured to move in response to Coriolis forces from rotation of the support structure about the y-axis, the y-axis being substantially orthogonal to both the z- and x-directions.
20. The gyroscope of Claim 1 9, wherein the first trigger comprises a digital trigger comprising a first proximity switch coupled between the drive mass and the first sense mass.
21. The gyroscope of Claim 20, further comprising:
a second sense mass springedly coupled to the drive mass, wherein the second sense mass is configured to move with respect to the drive mass in approximately on ly the y- direction in response to Coriol is forces from rotation of the support structure about the z-axis; and
a second digital trigger comprising a second proximity switch coupled between the drive mass and the second sense mass and configured to pass from an open state to a closed state when the second sense mass passes through a reference position with respect to the drive mass such that rotation of the support structure about the z-axis may be determ ined by mon itoring the state of the second proximity switch.
22. The gyroscope of Claim 23, further comprising a third d igital trigger comprising a third proximity switch coupled between the drive mass and the support structure and configured to pass from an open state to a closed state when the drive mass passes through a th ird reference position such that acceleration of the support structure in the x- direction may be determ ined by monitoring the state of the third proximity switch.
23. The gyroscope of Claim 22, wherein each of the first, second, and third switches comprises four electron tunneling electrode tips configured with respect to each other such that the fi rst, second, and th ird switches pass through closed states when the drive mass, the first sense mass, and the second sense mass respectively are displaced from their respective reference pos itions by a distance of ±d l , ±d2, and ±d3 respectively in their respective directions of oscillation.
24. The gyroscope of Claim 23, further comprising a first sense mass driver configured to drive the ilrst sense mass to oscil late in the z-direction at the resonant frequency of the first sense mass, wherein the resonant frequency of the first sense mass is substantially larger than a drive frequency of the drive mass.
25. The gyroscope of C laim 23, wherein the resonant frequency of the first sense mass is approximately equal to a drive frequency of the drive mass.
26. The gyroscope of Claim 23, wherein the support structure, the drive mass, the drive mass driver, the first sense mass, and the second sense mass are vacuum-sealed between top and bottom cap wafers.
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JP2015507752A (en) | 2015-03-12 |
TW201610392A (en) | 2016-03-16 |
TW201344157A (en) | 2013-11-01 |
TWI495848B (en) | 2015-08-11 |
US8650955B2 (en) | 2014-02-18 |
EP2805132A1 (en) | 2014-11-26 |
EP2805132A4 (en) | 2015-08-26 |
US20130180333A1 (en) | 2013-07-18 |
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