Abstract: A device for automatic detection of states of motion and rest includes at least one inertial sensor, having at least one preferential detection axis, and a converter, which is coupled to the inertial sensor and supplies a first signal correlated to forces acting on the first inertial sensor according to the preferential detection axis; the device further includes at least one processing stage for processing the first signal, which supplies a second signal correlated to a dynamic component of the first signal, and at least one threshold comparator, which supplies a pulse when the second signal exceeds a pre-determined threshold.

Abstract: A device for controlling the frequency of resonance of an oscillating micro-electromechanical system includes: a microstructure, having a first body and a second body, which is capacitively coupled to the first body and elastically oscillatable with respect thereto at a calibratable frequency of resonance, a relative displacement between the second body and the first body being detectable from outside; and an amplifier coupled to the microstructure for detecting the relative displacement. DC decoupling elements are arranged between the amplifier and the microstructure.

Abstract: An inertial sensor provided with a detection structure sensitive to a first, a second and a third component of acceleration along respective directions of detection, and generating respective electrical quantities as a function of said components of acceleration. The detection structure supplies at output a resultant electrical quantity obtained as combination of said electrical quantities, and correlated to the value of a resultant acceleration acting on the inertial sensor, given by a vector sum of the components of acceleration. In particular, the detection structure is of a microelectromechanical type, and comprises a mobile portion made of semiconductor material forming with a fixed portion a first, a second and a third detection capacitor, and an electrical-interconnection portion, connecting the detection capacitors in parallel; the resultant electrical quantity being the capacitance obtained from said connection in parallel.

Abstract: A micro-electro-mechanical sensor includes a microstructure having a mass which is movable with respect to a rest position, according to a predetermined degree of freedom, and a displacement-detecting device for detecting a displacement of the mass according to the predetermined degree of freedom. The displacement-detecting device includes a force feedback loop of a purely analog type, which supplies electrostatic forces tending to restore the mass to the rest position in response to a displacement of the mass according to the predetermined degree of freedom.

Abstract: A resonant micro-electro-mechanical system includes a microstructure having a mass which is free to oscillate in accordance with a predetermined degree of freedom, and a driving device coupled to the mass for maintaining the mass in oscillation at a resonance frequency. The driving device includes a differential sense amplifier supplying first signals indicative of a velocity of oscillation of the mass, and an actuation and control stage supplying second signals for driving the mass on the basis of the first signals. The driving device moreover includes a filtering circuit of a high-pass type, which is connected between the differential sense amplifier and the actuation and control stage, and has a bandpass that includes the resonance frequency.

Abstract: A micro-electro-mechanical sensor includes a microstructure having a mass which is movable with respect to a rest position, according to a predetermined degree of freedom, and a displacement-detecting device for detecting a displacement of the mass according to the predetermined degree of freedom. The displacement-detecting device includes a force feedback loop of a purely analog type, which supplies electrostatic forces tending to restore the mass to the rest position in response to a displacement of the mass according to the predetermined degree of freedom.

Abstract: A free-fall detector device includes an inertial sensor, a detection circuit associated to the inertial sensor, and a signal source for supplying a read signal to the inertial sensor. The device moreover includes: a storage element, selectively connectable to the detection circuit for storing a feedback signal generated by the detection circuit in response to the read signal supplied to the inertial sensor; and a feedback circuit coupled to the storage element for supplying the feedback signal to the inertial sensor so that the detection circuit generates at least one detection signal in response to the feedback signal supplied to the inertial sensor.

Abstract: A planar inertial sensor includes a first region and a second region of semiconductor material. The second region is capacitively coupled, and mobile with respect to the first region. The second region extends in a plane and has second portions, which face respective first portions of the first region. Movement of the second region, relative to the first region, in any direction belonging to the plane modifies the distance between the second portions and the first portions, which in turn modifies a value of the capacitive coupling.

Abstract: A detection circuit is provided with a differential capacitive sensor and with an interface circuit having a first sense input and a second sense input, electrically connected to the differential capacitive sensor. Provided in the interface circuit are: a sense amplifier connected at input to the first sense input and to the second sense input and supplying an output signal related to a capacitive unbalancing of the differential capacitive sensor; and a common-mode control circuit, connected to the first sense input and to the second sense input and configured to control a common-mode electrical quantity present on the first sense input and on the second sense input. The common-mode control circuit is of a totally passive type and is provided with a capacitive circuit, which is substantially identical to an equivalent electrical circuit of the differential capacitive sensor and is driven with a driving signal in phase opposition with respect to a read signal supplied to the differential capacitive sensor.

Abstract: A read device of a capacitive sensor includes: a signal source supplying an electrical read signal for driving the capacitive sensor; and a discrete-time sense circuit for generating an electrical output signal, correlated to variations of capacitance of the capacitive sensor, in response to variations of the electrical read signal. The device moreover includes: a modulator stage for generating a modulated electrical read signal on the basis of the electrical read signal and supplying the modulated electrical read signal to the capacitive sensor; a demodulator stage, connected to the sense circuit, for demodulating the electrical output signal and generating a demodulated electrical output signal; and a low-pass filtering stage for generating a filtered electrical output signal, on the basis of the modulated electrical output signal.

Abstract: An oversampling electromechanical modulator, including a micro-electromechanical sensor which has a first sensing capacitance and a second sensing capacitance and supplies an analog quantity correlated to the first sensing capacitance and to the second sensing capacitance; a converter stage, which supplies a first numeric signal and a second numeric signal that are correlated to the analog quantity; and a first feedback control circuit for controlling the micro-electromechanical sensor, which supplies an electrical actuation quantity correlated to the second numeric signal.

Abstract: An oversampling electromechanical modulator, including a micro-electromechanical sensor which has a first sensing capacitance and a second sensing capacitance and supplies an analog quantity correlated to the first sensing capacitance and to the second sensing capacitance; a converter stage, which supplies a first numeric signal and a second numeric signal that are correlated to the analog quantity; and a first feedback control circuit for controlling the micro-electromechanical sensor, which supplies an electrical actuation quantity correlated to the second numeric signal.

Abstract: A fully differential amplifier device includes a first input and a second input, a first output and a second output, and a differential input stage, provided with a first input transistor and a second input transistor. The first input and the first output and the second input and the second output are directly connected selectively in a first operating configuration and disconnected in a second operating configuration. The amplifier device further includes a current-generator circuit connected so as to supply respective first currents to the first and second outputs irrespective of a state of conduction of the first and second input transistors.

Abstract: An electronic device includes a motion sensitive power switching integrated circuit, which, in turn, includes a power switch connected between an input and an output, and a MEMS inertial sensing switch movable from a first position to a second position based upon motion thereof. The motion sensitive power switching integrated circuit also includes a detector operating the power switch to supply power to the output from the input based upon the MEMS inertial sensing switch moving from the first position to the second position. The first and second positions may be, respectively, a normally open position and a closed position. The device may be unpowered until the MEMS inertial sensing switch moves from the open to the closed position. The detector may generate a power on reset (POR) signal based upon the MEMS inertial sensing switch moving from the open to the closed position.

Abstract: A portable apparatus having an accelerometer device and a supporting element in the accelerometer device, having a first body of semiconductor material integrating a sensor element that detects movements of the first body and generates a signal correlated to the detected movement; a second body of semiconductor material that integrates a conditioning electronics and that is electrically connected to the first body; and conductive bumps that provide electrical connection of the first and second bodies to the supporting element. In particular, the conductive bumps connect the first and second bodies to the supporting element without the interposition of any packaging.

Abstract: A micro-electromechanical device includes a semiconductor body, in which at least one first microstructure and one second microstructure of reference are integrated. The first microstructure and the second microstructure are arranged in the body so as to undergo equal strains as a result of thermal expansions of the body. Furthermore, the first microstructure is provided with movable parts and fixed parts with respect to the body, while the second microstructure has a shape that is substantially symmetrical to the first microstructure but is fixed with respect to the body. By subtracting the changes in electrical characteristics of the second microstructure from those of the first, variations in electrical characteristics of the first microstructure caused by thermal expansion can be compensated for.

Abstract: A resonant micro-electro-mechanical system includes a microstructure having a mass which is free to oscillate in accordance with a predetermined degree of freedom, and a driving device coupled to the mass for maintaining the mass in oscillation at a resonance frequency. The driving device includes a differential sense amplifier supplying first signals indicative of a velocity of oscillation of the mass, and an actuation and control stage supplying second signals for driving the mass on the basis of the first signals. The driving device moreover includes a filtering circuit of a high-pass type, which is connected between the differential sense amplifier and the actuation and control stage, and has a bandpass that includes the resonance frequency.

Abstract: A micro-electro-mechanical sensor includes a microstructure having a mass which is movable with respect to a rest position, according to a predetermined degree of freedom, and a displacement-detecting device for detecting a displacement of the mass according to the predetermined degree of freedom. The displacement-detecting device includes a force feedback loop of a purely analog type, which supplies electrostatic forces tending to restore the mass to the rest position in response to a displacement of the mass according to the predetermined degree of freedom.

Abstract: A planar inertial sensor includes a first region and a second region of semiconductor material. The second region is capacitively coupled, and mobile with respect to the first region. The second region extends in a plane and has second portions, which face respective first portions of the first region. Movement of the second region, relative to the first region, in any direction belonging to the plane modifies the distance between the second portions and the first portions, which in turn modifies a value of the capacitive coupling.

Abstract: Method for detecting movements through a micro-electric-mechanical sensor, having a fixed body and a moving mass, forming at least one first and one second detection capacitor, connected to a common node and to a first, respectively a second detection node and having a common detection capacitance at rest and a capacitive unbalance in case of a movement. The method includes the steps of: feeding the common node with a constant detection voltage of predetermined duration; generating a feedback voltage to maintain the first and the second detection node at a constant common mode voltage; generating a compensation electric quantity, inversely proportional to the common detection capacitance at least in one predetermined range; supplying the compensating electric quantity to the common node; and detecting an output quantity related to the capacitive unbalance.