Patent Grant
11993509
The present disclosure relates to a MEMS (Micro Electro-Mechanical System) inclinometer having a reduced vibration rectification error.
As is known, inclinometers are devices used for monitoring the angle of inclination of an object or of a structure with respect to one or more reference axes or planes. In particular, inclinometers formed by out-of-plane accelerometers (i.e., accelerometers that are sensitive to accelerations along an axis perpendicular to a reference plane, this axis typically coinciding with the direction of the Earth's gravity) are known, which are designed for measuring the inclination of a surface to which they are constrained.
In the industrial field, inclinometers with extremely high precision and resolution are necessary, for example, for monitoring pointing of antennas, the state of structural health of buildings and other architectural structures and the state of levelling of offshore platforms.
Inclinometers built with MEMS technology are obtained on dice of semiconductor material, for example silicon. This has enabled a wide diffusion of these devices thanks to their small dimensions, high accuracy, possibility of integrating them in electrical circuits in order to improve the performance thereof, and low costs.
The mechanism of operation of MEMS inclinometers is typically based upon a capacitive measurement, i.e., upon measurement of the capacitance associated with at least two metal electrodes, arranged facing one another. For instance, inclinometers are known, each comprising two electrodes arranged facing one another so as to form a capacitor with parallel plane faces, as described in the U.S. patent application US2011/0023604A1.
In the above solution, a teeter-totter architecture is described, which includes a mobile mass, a substrate, a plurality of bottom electrodes and a plurality of top electrodes. The bottom electrodes are fixed to the substrate and face corresponding top electrodes, which are fixed with respect to the mobile mass. The mobile mass lies, at rest, in a reference plane parallel to the substrate, and in use is free to rotate about a central pin, which divides the top electrodes into a first set, which includes the top electrodes arranged on a first side with respect to the central pin, and a second set, which includes the top electrodes arranged on a second side with respect to the central pin. In the resting position, the top electrodes of the first and second sets are equidistant from the respective bottom electrodes and therefore the corresponding capacitors have the same capacitance. In use, when the device is subject to an acceleration directed transversally with respect to the reference plane, the mobile mass turns about the central pin. Consequently, it may happen, for example, that the top electrodes of the first set approach the respective bottom electrodes and that the top electrodes of the second set move farther away from the respective bottom electrodes, thus generating a difference of capacitance, which is indicative of the inclination of the device. In greater detail, a difference arises between a first capacitance C1, which depends upon the position of the top electrodes of the first set, and a second capacitance C2, which depends upon the position of the top electrodes of the second set. In particular, the first and second capacitances C1, C2 can be described by the following formulae:
where ε0 is the vacuum permittivity, A is the area of the electrodes, g0 is the distance at rest between top electrodes and bottom electrodes. Moreover, x represents a displacement, which, in resting conditions, and therefore when the first and second capacitances C1, C2 are equal, is zero. Instead, when the inclinometer is inclined by an angle of inclination α, x represents the displacement of the centroid of the top electrodes of the first set in direction of the corresponding bottom electrodes.
To guarantee accuracy in the measurements of capacitance, and therefore of inclination, the MEMS inclinometers should be robust with respect to undesired external stimuli. In particular, the two main sources of disturbance are mechanical stresses, for example due to temperature variations or to deformations of the device, and spurious vibrations of the mobile mass about the pin, which generally have a frequency from a few hertz to a few kilohertz.
For instance, in the presence of spurious vibrations of the mobile mass about the resting position, the displacement x oscillates between a positive value Vp and a negative value Vn, which are the same as one another in absolute value. In addition, the difference between the first and second capacitances C1, C2 is not linear with respect to the displacement x.
In greater detail, if the first and second capacitances C1, C2 have a same area of the electrodes A and a same distance at rest g0, the curve that defines the variation of the difference between the first and second capacitances C1, C2 (referred to in what follows simply as the difference DIFF) as a function of the displacement x is symmetrical, as shown, for example, in
Consequently, also in the presence of the aforementioned vibrations, the contribution of said undesired vibrations to the difference DIFF, based on which the inclination is measured, has a zero average. Consequently, the aforementioned undesired contribution can be removed, for example by applying filtering.
Instead, in the case where the distance at rest between the top electrodes and the corresponding bottom electrodes is not identical for the top electrodes of the first and second sets, and therefore in the case where there is, in resting conditions, an offset gos such that the first and second capacitances C1, C2 can be defined as
the difference DIFF has a plot as a function of the non-symmetrical displacement x, as shown in
In practice, it is known that the tolerances of the current manufacturing processes do not enable elimination of the offset gos. However, various solutions may be implemented to limit the error VRE, albeit only partially. For instance, it is possible to: minimize the offset gos by resorting to more complex and costly manufacturing processes; to reduce the displacement x of the electrodes per acceleration unit, even though this entails a reduction of the sensitivity of the inclinometers, and therefore a greater susceptibility to noise.
In various embodiments, the present disclosure provides a MEMS inclinometer with a reduced error VRE.
In at least one embodiment, a MEMS inclinometer includes a substrate and a first mobile mass suspended over the substrate. In use, the first mobile mass is subject to an acceleration that depends upon an inclination of the inclinometer. A first sensing unit includes a second mobile mass suspended over the substrate. The first sensing unit includes a plurality of elastic elements, each of which is mechanically interposed between the second mobile mass and the substrate and is compliant in a direction parallel to a first axis. The first sensing unit further includes a plurality of elastic structures, each of which is mechanically interposed between the first and second mobile masses and is compliant in a direction parallel to the first axis and to a second axis. The first sensing unit further includes at least one first fixed electrode that is fixed with respect to the substrate, and at least one first mobile electrode that is fixed with respect to the second mobile mass and configured to form a first variable capacitor with the first fixed electrode. Each elastic structure includes at least one respective elongated structure, which, in resting conditions, extends in a direction parallel to a third axis and, in a plane parallel to a plane containing the first axis and the second axis, has main axes of inertia which are transverse with respect to the first and second axes, so that movements of the first mobile mass in a direction parallel to the second axis, caused by said acceleration, cause corresponding movements of the second mobile mass in a direction parallel to the first axis.
In at least one embodiment, a MEMS inclinometer is provided that includes a substrate, a first mobile mass suspended over the substrate and subject, in use, to an acceleration that depends upon an inclination of the inclinometer, and a first sensing unit. The first sensing unit includes: a second mobile mass, suspended over the substrate, the second mobile mass including a first arm extending along a first direction that is parallel to a first axis and a second arm extending along a second direction that is parallel to a second axis, the first axis being perpendicular to the second axis; a first elastic element mechanically coupled between a first side of the second arm of the second mobile mass and the substrate, the first elastic element being compliant along the first direction; a second elastic element mechanically coupled between a second side of the second arm of the second mobile mass and the substrate, the second elastic element being compliant along the first direction, the second side being opposite the first side along the first direction; a third elastic element mechanically coupled between the first side of the second arm of the second mobile mass and the substrate, the third elastic element being compliant along the first direction, the first arm of the second mobile mass disposed between the first elastic element and the third elastic element; a fourth elastic element mechanically coupled between the second side of the second arm of the second mobile mass and the substrate, the fourth elastic element being compliant along the first direction, the first arm of the second mobile mass disposed between the second elastic element and the fourth elastic element; a plurality of elastic structures, each of which is mechanically interposed between the first and second mobile masses and is compliant along the first direction and is rigid along the second direction; at least one first fixed electrode that is fixed with respect to the substrate; and at least one first mobile electrode that is fixed with respect to the second mobile mass and configured to form a first variable capacitor with the first fixed electrode.
For a better understanding of the present disclosure, embodiments thereof are now described, purely by way of non-limiting example, with reference to the attached drawings, wherein:
A MEMS inclinometer 20 (referred to in what follows more briefly as inclinometer) is described hereinafter, which can be used for measuring an inclination out of the plane, i.e., with respect to an axis Z of a Cartesian reference system XYZ. For instance, the inclinometer 20 may be constrained to an object or a structure in order to measure the inclination of the object/structure.
As shown in
The inclinometer 20 further comprises four pillars 24A-24D, which extend vertically starting from the substrate 21, with which they form a monolithic body. The four pillars 24A-24D are therefore made, for example, of the same material as the substrate 21.
In greater detail, each pillar 24A-24D extends in a direction parallel to the axis Z and has a bottom end (not illustrated), fixed to the substrate 21, and a top end 25A-25D.
The inner mass 22 is suspended over the substrate 21 and is substantially cross-shaped and is formed by a first and a second arm 22A, 22B, which are mutually orthogonal and have approximately a parallelepiped shape. The first arm 22A has an axis X′ parallel to the axis X, whereas the second arm 22B has an axis Y′ parallel to the axis Y.
In resting conditions, the inclinometer 20 is symmetrical with respect to a first plane of symmetry Z′Y′, parallel to a plane ZY of the Cartesian reference system XYZ.
At the center, the inner mass 22 delimits a secondary cavity 26, which has approximately a parallelepiped shape, and a plurality of first and second projecting portions 27A, 27B, which are also shaped like parallelepipeds, elongated in a direction parallel to an axis Y of the Cartesian reference system XYZ.
In greater detail, the secondary cavity 26 is of a through type, therefore entirely traverses the inner mass 22 and faces the substrate 21. In addition, the secondary cavity 26 is laterally delimited by a first and a second secondary side wall Pl1, Pl2, which are formed by the inner mass 22 and are parallel to the plane Z′X′. The first and second projecting portions 27A, 27B of the inner mass 22 extend, respectively, from the first and from the second secondary side walls Pl1, Pl2 towards the center of the secondary cavity 26.
A first and a second electrode 29A, 29B are arranged within the secondary cavity 26, which are fixed with respect to the underlying substrate 21 and are made of conductive material, such as polysilicon.
In greater detail, each one of the first and second electrodes 29A, 29B is fixed at a respective first end to the substrate 21 and has a comb-shape, which extends in a direction parallel to the axis X and has projections that extend in a direction parallel to the axis Y. In particular, the projections of the first and second electrodes 29A, 29B are designated, respectively, by 30A and 30B. Furthermore, the projections 30A, 30B of the first and second electrodes 29A, 29B are partially set alongside the first and second projecting portions 27A, 27B, respectively, of the inner mass 22. In practice, the first projecting portions 27A of the inner mass 22 and the projections 30A of the first electrode 29A form a first capacitor 31A, the plates of which are interdigitated. The first capacitor 31A has a first capacitance Cp1. Likewise, the second projecting portions 27B of the inner mass 22 and the projections 30B of the second electrode 29B form a second capacitor 31B, the plates of which are interdigitated; the second capacitor 31B has a second capacitance Cp2.
The first arm 22A of the inner mass 22 is elastically coupled to the top ends 25A-25D of the pillars 24A-24D, via four elastic suspension elements 28A-28D, which are made, for example, of the same material as the inner mass 22 (for instance, polysilicon).
In particular, each elastic suspension element 28A-28D is fixed to a corresponding point of the first arm 22A and to the top end 25A-25D of a corresponding pillar 24A-24D. In addition, each elastic suspension element 28A-28D is compliant in a direction parallel to the axis Y and is rigid in a direction parallel to the axes Z and X.
Without this implying any loss of generality, the elastic suspension elements 28A-28D have a spring structure, of a folded type; i.e., they are each formed by a plurality of main arms (two of which are visible in
The outer mass 23 is suspended over the substrate 21 and is substantially frame-shaped (for example, having a rectangular shape in top view) so as to delimit a main cavity 50, inside of which the inner mass 22 extends. In other words, in top view, the outer mass 23 surrounds the inner mass 22.
Albeit not illustrated, the inner mass 22, the outer mass 23 and the elastic suspension elements 28A-28D have a same thickness.
In greater detail, the main cavity 50 is of a through type, therefore entirely traverses the outer mass 23, and has a parallelepiped shape. Moreover, the main cavity 50 is laterally delimited by a first and a second main side wall PP1, PP2, which are formed by the outer mass 23, are opposite to one another and are parallel to the first plane of symmetry Z′Y′.
The mass of the outer mass 23 is greater than the mass of the inner mass 22. Furthermore, the outer mass 23 is elastically coupled to the inner mass 22 through four elastic transformation elements 32A-32D, each of which is compliant in a direction parallel to the axes Z and Y and is rigid in a direction parallel to the axis X.
Each elastic transformation element 32A-32D has a respective first end 39A-39D, which is fixed to the outer mass 23 and a respective second end 40A-40D, which is fixed to the second arm 22B of the inner mass 22.
In detail, as shown in
In greater detail, each elastic transformation element 32A-32D comprises a top elongated portion 33, a bottom elongated portion 34 and a plurality of transverse portions 35. Moreover, the top elongated portion 33, the bottom elongated portion 34 and the transverse portions 35 of each elastic transformation element 32A-32D are made, for example, of the same material as that of the inner mass 22 and the outer mass 23 (for example, polysilicon) and form a single piece, and in particular a single elongated structure.
In resting conditions, the top elongated portion 33 and the bottom elongated portion 34 have the shape of parallelepipeds, which have axes parallel to the axis X.
In greater detail, in what follows the elastic transformation elements 32A-32D will be referred to as first, second, third and fourth elastic transformation elements 32A-32D, respectively. Moreover, in resting conditions, the top elongated portion 33 and the bottom elongated portion 34 of each one of the first, second, third and fourth elastic transformation elements 32A-32D are separate from one another, and in particular are laterally staggered both in a direction parallel to the axis Y and in a direction parallel to the axis Z, as may be seen, for example, in
Furthermore, the first and second elastic transformation elements 32A, 32B are the same as one another and symmetrical with respect to the first plane of symmetry Z′Y′. Moreover, the top elongated portion 33 and the bottom elongated portion 34 of each one of the first and second elastic transformation elements 32A, 32B have a respective first end, which is fixed to a first end of the second arm 22B of the inner mass 22 and a respective second end, which is fixed to a corresponding point of the outer mass 23. Likewise, the third and fourth elastic transformation elements 32C, 32D are the same as one another and symmetrical with respect to the first plane of symmetry Z′Y′. In addition, the top elongated portion 33 and the bottom elongated portion 34 of each one of the third and fourth elastic transformation elements 32C, 32D have a respective first end, which is fixed to a second end of the second arm 22B of the inner mass 22, and a respective second end, which is fixed to a corresponding point of the outer mass 23.
Once again with reference to the embodiment illustrated in
Furthermore, the first, second, third and fourth elastic transformation elements 32A-32D are directed so that, in top view, the first arm 22A is interposed between the bottom elongated portions 34 of the third and fourth elastic transformation elements 32C, 32D and the top elongated portions 33 of the first and second elastic transformation elements 32A, 32B.
In each one of the first, second, third and fourth elastic transformation elements 32A-32D, the transverse portions 35 have shapes elongated in a direction parallel to the axis Z and are interposed between the bottom elongated portion 34 and the top elongated portion 33, which are arranged on opposite sides of each transverse portion 35. In particular, a top part of each transverse portion 35 laterally contacts the top elongated portion 33, while a bottom part of the transverse portion 35 laterally contacts the bottom elongated portion 34.
In greater detail, as illustrated, without this implying any loss of generality, in
In even greater detail,
Likewise each of
For each section of the first elastic transformation element 32A, it is possible to calculate a centrifugal moment of inertia IC, with respect to the corresponding pair of local axes, by solving the integral:
IC=∫∫r1r2dA,
where r1 and r2 represent the distance of each point of the section from a first axis and a second axis, respectively, of the pair of local axes, while dA is the unit of area of the section. Said centrifugal moment of inertia IC is not null, since the local axes are not axes of symmetry of the section and therefore do not coincide with the main axes of inertia I1, I2. In particular, the main axes of inertia I1, I2 form an angle β with the local axis parallel to the axis Z and the local axis parallel to the axis Y, respectively.
Consequently, with reference, for example, to the section illustrated in
The foregoing considerations regarding the arrangement of the main axes of inertia also apply in the case of the sections of each one of the first, second, third and fourth elastic transformation elements 32A-32D that traverse corresponding transverse portions 35 (as shown, for example, in
In use, the inclinometer 20 undergoes a direct acceleration in a direction parallel to the axis Z, for example due to the acceleration of gravity or vibrations. Furthermore, acting on the outer mass 23 is an external force having a direction opposite to the aforementioned acceleration, said external force having a component parallel to the axis Z, referred to in what follows as the external force Fi. The inner mass 22 is fixed with respect to the substrate 21 for displacements parallel to the axis Z, since the elastic suspension elements 28A-28D via which it is coupled to the substrate 21 are rigid along the axis Z. The external force Fi therefore causes a displacement, with respect to the substrate 21, of the outer mass 23 and of the first end 39A of the first elastic transformation element 32A, in the direction of the external force Fi, as shown in
To a first approximation, the first end 39A does not undergo a deformation of the type described with reference to
In general, the considerations regarding the movements of the median part 41A of the first elastic transformation element 32A can be applied to any part of the first elastic transformation element 32A other than the first and second ends 39A, 40A, albeit with the differences that derive from the different positioning along the axis X. Moreover, the considerations regarding the first elastic transformation element 32A can be applied also to the second, third and fourth elastic transformation elements 32B-32D.
The translations in a direction parallel to the axis Y of the second end 40A-40D of the first, second, third and fourth elastic transformation elements 32A-32D also cause a translation in a direction parallel to the axis Y of the inner mass 22 since, as mentioned previously, the elastic suspension elements 28A-28D are compliant in a direction parallel to the axis Y. Consequently, the relative position between the first projecting portions 27A of the inner mass 22 and the projections 30A of the first electrode 29A changes; at the same time, also the relative position between the second projecting portions 27B of the inner mass 22 and the projections 30B of the second electrode 29B changes. There follow variations of opposite sign of the values of the first and second capacitances Cp1, Cp2 of the first and second capacitors 31A, 31B, which can be detected in a per se known manner and therefore indicative of the inclination undergone by the inclinometer 20.
In practice, an acceleration out of the plane (along the axis Z) causes, in a plane parallel to the plane XY, a displacement of an electrode of each one of the first and second capacitors 31A, 31B, which, as mentioned, have an interdigitated structure, which in turn guarantees a linear dependence of the respective capacitance upon the distance between the electrodes, thus eliminating the problem of the vibration rectification error. In particular, the first and second capacitances Cp1 and Cp2 are directly proportional to (Lov−xos−x) and (Lov+xos+x), respectively, where (Lov-xos) and (Lov+xos), respectively, represent the degree of overlapping along X i) of the first projections 27A of the inner mass 22 and of the projections 30A of the first electrode 29A, and ii) of the second projections 27B of the inner mass 22 and of the projections 30B of the second electrode 29B; x represents the displacement along Y of the inner mass 22 with respect to the resting position.
In detail, the inclinometer 70 comprises a first part 100, which is the same as the inclinometer 20. In addition, the inclinometer 70 comprises a second part 102; the first and second parts 100, 102 are symmetrical with respect to a second plane of symmetry S, parallel to the plane ZX, and moreover share the substrate 21 and the outer mass 23. Furthermore, except where specified otherwise, the elements of the second part 102 are designated by the same reference numbers as those of the corresponding elements of the inclinometer 20, increased by 50. In practice, both the first and the second parts 100, 102 function in the same way as the inclinometer 20, except for the differences described hereinafter.
In detail, the ensemble formed by the inner mass 22, the pillars 24A-24D, the elastic suspension elements 28A-28D, the first and second projections 27A, 27B of the inner mass 22, the first, second, third and fourth elastic transformation elements 32A-32D and the first and second electrodes 29A, 29B forms a first sensing unit, which is the same as a second sensing unit, which is formed by the ensemble constituted by the inner mass 72, the pillars 74A-74D, the elastic suspension elements 78A-78D, the first and second projections 77A, 77B of the inner mass 72, the first, second, third and fourth elastic transformation elements 82A-82D and the first and second electrodes 79A, 79B, except for a translation along the axis Y and for the aspect described in what follows.
In detail, in each one of the first, second, third and fourth elastic transformation elements 82A-82D of the second part 102, the arrangement of the respective top elongated portion 83 and of the respective bottom elongated portion 84 is reversed with respect to what occurs in the corresponding elastic transformation element 32A-32D of the first part 100. In other words, with reference, for example, to the first elastic transformation element 82A of the second part 102 (but the same considerations apply to the second, third and fourth elastic transformation elements 82B-82D), the bottom elongated portion 84 has a co-ordinate along Y smaller than the co-ordinate along Y of the top elongated portion 83. In this way, with reference, for example, to the fourth elastic transformation element 82D of the second part 102, this has a symmetrical shape, relative to the second plane of symmetry S, with respect to the first elastic transformation element 32A of the second part 100.
In use, in the presence of an acceleration directed out of the plane, the movement (for example, designated by MZ in
In practice, by electrically connecting in an appropriate way the first and second electrodes 29A, 29B of the first part 100 and the first and second electrodes 79A, 79B of the second part 102, it is possible to improve the estimation of the inclination, and therefore of the acceleration along Z, or carry out a measurement of acceleration in a direction parallel to the axis Y.
In particular, recalling that the first and second capacitors 31A, 31B of the first part 100 have a first and a second capacitance Cp1, Cp2, respectively, and denoting by Cp3 and Cp4, respectively, the capacitances of the first and second capacitors 81A, 81B of the second part 102, in order to render the measurement of the acceleration along Z independent of possible accelerations along Y, it is possible to determine the estimation of the acceleration along Z on the basis of the following quantity: DELTA_Z=(Cp2+Cp3)−(Cp1+Cp4). In fact, the contributions to the quantity DELTA_Z due to the variations of the values of capacitance Cp1-Cp4 caused by possible accelerations undergone by the inclinometer 70 along Y cancel out.
Moreover, it is possible to obtain a measurement of the acceleration to which the inclinometer 70 is subjected in a direction parallel to the axis Y, based on the following quantity DELTA_Y=(Cp1+Cp3)−(Cp2+Cp4). In fact, the contributions to the quantity DELTA_Y due to the variations of the values of capacitance Cp1-Cp4 caused by possible accelerations to which the inclinometer 70 is subjected in a direction parallel to the axis Z cancel out.
As shown in
In detail, the inclinometer 220 comprises a first and a second anchorage portion 200, 202, which are made of the same material as the outer mass 23, with respect to which they are fixed and with which they form a single piece. In addition, the first and second anchorage portions 200, 202 have the shape of parallelepipeds that extend towards the center of the main cavity 50, starting, respectively, from a third and a fourth main side wall PP3, PP4 of the main cavity 50, which are formed by the outer mass 23, are opposite to one another and are parallel to the plane Z′X′. The first and second anchorage portions 200, 202 are the same as one another and symmetrical with respect to the plane Z′X′. Furthermore, the first and second anchorage portions 200, 202 have the same thickness as the outer mass 23.
In addition, with reference, for example, to the first elastic transformation element, here designated by 232A (but the same considerations also apply to the second, third and fourth elastic transformation elements 232B-232D), this has a folded shape.
In detail, the first elastic transformation element 232A comprises a first and a second elongated structure 240, 242, and a connection arm 244, which are made of the same material as the inner mass 22 (for example, polysilicon).
Each one of the first and second elongated structures 240, 242 comprises a respective top elongated portion (designated by 233′ and 233″ in the case of the first and second elongated structures 240, 242, respectively) and a respective bottom elongated portion (designated by 234′ and 234″ in the case of the first and second elongated structures 240, 242, respectively), which, in resting conditions, have the shape of parallelepipeds with axes parallel to the axis X. In addition, each of the first and second elongated structures 240, 242 comprises a respective plurality of transverse portions (designated by 235′ and 235″ in the case of the first and second elongated structures 240, 242, respectively), which, without this implying any loss of generality, are the same as one another and have the shape of parallelepipeds with axes parallel to the axis Z, which are, for example, equispaced in a direction parallel to the axis X. Moreover, with reference for brevity to just the first elongated structure 240 (but the same considerations apply to the second elongated structure 242), the mutual arrangement of the top elongated portion 233′, the bottom elongated portion 234′, and the transverse portions 235 is, for example, the same as what has been described as regards the first elastic transformation element 32A illustrated in
The connection portion 244 has the shape of a parallelepiped, with walls parallel alternately to the plane ZY or to the plane ZX and has a thickness equal to the thickness of the outer mass 23.
In even greater detail, each one of the top elongated portion 233′ and the bottom elongated portion 234′ of the first elongated structure 240 is fixed, at a respective first end, to a corresponding point of the second arm 22B of the inner mass 22, as well as, at a respective second end, to a corresponding point of the connection portion 244. Furthermore, each one of the top elongated portion 233″ and the bottom elongated portion 234″ of the second elongated structure 242 is fixed, at a respective first end, to a corresponding point of the first anchorage portion 200, as well as, at a respective second end, to a corresponding point of the connection portion 244.
As explained previously with reference to
In use, the first, second, third and fourth elastic transformation elements 232A-232D behave in the same way as the first, second, third and fourth elastic transformation elements 32A-32D illustrated in
The advantages that the present inclinometer affords emerge clearly from the foregoing description. In particular, the present inclinometer enables conversion of an out-of-plane acceleration into an in-plane movement, so as to favor, for the purposes of measurement of an acceleration, linearity of the variation of capacitance of a variable capacitor with interdigitated electrodes when the latter are moved in a direction parallel to the direction of elongation of the respective projections, which are interdigitated with respect to one another. In this way, the error VRE is reduced. Furthermore, at least some of the embodiments described are suited not only to the measurement of out-of-plane accelerations, but also to use as in-plane accelerometers.
Finally, it is clear that modifications and variations may be made to the inclinometer described and illustrated herein, without thereby departing from the scope of the present disclosure.
For instance, the shape of the elastic transformation elements may be different from what has been described. For instance, the shape of the transverse portions may be different from what has been described. In this regard, the number and spacing of the transverse portions, as also possibly the number of foldings in the case of elastic transformation elements of a folded type, may be chosen as a function of the desired elasticity for the elastic transformation elements. In any case, the presence of at least one transverse portion enables mechanical coupling of the corresponding bottom and top elongated portions, and therefore prevents the latter from undergoing deformation in an independent way, thereby reducing the effectiveness of the conversion of the out-of-plane acceleration into the in-plane movement.
It is moreover possible, considering any elastic transformation element, for the orientation of the main axes of inertia to vary as a function of the position along X of the plane (parallel to Z′Y′) of the section considered. However, should it happen that, in one or more sections, the orientations of the corresponding main axes of inertia coincide with the axes Z and Y, there would be a reduction in the effectiveness of the conversion of the out-of-plane acceleration into the in-plane movement.
Finally, the various embodiments described may be combined so as to provide further solutions.
The various embodiments described above can be combined to provide further embodiments. These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
| Number | Date | Country | Kind |
|---|---|---|---|
| 102020000003868 | Feb 2020 | IT | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 20050109109 | Eskridge et al. | May 2005 | A1 |
| 20080173092 | Hattori et al. | Jul 2008 | A1 |
| 20100122579 | Hsu et al. | May 2010 | A1 |
| 20110023604 | Cazzaniga et al. | Feb 2011 | A1 |
| 20140283605 | Baldasarre et al. | Sep 2014 | A1 |
| 20160084872 | Naumann | Mar 2016 | A1 |
| 20160305780 | Comi et al. | Oct 2016 | A1 |
| 20170108336 | Boysel et al. | Apr 2017 | A1 |
| 20170184400 | Valzasina | Jun 2017 | A1 |
| Number | Date | Country |
|---|---|---|
| 101236214 | Aug 2008 | CN |
| Number | Date | Country | |
|---|---|---|---|
| 20210261403 A1 | Aug 2021 | US |
