Patent Description:
In a known manner, microelectromechanical mirror devices are used in portable apparatuses, such as for example smartphones, tablets, notebooks, PDAs, for optical applications, in particular to direct light radiation beams generated by a light source (for example laser) in a desired manner. Due to their small size, these devices allow stringent requirements as to space occupation, in terms of area and thickness, to be complied with.

For example, microelectromechanical mirror devices are used in miniaturized projectors apparatuses (so-called picoprojectors), capable of projecting images from a distance and generating desired light patterns.

Microelectromechanical mirror devices generally include a tiltable structure carrying a suitable reflecting (or mirror) surface, elastically supported above a cavity and made from a body of semiconductor material, so as to be movable, for example with tilt or rotation movement out of a main extension plane, to direct the incident light beam in a desired manner.

The rotation of the mirror device is controlled through an actuation system which may be, for example, of electrostatic, electromagnetic or piezoelectric type.

Electrostatic actuation systems generally have the disadvantage of requiring high operating voltages, while electromagnetic actuation systems generally entail high power consumption; it has therefore been proposed to control movement of the tiltable mirror structure with piezoelectric actuation.

Mirror devices with piezoelectric actuation have the advantage of requiring reduced actuation voltages and power consumption with respect to devices with electrostatic or electromagnetic actuation. Furthermore, it is possible to exploit the inverse piezoelectric effect to provide piezoresistive sensor elements for sensing the driving state of the mirror and providing a feedback signal to allow a feedback control of the actuation.

The present Applicant has realized that known solutions of mirror devices with piezoelectric actuation have, however, a few limitations, which do not allow to fully exploit their advantages.

In particular, there are applications wherein the need is felt to increase the opening angle of the tiltable mirror structure (that is, the extent of rotation out of the plane), without increasing the size of the microelectromechanical device and also without reducing the feedback signal provided by the piezoresistive sensor and without compromising the reliability of the device.

Known solutions do not allow this need to be easily satisfied.

<CIT> discloses a microelectromechanical device, having: a fixed structure defining a cavity; a tiltable structure, elastically suspended in the cavity and having a main extension in a horizontal plane; a piezoelectrically driven actuation structure, which can be biased for causing rotation of the tiltable structure about at least one first rotation axis belonging to the horizontal plane and is interposed between the tiltable structure and the fixed structure. The actuation structure has at least one first pair of driving arms, which carry respective regions of piezoelectric material and are elastically coupled to the tiltable structure on opposite sides of the first rotation axis, by means of respective elastic decoupling elements, which have a high stiffness in regard to movements out of the horizontal plane and are compliant in regard to torsion about the first rotation axis.

<CIT> discloses an optical scanner and image forming apparatus, capable of exhibiting a desired oscillation characteristic by changing the resonance frequency of a movable plate. The actuator has rigidity change means for changing the torsional rigidity of a pair of shaft members having a longitudinal shape and coupled to the movable plate. The rigidity change means include a pair of piezoelectric elements which are driven to expand and contract in a direction perpendicular to the longitudinal direction of the shaft members, to vary the shape of the cross section and changing the torsional rigidity of the shaft members.

The aim of the present solution is therefore to provide a microelectromechanical mirror device with piezoelectric actuation having an improved opening angle.

According to the present solution, a microelectromechanical mirror device is provided, as defined in the attached claims.

For a better understanding of the present invention, preferred embodiments thereof are now described, purely by way of non-limiting example, with reference to the attached drawings, wherein:.

<FIG> schematically illustrates a microelectromechanical mirror device, based on MEMS technology, indicated as a whole with <NUM>; this device generally has the structure described in detail in <CIT> filed in the name of the same Applicant.

The microelectromechanical device <NUM> is formed in a die <NUM>' of semiconductor material, in particular silicon, and is provided with a tiltable structure <NUM>, having a main extension in a horizontal plane xy and arranged to rotate around a rotation axis, parallel to a first horizontal axis x of the aforementioned horizontal plane xy.

The aforementioned rotation axis represents a first median axis of symmetry X for the microelectromechanical device <NUM>; a second median axis of symmetry Y for the same microelectromechanical device <NUM> is parallel to a second horizontal axis y, orthogonal to the first horizontal axis x and defining, with the same first horizontal axis x, the horizontal plane xy.

The tiltable structure <NUM> is suspended above a cavity <NUM>, formed in the die <NUM>', and defines a supporting structure, which carries a reflecting surface <NUM>' at the top, to define a mirror structure.

The tiltable structure <NUM> is elastically coupled to a fixed structure <NUM>, defined in the same die <NUM>'. In particular, the fixed structure <NUM> forms, in the horizontal plane xy, a frame <NUM>' which delimits and surrounds the aforementioned cavity <NUM> and also has a first and a second support (or anchoring) element 5a, 5b, extending longitudinally along the first median axis of symmetry X inside the cavity <NUM> from the same frame <NUM>', on opposite sides of the tiltable structure <NUM> (along the first horizontal axis x).

The tiltable structure <NUM> is supported by the first and the second support elements 5a, 5b, whereto it is elastically coupled through a first and, respectively, a second elastic suspension element 6a, 6b, having high stiffness with respect to movements out of the horizontal plane xy (along an orthogonal axis z, transverse to the same horizontal plane xy) and yielding with respect to torsion around the first horizontal axis x. The first and the second elastic suspension elements 6a, 6b extend overall along the first median axis of symmetry X, between the first, respectively, the second support elements 5a, 5b and a facing side of the tiltable structure <NUM>, whereto they are coupled at a central portion thereof.

In the illustrated embodiment, the first and second elastic suspension elements 6a, 6b are of linear type.

The first and second elastic suspension elements 6a, 6b couple the tiltable structure <NUM> to the fixed structure <NUM>, allowing it to rotate around the first rotation axis and providing a high stiffness with respect to movements out of the plane, thus ensuring a high ratio between the frequencies of spurious movements out of the horizontal plane xy and the rotation frequency around the first rotation axis.

The microelectromechanical device <NUM> further comprises an actuation structure <NUM>, coupled to the tiltable structure <NUM> and configured to cause rotation thereof around the first rotation axis; the actuation structure <NUM> is interposed between the tiltable structure <NUM> and the fixed structure <NUM> and also contributes to supporting the tiltable structure <NUM> above the cavity <NUM>.

This actuation structure <NUM> comprises a first pair of driving arms formed by a first and a second driving arm 12a, 12b, arranged on opposite side of, and symmetrically with respect to, the first median axis of symmetry X and the first support element 5a, and having a longitudinal extension parallel to the first horizontal axis x and to the aforementioned first support element 5a.

In the embodiment illustrated in <FIG>, the driving arms 12a, 12b have a generically trapezoidal (or "fin") shape, with the longer side parallel to the second horizontal axis y integrally coupled to the frame <NUM>' of the fixed structure <NUM> and the shorter side parallel to the same second horizontal axis y elastically coupled to the tiltable structure <NUM>. Each driving arm 12a, 12b therefore has a respective first end integrally coupled to the frame <NUM>' of the fixed structure <NUM> and a respective second end elastically coupled to the tiltable structure <NUM>, through a first and respectively, second elastic decoupling element 14a, 14b.

Each driving arm 12a, 12b is suspended above the cavity <NUM> and carries, at a top surface thereof (opposite to the same cavity <NUM>) a respective piezoelectric structure <NUM> (in particular including PZT - Lead Zirconate Titanate), having for example substantially the same extension in the horizontal plane xy with respect to the driving arm 12a, 12b.

This piezoelectric structure <NUM> (in a manner not illustrated in detail) is formed by the superimposition of a bottom electrode region, of a suitable conductive material, arranged above the corresponding driving arm 12a, 12b; a piezoelectric material region (for example made by a thin PZT film) arranged on the aforementioned bottom electrode region; and a top electrode region arranged on the piezoelectric material region.

The aforementioned first and second elastic decoupling elements 14a, 14b have a high stiffness with respect to movements out of the horizontal plane xy (along the orthogonal axis z) and are yielding with respect to torsion (around a rotation axis parallel to the first horizontal axis x). The first and the second elastic decoupling elements 14a, 14b extend in parallel with the first horizontal axis x, between the first, respectively, the second driving arms 12a, 12b and a same facing side of the tiltable structure <NUM>.

The first and the second elastic decoupling elements 14a, 14b are coupled to the tiltable structure <NUM> at a respective coupling point Pa, Pb, which is located in proximity to the first median axis of symmetry X, at a short distance from the same first median axis of symmetry X. For example, this distance may be comprised between <NUM> and <NUM> in a typical embodiment and may also be generally comprised between <NUM>/<NUM> and <NUM>/<NUM> of the main dimension (in the example along the second median axis of symmetry Y) of the tiltable structure <NUM>.

In any case, the distance between the respective coupling point Pa, Pb and the first median axis of symmetry X is preferably smaller, in particular much smaller, than the distance between the same coupling point Pa, Pb and end or edge portions (taken along the second median axis of symmetry Y) of the tiltable structure <NUM>. In fact, the closer these coupling points Pa, Pb are to the first rotation axis, the greater the ratio between the vertical displacement of the end of the tiltable structure <NUM> and the vertical displacement of the driving arms 12a, 12b, due to the piezoelectric effect.

In the embodiment illustrated in <FIG>, the first and the second elastic decoupling elements 14a, 14b are of a folded type, that is they are formed by a plurality of arms having a longitudinal extension parallel to the first horizontal axis x, connected two by two through connecting elements having extension parallel to the second horizontal axis y (in a different embodiment, the elastic decoupling elements 14a, 14b may alternatively be of a linear type).

The aforementioned actuation structure <NUM> further comprises a second pair of driving arms formed by a third and a fourth driving arm 12c, 12d, arranged on opposite side of the first median axis of symmetry X and, this time, of the second support element 5b and having a longitudinal extension parallel to the first horizontal axis x and to the aforementioned second support element 5b (it should be noted that the second pair of driving arms 12c, 12d is therefore arranged symmetrically to the first pair of driving arms 12a, 12b with respect to the second median axis of symmetry Y).

Similarly to what has been discussed for the first pair of driving arms 12a, 12b, each driving arm 12c, 12d of the second pair carries, at a top surface thereof, a respective piezoelectric structure <NUM> (in particular including PZT - Lead Zirconate Titanate) and has a respective first end integrally coupled to the frame <NUM>' of the fixed structure <NUM> and a respective second end elastically coupled to the tiltable structure <NUM>, through a respective third and fourth elastic decoupling element 14c, 14d (arranged on opposite side of the first and second elastic decoupling elements 12a, 12b with respect to the second median axis of symmetry Y).

The aforementioned third and fourth elastic decoupling elements 14c, 14d also have a high stiffness with respect to movements out of the horizontal plane xy (along the orthogonal axis z) and are yielding with respect to torsion (around a rotation axis parallel to the first horizontal axis x).

Moreover, as illustrated in the aforementioned <FIG>, also the third and the fourth elastic decoupling elements 14c, 14d are coupled to the tiltable structure <NUM> at a respective coupling point Pc, Pd, which is located in proximity to the first rotation axis, at the short distance d from the same first rotation axis. Furthermore, the third and the fourth elastic decoupling elements 14c, 14d are also of a folded type.

The microelectromechanical device <NUM> further comprises a plurality of electrical contact pads <NUM>, carried by the fixed structure <NUM> at the frame <NUM>', electrically connected (in a manner not shown in detail in the same <FIG>) to the piezoelectric structures <NUM> of the driving arms 12a-12d through electrical connection tracks, to allow their electrical biasing through electrical signals coming from the outside of the same electromechanical device <NUM> (for example provided by a biasing device of an electronic apparatus wherein the electromechanical device <NUM> is integrated).

Furthermore, the microelectromechanical device <NUM> comprises a piezoresistive (PZR) sensor <NUM>, suitably arranged to provide a sensing signal associated with the rotation of the tiltable structure <NUM> around the first rotation axis; this sensing signal may be provided as a feedback to the outside of the microelectromechanical device <NUM>, for example to the aforementioned biasing device, through at least one of the electrical contact pads <NUM>.

In the embodiment illustrated in <FIG>, this piezoresistive sensor <NUM> is formed (for example by surface diffusion of doping atoms) at the second support element 5b (however, different arrangements may be provided for the same piezoresistive sensor <NUM>, which may for example be similarly formed at the first support element 5a).

Advantageously, the elastic suspension elements 6a, 6b are capable of transmitting the stress to the support elements 5a, 5b and therefore towards the piezoresistive sensor <NUM>, allowing its arrangement at the same support elements 5a, 5b and a resulting simplification of the routing of the electrical connections towards the electrical contact pads <NUM>.

As shown in the enlarged detail of <FIG> (corresponding to the box highlighted in <FIG>), the aforementioned piezoresistive sensor <NUM> may for example be formed by four piezoresistor elements which are arranged and connected in a Wheatstone bridge configuration, at the end of the relative support element (in the example of the second support element 5b) coupled to the relative elastic suspension element (in the example to the second elastic suspension element 6b). Four electric connection tracks 22a-22d extend from the aforementioned piezoresistor elements along the corresponding support element, to reach (in a manner not shown here) corresponding electrical contact pads <NUM>.

During operation of the microelectromechanical device <NUM>, the application of a bias voltage to the piezoelectric structure <NUM> of the first driving arm 12a (having a positive value with respect to the bias of the piezoelectric structure <NUM> of the second driving arm 12b, which may for example be connected to a ground reference potential), causes a rotation of a positive angle around the first rotation axis (parallel to the first horizontal axis x).

Correspondingly, the application of a bias voltage to the piezoelectric structure <NUM> of the second driving arm 12b (having a positive value with respect to the bias of the piezoelectric structure <NUM> of the first driving arm 12a, which may for example in this case be connected to a ground reference potential), causes a corresponding rotation of a negative angle around the same first rotation axis.

It should be noted that the same bias voltage may be applied to the piezoelectric structure <NUM> of both the first driving arm 12a and the third driving arm 12c, and, similarly, in order to cause the opposite rotation, to the piezoelectric structure <NUM> of both the second driving arm 12b and the fourth driving arm 12d, to contribute correspondingly to the rotation of the tiltable structure <NUM> around the first rotation axis (as moreover will become apparent from the previous description).

The elastic decoupling elements 14a-14d elastically decouple the displacement due to the piezoelectric effect of the driving arms 12a-12d along the orthogonal axis z from the resulting rotation of the tiltable structure <NUM> about the first rotation axis.

In particular, by virtue of the proximity to the rotation axis of the coupling points Pa-Pd between the same elastic decoupling elements 14a-14d and the tiltable structure <NUM>, a high opening angle (i.e. the rotation angle of the tiltable structure <NUM> around the first rotation axis), or, similarly, a high displacement out of the horizontal plane xy of the end portions (taken along the second horizontal axis y) of the same tiltable structure <NUM> corresponds to a reduced displacement out of the horizontal plane xy of the aforementioned driving arms 12a-12d; for example, the ratio between the extent of such displacements may be equal to five in a possible embodiment.

The tiltable structure <NUM> may thus reach high tilt angles (for example > <NUM>°) in the face of a low value of the bias voltage (for example < <NUM> V).

Furthermore, the maximum amount of stress occurs in the elastic suspension elements 6a, 6b, which couple the tiltable structure <NUM> to the fixed structure <NUM> (the arrangement of the piezoresistive sensor <NUM> at least one of the support elements 5a, 5b is therefore advantageous).

Furthermore, also by virtue of the reduced displacement in the direction of the orthogonal axis z of the driving arms 12a-12d (this displacement is reduced even by a factor of ten with respect to different prior art solutions), the microelectromechanical device <NUM> is less subject to shocks acting along the same orthogonal axis z (in other words, a same shock causes a level of stress and a displacement out of the horizontal plane xy which are much lower in the microelectromechanical device <NUM> with respect to different known solutions).

As previously indicated, there may be a need to increase the opening angle of the tiltable structure <NUM> keeping the size of the die <NUM>' of the microelectromechanical device <NUM> unaltered and not modifying the arrangement of the piezoelectric structure <NUM> (of PZT material) of the driving arms 12a-12d.

The present Applicant has therefore considered decreasing the torsional stiffness associated with the elastic suspension elements 6a, 6b, which couple the tiltable structure <NUM> to the first and the second support elements 5a, 5b, for example reducing a corresponding width (in the embodiment illustrated in <FIG>, along the second horizontal axis y).

The present Applicant has in fact realized that a reduction in torsional stiffness, for example a reduction in width associated with the aforementioned elastic suspension elements 6a, 6b (with respect to a reference value "Ref.") determines an increase in the opening angle, as indicated by way of example in the Table shown in <FIG> (where different percentage reduction values for the torsional stiffness and width are shown).

However, the same Applicant has highlighted an unwanted concurrent decrease in the detection sensitivity associated with the piezoresistive sensor <NUM> (as shown in the same Table of <FIG>), which exhibits a faster percentage reduction (Δ) with the increase of the opening angle with respect to the percentage reduction in the torsional stiffness (or width) of the aforementioned elastic suspension elements 6a, 6b.

The reduction in torsional stiffness, for example associated with a reduction in width, in fact entails a reduction of the stress, which may be transmitted by the elastic suspension elements 6a, 6b to the support elements 5a, 5b and therefore of the stress detected by the piezoresistive sensor <NUM>.

A particular aspect of the present solution therefore provides, in order to obviate this problem, an asymmetrical arrangement of the elastic suspension elements 6a, 6b, which have an asymmetrical arrangement on opposite sides of the tiltable structure <NUM> (along the first horizontal axis x).

In particular, the elastic suspension elements 6a, 6b are formed with a different torsional stiffness (having for example a different width) and the piezoresistive sensor <NUM> is formed in the proximity of the elastic suspension element having a higher torsional stiffness (with respect to the other elastic suspension element).

In detail, the elastic element associated with the support element, at which no piezoresistive sensor is formed (in the embodiment illustrated in <FIG>, the first elastic suspension element 6a associated with the first support element 5a), is formed with a first torsional stiffness, for example with a first width w1; while the elastic element associated with the support element, at which the piezoresistive sensor <NUM> is formed (in the embodiment illustrated in the same <FIG>, the second elastic suspension element 6b associated with the second support element 5b) is formed with a second torsional stiffness, in the example with a second width w2.

In particular, the aforementioned first torsional stiffness is smaller than the second torsional stiffness (and the first width w1 is smaller than the second width w2). In the embodiment illustrated in the aforementioned <FIG>, as also shown in the enlarged images of the aforementioned <FIG> and also in <FIG>, the second elastic suspension element 6b is therefore formed with the second width w2 (which may for example be equal to <NUM>); while the first elastic suspension element 6a is formed with the first width w1 (which may for example be equal to <NUM>, that is with a reduction of <NUM> with respect to the second width w2).

This asymmetrical arrangement allows, in the example, to obtain a percentage increase equal to <NUM>% of the opening angle of the tiltable structure <NUM> (which increases its value from <NUM>° to <NUM>°) with the same bias voltage applied to the piezoelectric structure <NUM> of the driving arms; at the same time, the sensitivity of the piezoresistive sensor <NUM> is kept substantially unchanged.

According to an aspect of the present solution, the differential reduction in torsional stiffness of one of the elastic suspension elements 6a, 6b with respect to the other is such that the percentage difference between the first torsional stiffness and the second torsional stiffness is comprised between <NUM>% and <NUM>%; moreover, the percentage difference between the first width w1 and the second width w2 may be comprised between <NUM>% and <NUM>%.

In particular, the present Applicant has verified the possibility of decreasing the aforementioned first width w1 even by <NUM>% with respect to the second width w2; a greater decrease, although it might potentially lead to an even greater increase in the opening angle, might in fact entail an excessive reduction in shock resistance, in particular along the orthogonal axis z and along the second horizontal axis y, due to the increased extent of movement (so-called "displacement") of the elastic suspension element having the reduced width.

In other words, the second width w2 differs from the first width w1 preferably by no more than <NUM>%, in order to avoid robustness problems for the microelectromechanical device <NUM>.

A further embodiment of the present solution provides for a particular shape of one or both of the elastic suspension elements 6a, 6b, which in this case have a substantially a "T" shape.

As illustrated in <FIG> and in <FIG>, one or both of the elastic suspension elements 6a, 6b (in the example illustrated, the first elastic suspension element 6a) in this case have: a body portion <NUM>, having a substantially linear extension, in the embodiment illustrated along the first horizontal axis x; and a head portion <NUM>, also having a substantially linear extension, in the embodiment illustrated along the second horizontal axis y, orthogonally with respect to the body portion <NUM>.

In particular, the aforementioned body and head portions <NUM>, <NUM> substantially have a same width in the direction transverse to the aforementioned linear extension, in the horizontal plane xy, corresponding to the aforementioned first or second width (what has been previously discussed on the asymmetrical arrangement of the elastic suspension elements being in fact valid also in this case). In the example shown in <FIG>, the body and head portions <NUM>, <NUM> both have substantially the same first width w1 (the corresponding first elastic suspension element 6a being associated with the first support element 5a without a piezoresistive sensor).

In greater detail, in a possible implementation, shown in <FIG>, the aforementioned head portion <NUM> is formed in the tiltable structure <NUM>, at the connecting portion with the respective elastic suspension element (in the example with the first elastic suspension element 6a); an opening <NUM> is therefore formed in this case in the aforementioned connecting portion of the tiltable structure <NUM>, having a main extension along the second horizontal axis y, so that the aforementioned head portion <NUM> is interposed between the same opening <NUM>, on one side, and the cavity <NUM>, on the other side (along the first horizontal axis x).

In a different implementation, shown in <FIG>, the aforementioned head portion <NUM> is formed instead in the associated support element (in the example, in the first support element 5a), at the connecting portion with the respective elastic suspension element (in the example with the first elastic suspension element 6a); the opening <NUM> is therefore formed in this case in the aforementioned connecting portion of the associated support element, having again a main extension along the second horizontal axis y, so that the aforementioned head portion <NUM> is interposed between the same opening <NUM>, on one side, and the cavity <NUM>, on the other side (again, along the first horizontal axis x).

It should be noted that, in this implementation, it is preferable that the piezoresistive sensor <NUM> is not formed at the support element 5a, 5b wherein the aforementioned head portion <NUM> of the elastic suspension element 6a, 6b is also formed.

The advantages of the present solution are clear from the previous description.

In any case, it is again highlighted that the solution described allows an increase in the opening angle of the microelectromechanical device <NUM> to be obtained, with minor structural changes with respect to structures of a known type and, in particular, keeping the size of the relative die <NUM>' of semiconductor material unchanged and without requiring changes in the arrangement of the piezoelectric structure <NUM> of the driving arms 12a-12d.

In general, the present solution allows to fully exploit the advantages of the piezoelectric actuation (i.e., the use of reduced bias voltages with a reduced energy consumption to obtain high displacements), while having improved mechanical and electrical performance compared to known solutions.

Advantageously, the microelectromechanical mirror device <NUM> may therefore be used in a picoprojector (or miniaturized projector) <NUM>, which is operatively coupled to a portable electronic apparatus <NUM> (for example a smartphone or augmented reality glasses), as schematically illustrated with reference to <FIG>.

In detail, the picoprojector <NUM> of <FIG> comprises a light source <NUM>, for example of a laser type, for generating a light beam <NUM>; the microelectronic device <NUM>, acting as a mirror and for receiving the light beam <NUM> and directing it towards a screen or display surface <NUM> (external and arranged at a distance from the picoprojector <NUM>); a first driving circuit <NUM>, for providing suitable control signals to the light source <NUM>, for the generation of the light beam <NUM> based on an image to be projected; a second driving circuit <NUM>, for providing driving signals to the actuation structure of the microelectronic mirror device <NUM>; and a communication interface <NUM>, for receiving, from a control unit <NUM>, which is external, for example being included in the portable apparatus <NUM>, information about the image to be generated, for example in the form of a pixel matrix. This information is sent at the input for driving the light source <NUM>.

Finally, it is clear that modifications and variations may be made to what has been described and illustrated without thereby departing from the scope of protection of the present invention, as defined in the attached claims.

In particular, the solution described may also be applied in the case of a biaxial embodiment of the microelectromechanical mirror device <NUM> (in a manner similar to what has been described in detail in the aforementioned <CIT>), that is in the case wherein the tiltable structure <NUM> is capable of performing rotation movements both around the first rotation axis (coinciding with the first median axis of symmetry X parallel to the first horizontal axis x), and around a second rotation axis (coinciding with the second median axis of symmetry Y parallel to the second horizontal axis y).

Furthermore, variations may generally be provided as regards the shape of the elements constituting the microelectromechanical mirror device <NUM>, for example different shapes of the tiltable structure <NUM> (and of the corresponding reflecting surface <NUM>'), or different shapes and/or arrangements of the driving arms 12a-12d.

Claim 1:
A microelectromechanical mirror device (<NUM>), comprising:
a fixed structure (<NUM>) defining a cavity (<NUM>);
a tiltable structure (<NUM>) carrying a reflecting surface (<NUM>'), elastically suspended above the cavity (<NUM>) and having a main extension in a horizontal plane (xy);
at least one first pair of driving arms (12a, 12b), elastically coupled to the tiltable structure (<NUM>) and carrying respective piezoelectric material regions (<NUM>) configured to be biased to cause a rotation of the tiltable structure (<NUM>) around at least one first rotation axis (X) parallel to a first horizontal axis (x) of said horizontal plane (xy);
elastic suspension elements (6a, 6b), configured to couple said tiltable structure (<NUM>) elastically to said fixed structure (<NUM>) at said first rotation axis (X), stiff with respect to movements out of the horizontal plane (xy) and yielding with respect to torsion around said first rotation axis (X), said elastic suspension elements (6a, 6b) extending between said tiltable structure (<NUM>) and said fixed structure (<NUM>); and
a piezoresistive sensor (<NUM>), configured to provide a detection signal associated with the rotation of the tiltable structure (<NUM>) around the first rotation axis (X),
wherein said elastic suspension elements (6a, 6b) comprise a first (6a) and a second (6b) elastic suspension element, coupled to said tiltable structure (<NUM>) on opposite sides along said first horizontal axis (x); wherein said first elastic suspension element (6a) is formed with a first torsional stiffness and said second elastic suspension element (6b) is formed with a second torsional stiffness,
characterised in that said second torsional stiffness is different from said first torsional stiffness;
and in that said piezoresistive sensor (<NUM>) is arranged in the proximity of the elastic suspension element, between the first and the second elastic suspension elements (6a, 6b), having a higher torsional stiffness.