CN203275441U - Sensor circuit - Google Patents
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- CN203275441U CN203275441U CN2013201715040U CN201320171504U CN203275441U CN 203275441 U CN203275441 U CN 203275441U CN 2013201715040 U CN2013201715040 U CN 2013201715040U CN 201320171504 U CN201320171504 U CN 201320171504U CN 203275441 U CN203275441 U CN 203275441U
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- sensing capacitor
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- sensing
- gyro sensor
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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
- G01C19/5776—Signal processing not specific to any of the devices covered by groups G01C19/5607 - G01C19/5719
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01P—MEASURING LINEAR OR ANGULAR SPEED, ACCELERATION, DECELERATION, OR SHOCK; INDICATING PRESENCE, ABSENCE, OR DIRECTION, OF MOVEMENT
- G01P15/00—Measuring acceleration; Measuring deceleration; Measuring shock, i.e. sudden change of acceleration
- G01P15/14—Measuring acceleration; Measuring deceleration; Measuring shock, i.e. sudden change of acceleration by making use of gyroscopes
Abstract
The utility model relates to a sensor circuit. The sensor circuit comprises a micro-electro-mechanical system (MEMS) gyroscope sensor and an integrated circuit (IC). The MEMS gyroscope sensor comprises a first sensing capacitor and a second sensing capacitor; the IC comprises a switching circuit and a capacitance measurement circuit; the switching circuit is configured in a way that the first sensing capacitor is electrically decoupled with a first input terminal of the IC, and the second sensing capacitor is electrically coupled to a second input terminal of the IC; and the capacitance measurement circuit can be configured in a way that the capacitance of the second sensing capacitor of the MEMS gyroscope sensor is measured when a first electric signal is applied to the decoupled first sensing capacitor.
Description
Technical field
Generally speaking, the application relates to electronic circuit, more specifically, relates to the MEMS sensor circuit.
Background technology
MEMS (micro electro mechanical system) (MEMS) comprises the small mechanical equipment of carrying out electric power and mechanical function, and this plant equipment uses the photoetching process of the resemble process that uses with the making integrated circuit to be made.Some MEMS equipment is the sensor that can detect motion, such as accelerometer, or can detect the sensor of angular velocity, such as gyroscope.The capacitive MEMS gyroscope experiences the variation of electric capacity in response to angular velocity varies.The production of MEMS gyro sensor comprises test, any defective in the equipment that this test should fast detecting goes out to process.
The utility model content
Except other aspects, the application has also discussed for the equipment, the system and method that are connected with the MEMS sensor.A kind of exemplary device comprises integrated circuit (IC) and MEMS gyro sensor, and described MEMS gyro sensor comprises the first sensing capacitor and the second sensing capacitor.Described IC comprises on-off circuit and capacitance measurement circuit.Described on-off circuit is configured to the first input end electrolysis coupling of described the first sensing capacitor from described IC is electrically connected to described the second sensing capacitor the second input end of described IC.Described capacitance measurement circuit is configured to measure the electric capacity of described second sensing capacitor of described MEMS gyro sensor during applying the first electric signal to this first sensing capacitor by decoupling zero.
This MEMS gyro sensor does not need extra test capacitors.This just makes this MEMS sensor need less circuit block and circuit junction, has simplified design.
The utility model content part aims to provide the general introduction to subject of this patent application, is not exclusiveness or the exhaustive explanation that aims to provide the application.This paper comprises that embodiment is to provide the further information relevant with present patent application.
Description of drawings
In accompanying drawing (these accompanying drawings not necessarily are drawn to scale), identical numeral can be described the similar parts in different views.Same numbers with different letter suffix can represent the different instances of like.Unrestriced mode briefly shows each embodiment that discusses in the application to accompanying drawing by example.
Fig. 1 shows the block scheme of the part of exemplary MEMS sensor and integrated circuit;
Fig. 2 is the process flow diagram of illustrative methods of realizing the self-test of MEMS sensor;
Fig. 3 shows an exemplary circuit of test MEMS sensor;
Fig. 4 shows another exemplary circuit of test MEMS sensor.
Embodiment
Fig. 1 is the block scheme of the part of an example electronic system, and this electronic system comprises MEMS sensor 105 and IC110.This MEMS sensor can comprise MEMS gyroscope, for example gyrotron.Gyrotron can comprise the detection mass (proof mass) that is suspended on the substrate top.This detects mass at driving direction and mechanical oscillation on perpendicular to the induction direction of this driving direction.External drive source drives this detection mass and enter resonance state on driving direction.When gyroscope is subject to the angle rotation, induct on the induction direction Coriolis (Coriolis) power or Coriolis effect, this Coriolis force or Coriolis effect use sensing capacitor to be detected.
In Fig. 1, sensing capacitor Cgp and Cgn represent the gyroscope Coriolis induction output of IC110.Capacitor Cgp and Cgn drive sensing capacitor.These capacitors are used for the driving loop that monitoring is included in MEMS gyro sensor 105 and IC110.Except other aspects, this gyroscope drives the loop and comprises: the driving capacitor (not shown) of MEMS gyro sensor 105; The output driving amplifier circuit (not shown) of IC110 is in order to produce the mechanical oscillation of MEMS gyro sensor 105; And automatic gain is controlled (AGC) circuit (not shown).This agc circuit regulates that to the electrostatic force that this output driving amplifier circuit provides mechanical oscillation is maintained to desired value.Driven nature sensing capacitor Cgsp and Cgsn are used for the oscillation amplitude of sensing MEMS gyro sensor 105.This gyroscope drives the loop and also comprises top capacitor-voltage (C2V) sensor circuit 120 and phase-shift circuit 125.This top C2V sensor circuit 120 converts the electric capacity of Cgsp and Cgsn to can be observed voltage signal, continues so that drive by this gyroscope the vibration of keeping in the loop.
Bottom C2V sensor circuit 130 converts Coriolis sensing capacitor Cgp and Cgn to voltage.Use 135 pairs of mixting circuits to carry out demodulation from the voltage that drives sensing capacitor Cgsp and Cgsn and obtain with from the voltage that Coriolis sensing capacitor Cgp and Cgn obtain, 140 pairs of demodulation result of use analog to digital converter (ADC) circuit are measured.In some instances, this adc circuit 140 is the sigma-delta adc circuit.
Example in Fig. 1 has only shown a cover driven nature sensing capacitor and a cover Coriolis sensing capacitor.In the multi-axis mems gyroscope sensor, can comprise that for each axle a cover drives sensing capacitor and a cover Coriolis sensing capacitor.For example, the 3 axis MEMS gyro sensor can comprise a cover driven nature sensing capacitor and a cover Coriolis sensing capacitor for each axle in X, Y and Z axis.
For MEMS gyro sensor 105 is tested, can utilize the capacitive MEMS sensor also to can be used as this advantage of actuator.Typically, increase capacitor in the MEMS sensor, when equipment operated under test pattern, these capacitors were used to increase electrostatic charge and drive and detect mass.This test mode need to be made extra capacitor and extra electrical contact.Better method is to use sensing capacitor itself in test.Like this, simplified the design of MEMS gyro sensor due to the parts that do not need to be exclusively used in test.
Fig. 2 is the process flow diagram of illustrative methods 200 of realizing the self-test of MEMS gyro sensor.Under normal mode of operation, the MEMS gyro sensor is electrically connected to IC(for example special IC or ASIC as shown in Figure 1).Under normal mode, this IC measures the electric capacity of Coriolis sensing capacitor of the output of this MEMS gyro sensor.
At frame 205 places, under test pattern, with the first Coriolis sensing capacitor and this IC electrolysis coupling of MEMS sensor.At frame 210 places, the first electric signal is applied to this by on the first Coriolis sensing capacitor of decoupling zero.Apply this first electric signal and can cause detecting the electric capacity that mass moved and changed the second sensing capacitor, at the electric capacity of frame 215 places measurement the second sensing capacitor.Like this, need not to provide revolving force just can test this interaction that detects between the capacitance variations of the movement of mass and this second sensing capacitor to the MEMS gyro sensor.Can measure the first Coriolis sensing capacitor in a similar manner.
Get back to Fig. 1, IC110 comprises the on-off circuit (not shown).This on-off circuit can be worked under normal mode and test pattern.Under normal mode of operation, this on-off circuit can be coupled as the first sensing capacitor Cgp of MEMS sensor 105 and the second Coriolis sensing capacitor Cgn capacity cell pair.This capacity cell is to changing electric capacity in response to acting on the Coriolis effect on this MEMS sensor.Under test pattern, this on-off circuit provides the one or more path to the Coriolis sensing capacitor.
Fig. 3 shows exemplary MEMS gyro sensor 305 under test pattern and the part of IC310.On-off circuit can be with the first sensing capacitor Cgp of MEMS gyro sensor 305 and the first input end electrolysis coupling of IC, and the second sensing capacitor Cgn is electrically coupled to the second input end of IC310.As shown in the figure, this first sensing capacitor Cgp can with bottom C2V sensor circuit 330 electrolysis couplings.This on-off circuit can be connected to internal capacitor 345 bottom C2V sensor circuit 330.
Electric test signal can for example be applied to by the first sensing capacitor Cgp of decoupling zero by test circuit (not shown) or test platform.In some instances, electric signal is sinusoidal signal.In some instances, the MEMS gyro sensor can comprise that electrical contact is to contact the detection mass of this MEMS gyro sensor.As shown in Figure 3, during applying electric test signal, can direct current (DC) driving voltage be applied to the detection mass by electrical contact.This electric test signal and this DC driving voltage provide the static of mobile this detection mass to drive, to imitate the variation of angular velocity.When driving this detection mass, measures static the electric capacity of the second sensing capacitor Cgn.
IC310 also comprises the capacitance measurement circuit that the electric capacity of the second sensing capacitor of MEMS sensor is measured.This capacitance measurement circuit comprises bottom C2V sensor 330 and adc circuit 340.These C2V sensor circuit 330 inductions represent the voltage of the electric capacity of the second sensing capacitor, and this adc circuit 340 produces the digital value of the electric capacity that represents this second sensing capacitor.This capacitance measurement circuit is measured the electric capacity of the second sensing capacitor of MEMS gyro sensor during electric signal is applied to by the first sensing capacitor of decoupling zero.
Can measure in a similar manner the electric capacity of the first sensing capacitor Cgp.The first on-off circuit is the second sensing capacitor Cgn of MEMS gyro sensor and the second input end electrolysis coupling of IC, and the first sensing capacitor Cgp of this MEMS gyro sensor is electrically coupled to the first input end of this IC.Capacitance measurement circuit is configured to measure the electric capacity of the first sensing capacitor Cgn during the second electric signal is applied to by the second sensing capacitor Cgn of decoupling zero.
As setting forth before, described electric test signal can be sinusoidal signal.In some instances, use sinusoidal test signal, measure electric capacity in different phase shifts place of this sinusoidal signal.For example, in order to test the second sensing capacitor Cgn, the first sinusoidal electric signals with first phase-shift value (such as 0 ° of phase shift) can be applied to the first sensing capacitor Cgp.Can measure the electric capacity of the second sensing capacitor Cgn during applying the first sinusoidal signal with first phase-shift value.
Then, the phase-shift value of the first sinusoidal electric signals can be changed into the second phase-shift value (such as 90 ° of phase shifts).Can remeasure the electric capacity of the second sensing capacitor Cgn during applying the first sinusoidal signal with second phase-shift value.Also can locate to measure at other phase-shift value (such as 180 ° and 270 °) electric capacity of sensing capacitor.
Fig. 4 shows another exemplary MEMS gyro sensor 405 under test pattern and the part of IC410.Top C2V sensor 420 circuit convert the oscillating capacitance of MEMS gyro sensor to the oscillating voltage signal.Then, on-off circuit can apply the oscillating voltage signal and measure the electric capacity of Coriolis sensing capacitor (for example sensing capacitor Cgn shown in figure) as electric test signal.
As setting forth before, IC405 comprises that gyroscope drives the pith in loop.In some instances, IC410 comprises the self-starting pierce circuit, drives the loop by the self oscilaltion signal, random " initial disturbance (initialkick) " offered gyroscope.This self oscilaltion signal can be roughly sinusoidal signal, and the frequency of this sinusoidal signal is different from the resonant frequency of (as lower than) MEMS gyro sensor 405.The energy accumulating of initialize signal gets up, and makes MEMS gyro sensor 405 enter resonance state, and under this resonance state, the mechanical oscillation of this MEMS gyro sensor is locked in the MEMS oscillation frequency.
Gyro drives the loop and is locked in the MEMS oscillation frequency.This vibration senses by driving sensing capacitor Cgsp and Cgsn, and the oscillation amplitude of the voltage signal that top C2V sensor circuit 420 generates begins to increase.The amplitude of voltage signal can continue to increase, until cross threshold value (for example 97% of the target oscillation amplitude).When satisfying threshold amplitude, agc circuit is selected to replace the self oscilaltion signal to remove to drive the MEMS gyro sensor from the voltage signal of top C2V sensor 420 as the reference signal.The AGC loop begins to adjust the gain of output driver to keep the target amplitude of vibration.
As setting forth before, gyroscope drives the loop and comprises phase-shift circuit 425 on IC.425 pairs of phase places from the oscillating voltage signal of top C2V sensor circuit 420 of this phase-shift circuit are shifted.In some examples, this phase-shift circuit 425 provides the phase shift of 90 °.On-off circuit can be applied on sensing capacitor dephased oscillating voltage signal as electric test signal.In some examples, receive the sensing capacitor (such as Cgn) and bottom C2V sensor circuit 430 decoupling zeros of electric signal, but keep and the electrically contacting of IC410, to receive electric test signal.
According to some examples, on-off circuit comprises that the electric test signal that multiplexer or MUX circuit 450 come optionally to have 0 ° or 90 ° phase shift offers sensing capacitor.In order to produce the phase shift of 180 ° and 270 °, this on-off circuit can reverse from the signal of top C2V circuit 420 so that the phase shift of 180 ° to be provided, and generates the phase shift of 270 ° with phase-shift circuit 425.In some examples, this on-off circuit can be applied to initial voltage signal another sensing capacitor (for example Cgp but not Cgn) to generate the phase shift of 180 ° and 270 °.
According to some examples, the first sensing capacitor Cgp and the second sensing capacitor Cgn are configured to sensing along the Coriolis effect of first axle (as X-axis) of MEMS gyro sensor.The MEMS gyro sensor can comprise in order to sensing along the second sensing capacitor of the Coriolis effect of the second axle (as Y-axis) pair, also can comprise in order to sensing along the 3rd sensing capacitor of the Coriolis effect of the 3rd axle (as Z axis) pair.
Capacitance measurement circuit can be measured and be configured to sensing along the electric capacity of at least one extra sensing capacitor of the Coriolis effect of the second axle of MEMS gyro sensor or the 3rd axle.For example, Fig. 3 and Fig. 4 IC at least one can comprise for the C2V sensor circuit that drives sensing capacitor with for the Coriolis sensing capacitor of the second axle or the 3rd axle at least.On-off circuit applies electric test signal to one or more sensing capacitors, and capacitance measurement circuit is measured the electric capacity of this sensing capacitor during this electric test signal is applied in.
Note that and only use the sensing capacitor that is used for the sensing Coriolis effect in the MEMS gyro sensor in test, this MEMS gyro sensor does not need extra test capacitors.This just makes this MEMS sensor need less circuit block and circuit junction, has simplified design.
Bu Chongzhushi ﹠amp; Example
Example 1 can comprise following theme (for example a kind of device), and this theme comprises MEMS (micro electro mechanical system) (MEMS) gyroscope and IC.Described MEMS gyro sensor comprises the first sensing capacitor and the second sensing capacitor.Described IC comprises on-off circuit and capacitance measurement circuit, and this on-off circuit is configured to the first input end electrolysis coupling with described the first sensing capacitor and described IC, and described the second sensing capacitor is electrically coupled to the second input end of described IC; Described capacitance measurement circuit is configured to be applied at the first electric signal the electric capacity that this measures described second sensing capacitor of described MEMS gyro sensor during by the first sensing capacitor of decoupling zero.
Example 2 can comprise, or alternatively with the subject combination of example 1 to comprise alternatively the first sensing capacitor and the second sensing capacitor that is configured to the Coriolis effect of the described MEMS gyro sensor of sensing under normal mode of operation.
Example 3 can comprise, or alternatively with the subject combination of one of them or combination in any of example 1 and 2 to comprise alternatively on-off circuit, this on-off circuit is configured to described the second input end electrolysis coupling with described second sensing capacitor of described MEMS gyro sensor and described IC, and described first sensing capacitor of described MEMS gyro sensor is electrically coupled to the described first input end of described IC.Described capacitance measurement circuit is configured to be applied at the second electric signal the electric capacity that this measures described first sensing capacitor of described MEMS gyro sensor during by the second sensing capacitor of decoupling zero alternatively.
Example 4 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 1-3 to comprise alternatively: apply the first sinusoidal electric signals to described the first sensing capacitor, wherein this first sinusoidal electric signals has the first phase shift; Measure the electric capacity of described the second sensing capacitor during applying described the first sinusoidal signal with described first phase shift; The second phase shift is changed in the phase shift of described the first sinusoidal electric signals; And the electric capacity that remeasures described the second sensing capacitor during applying described the first sinusoidal signal with described second phase shift.
Example 5 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 1-4 to comprise alternatively: the capacitance-voltage sensor circuit is configured to the voltage that sensing represents the electric capacity of described the second sensing capacitor; And analog to digital converter (ADC) circuit, be configured to produce the digital value of the electric capacity that represents described the second sensing capacitor.
Example 6 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 1-5 to comprise alternatively capacitor-voltage sensor, this capacitor-voltage sensor is configured to convert the oscillating capacitance of described MEMS gyro sensor to the oscillating voltage signal, and described on-off circuit is configured to apply described oscillating voltage signal alternatively as described the first electric signal.
Example 7 can comprise, or be configured to comprise alternatively phase-shift circuit that described oscillating voltage signal is carried out phase shift with the subject combination of example 6 alternatively, and described on-off circuit is configured to apply oscillating voltage signal after this phase shift alternatively as described the first electric signal.
Example 8 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 1-7 to comprise alternatively test circuit, this test circuit is configured to during described the first electric signal is applied in, direct current (DC) voltage is applied to the detection mass of described MEMS gyro sensor.
Example 9 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 1-8 to comprise alternatively the first sensing capacitor and the second sensing capacitor, this first sensing capacitor and the second sensing capacitor are configured to sensing along the Coriolis effect of the first axle of described MEMS gyro sensor, and described capacitance measurement circuit is configured to measure the electric capacity of at least one extra sensing capacitor alternatively, and described at least one extra sensing capacitor is configured to sensing along the Coriolis effect of the second axle of described MEMS gyro sensor.
example 10 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 1-9 to comprise alternatively the MEMS gyro sensor, this MEMS gyro sensor comprises removable detection mass, described the first sensing capacitor and described the second sensing capacitor are configured to the Coriolis effect of this detection mass of sensing when described IC works alternatively under normal mode of operation, described the first electric signal is applied to described the first sensing capacitor by decoupling zero and is configured to alternatively make this detection mass to move under test pattern, described IC is configured to alternatively during under described test pattern, described detection mass moves, measure the electric capacity of described the second sensing capacitor.
Example 11 can comprise following theme, or alternatively with the subject combination of one of them or the combination in any of example 1-10 to comprise following theme (a kind of device for implementing action for example, method, perhaps comprise the machine readable media that makes this machine implement the instruction of action when being carried out by machine), comprising: with the first sensing capacitor and the IC electrolysis coupling of MEMS gyro sensor; Apply the first electric signal to this first sensing capacitor by decoupling zero; And the electric capacity of measuring the second sensing capacitor of described MEMS sensor during applying described the first electric signal.
Example 12 can comprise, or alternatively with the subject combination of example 11 to comprise alternatively: under normal mode of operation, use the Coriolis effect of described the first sensing capacitor and described the second described MEMS gyro sensor of sensing capacitor sensing.
Example 13 can comprise, or alternatively with the subject combination of one of them or combination in any of example 11 and 12 to comprise alternatively: with described the second sensing capacitor and the described IC electrolysis coupling of described MEMS sensor; Apply the second electric signal to described the second sensing capacitor; And the electric capacity of measuring described first sensing capacitor of described MEMS gyro sensor during applying described the second electric signal.
Example 14 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 11-13 to comprise alternatively: apply the first sinusoidal electric signals to described the first sensing capacitor, wherein this first sinusoidal electric signals has the first phase shift; Measure the electric capacity of described the second capacitor during applying described the first sinusoidal signal with described first phase shift; The second phase shift is changed in the phase shift of described the first sinusoidal electric signals; And the electric capacity that remeasures described the second capacitor during applying described the first sinusoidal signal with described second phase shift.
Example 15 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 11-14 to comprise alternatively: sensing represents the voltage of the electric capacity of described the second sensing capacitor; And use adc circuit to produce the digital value of the electric capacity that represents described the second sensing capacitor.
Example 16 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 11-15 to comprise alternatively: receive oscillator signal from described MEMS gyro sensor at the 3rd input end of described IC; And apply described oscillator signal from described MEMS gyro sensor as described the first electric signal.
Example 17 can comprise, or alternatively with the subject combination of example 16 to comprise alternatively: the described oscillator signal from described MEMS gyro sensor is carried out phase shift; And apply described dephased oscillator signal as described the first electric signal.
Example 18 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 11-17 to comprise alternatively: the detection mass that DC voltage is applied to described MEMS gyro sensor during applying described the first electric signal.
Example 19 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 11-18 to comprise alternatively: use described the first sensing capacitor and described the second sensing capacitor sensing along the Coriolis effect of the first axle of described MEMS gyro sensor, and measure the electric capacity of at least one extra sensing capacitor, this at least one extra sensing capacitor is configured to sensing along the Coriolis effect of the second axle of described MEMS gyro sensor.
Example 20 can comprise, or alternatively with the subject combination of one of them or the combination in any of example 11-19 to comprise alternatively: under the normal mode of operation of described MEMS gyro sensor, use the Coriolis effect of the detection mass of described the first sensing capacitor and described the second described MEMS gyro sensor of sensing capacitor sensing; During the test pattern of described MEMS gyro sensor, apply described the first electric signal to described the first sensing capacitor by decoupling zero, so that the detection mass of described MEMS gyro sensor moves; And the electric capacity of measuring described the second sensing capacitor comprises: the electric capacity of measuring described second sensing capacitor of described MEMS gyro sensor during under described test pattern, described detection mass moves.
Example 21 can comprise following theme, or alternatively with example 1-20 in any one or arbitrary part of a plurality of examples or the combination of a plurality of arbitrary portions combine to comprise following theme, this theme can comprise: be used for to carry out the device of any one or several functions of the function of example 1-20, or comprise the machine readable media of the instruction of any one or several functions in the function that makes machine execution example 1-20 when carried out by machine.
Above-mentioned detail specifications is with reference to accompanying drawing, and accompanying drawing is also the part of described detail specifications.Accompanying drawing has shown the concrete example that can use the application in graphic mode.These embodiment are known as " example " in this application.Related all publications, patent and the patent document of the application be all as the application's reference content, although they are in addition references respectively.If there is purposes difference between the application and reference paper, regard the application's the replenishing of purposes as with reference to the purposes of file, if there is implacable difference between the two, the purposes with the application is as the criterion.
In this application, normally used the same with patent document, term " " or " a certain " expression comprises one or more, but other situations or when using " at least one " or " one or more " should except.In this application, except as otherwise noted, otherwise use the term "or" refer to without exclusiveness or, make " A or B " comprising: " A but be not B ", " B but be not A " and " A and B ".In claims, term " comprises " and " therein " is equal to that each term " comprises " and the popular English of " wherein ".Equally, in appended claims, term " comprises " and " comprising " is open, namely, system, equipment, article or step comprise parts those parts listed after in claim this term, within still being considered as dropping on the scope of this claim.And in claim below, term " first ", " second " and " the 3rd " etc. as label, are not only that object is had quantitative requirement.
The effect of above-mentioned explanation is to explain orally and unrestricted.Above-described embodiment (or one or more aspects of embodiment) can be combined with.Can on the basis of understanding above-mentioned instructions, utilize certain routine techniques of prior art to carry out other examples.In accordance with 37C.F.R. § 1.72(b) regulation summary is provided, allow the reader to determine fast the disclosed character of present technique.Should be understood that when submitting this summary to that this summary is not used in scope or the meaning of explaining or limiting claim.Equally, in superincumbent embodiment, various features can be classified into rationalizes the disclosure.This open feature that does not should be understood to failed call is essential to any claim.On the contrary, the application's theme can be that feature is less than all features of specific disclosed example.Therefore, following claim is incorporated in embodiment accordingly, and each claim is all as an independent example.Should be referring to appended claim, and all scopes of the equivalent enjoyed of these claims, determine the application's scope.
Claims (10)
1. sensor circuit comprises:
The micro-electromechanical system (MEMS) gyro sensor comprises the first sensing capacitor and the second sensing capacitor; And
Integrated circuit (IC) comprises:
On-off circuit is configured to the first input end electrolysis coupling with described the first sensing capacitor and described IC, and described the second sensing capacitor is electrically coupled to the second input end of described IC; And
Capacitance measurement circuit is configured to be applied at the first electric signal the electric capacity that this measures described second sensing capacitor of described MEMS gyro sensor during by the first sensing capacitor of decoupling zero.
2. sensor circuit as claimed in claim 1, wherein, described the first sensing capacitor and described the second sensing capacitor are configured to the Coriolis effect of the described MEMS gyro sensor of sensing under normal mode of operation.
3. sensor circuit as claimed in claim 2, wherein, described on-off circuit is configured to described the second input end electrolysis coupling with described second sensing capacitor of described MEMS gyro sensor and described IC, and described first sensing capacitor of described MEMS gyro sensor is electrically coupled to the described first input end of described IC; And
Wherein, described capacitance measurement circuit is configured to be applied at the second electric signal the electric capacity that this measures described first sensing capacitor of described MEMS gyro sensor during by the second sensing capacitor of decoupling zero.
4. sensor circuit as claimed in claim 1 wherein, applies the first electric signal and comprises:
Apply the first sinusoidal electric signals to described the first sensing capacitor, wherein this first sinusoidal electric signals has the first phase shift;
Measure the electric capacity of described the second sensing capacitor during applying described the first sinusoidal signal with described first phase shift;
The second phase shift is changed in the phase shift of described the first sinusoidal electric signals; And
Remeasure the electric capacity of described the second sensing capacitor during applying described the first sinusoidal signal with described second phase shift.
5. sensor circuit as claimed in claim 1, wherein, described IC comprises:
The capacitance-voltage sensor circuit is configured to the voltage that sensing represents the electric capacity of described the second sensing capacitor;
The analog to digital converter adc circuit is configured to produce the digital value of the electric capacity that represents described the second sensing capacitor.
6. sensor circuit as claimed in claim 1, wherein, described IC comprises:
Capacitor-voltage sensor is configured to convert the oscillating capacitance of described MEMS gyro sensor to the oscillating voltage signal, and
Wherein, described on-off circuit is configured to apply described oscillating voltage signal as described the first electric signal.
7. sensor circuit as claimed in claim 6,
Wherein, described IC comprises and is configured to phase-shift circuit that described oscillating voltage signal is carried out phase shift; And
Wherein, described on-off circuit is configured to apply oscillating voltage signal after this phase shift as described the first electric signal.
8. sensor circuit as claimed in claim 1, comprise test circuit, and this test circuit is configured to during described the first electric signal is applied in, the direct current dc voltage is applied to the detection mass of described MEMS gyro sensor.
9. sensor circuit as claimed in claim 1, wherein, described the first sensing capacitor and described the second sensing capacitor are configured to sensing along the Coriolis effect of the first axle of described MEMS gyro sensor, and
Wherein, described capacitance measurement circuit is configured to measure the electric capacity of at least one extra sensing capacitor, and described at least one extra sensing capacitor is configured to sensing along the Coriolis effect of the second axle of described MEMS gyro sensor.
10. sensor circuit as claimed in claim 1, wherein, described MEMS gyro sensor comprises removable detection mass,
Wherein, described the first sensing capacitor and described the second sensing capacitor are configured to the Coriolis effect of this detection mass of sensing when described IC works under normal mode of operation,
Wherein, described the first electric signal is applied to described the first sensing capacitor by decoupling zero and is configured to make this detection mass to move under test pattern, and
Wherein, described IC is configured to measure the electric capacity of described the second sensing capacitor during under described test pattern, described detection mass moves.
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| US201261620575P | 2012-04-05 | 2012-04-05 | |
| US61/620,575 | 2012-04-05 |
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| CN2013201715040U Withdrawn - After Issue CN203275441U (en) | 2012-04-05 | 2013-04-08 | Sensor circuit |
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Cited By (19)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN103364593A (en) * | 2012-04-05 | 2013-10-23 | 快捷半导体(苏州)有限公司 | Sensor circuit and method for testing MEMS (micro electro mechanical system) sensor |
| US8978475B2 (en) | 2012-02-01 | 2015-03-17 | Fairchild Semiconductor Corporation | MEMS proof mass with split z-axis portions |
| US9006846B2 (en) | 2010-09-20 | 2015-04-14 | Fairchild Semiconductor Corporation | Through silicon via with reduced shunt capacitance |
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| US8710599B2 (en) | 2009-08-04 | 2014-04-29 | Fairchild Semiconductor Corporation | Micromachined devices and fabricating the same |
Family Cites Families (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP3125675B2 (en) * | 1996-03-29 | 2001-01-22 | 三菱電機株式会社 | Capacitive sensor interface circuit |
| JP5045616B2 (en) * | 2007-08-30 | 2012-10-10 | 株式会社デンソー | Capacitive physical quantity detector |
| KR20130113386A (en) * | 2012-04-05 | 2013-10-15 | 페어차일드 세미컨덕터 코포레이션 | Self test of mems gyroscope with asics integrated capacitors |
-
2013
- 2013-04-04 KR KR1020130036907A patent/KR20130113386A/en not_active Application Discontinuation
- 2013-04-08 CN CN201310119472.4A patent/CN103364593B/en active Active
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| US9352961B2 (en) | 2010-09-18 | 2016-05-31 | Fairchild Semiconductor Corporation | Flexure bearing to reduce quadrature for resonating micromachined devices |
| US9278845B2 (en) | 2010-09-18 | 2016-03-08 | Fairchild Semiconductor Corporation | MEMS multi-axis gyroscope Z-axis electrode structure |
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| CN103364593B (en) * | 2012-04-05 | 2015-05-13 | 快捷半导体(苏州)有限公司 | Sensor circuit and method for testing MEMS (micro electro mechanical system) sensor |
| US10060757B2 (en) | 2012-04-05 | 2018-08-28 | Fairchild Semiconductor Corporation | MEMS device quadrature shift cancellation |
| CN103364593A (en) * | 2012-04-05 | 2013-10-23 | 快捷半导体(苏州)有限公司 | Sensor circuit and method for testing MEMS (micro electro mechanical system) sensor |
| US9094027B2 (en) | 2012-04-12 | 2015-07-28 | Fairchild Semiconductor Corporation | Micro-electro-mechanical-system (MEMS) driver |
| US9625272B2 (en) | 2012-04-12 | 2017-04-18 | Fairchild Semiconductor Corporation | MEMS quadrature cancellation and signal demodulation |
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| US9425328B2 (en) | 2012-09-12 | 2016-08-23 | Fairchild Semiconductor Corporation | Through silicon via including multi-material fill |
Also Published As
| Publication number | Publication date |
|---|---|
| CN103364593B (en) | 2015-05-13 |
| CN103364593A (en) | 2013-10-23 |
| KR20130113386A (en) | 2013-10-15 |
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