Abstract: Various embodiments of the invention allow to reduce unwanted high-Q oscillations in capacitive MEMS sensors. In certain embodiments, stabilization of high-Q MEMS sensors is accomplished through a dedicated ultra-low power circuit that provides a bias voltage to one or more sensor electrodes during an OFF-phase. The bias voltage forces a balance condition that eliminates perturbations and enables smooth transitions that, ultimately, result in shorter sensor settling times.

Abstract: A transducer converts energy coming from an energy source into an electrical signal for storage as electrical energy on a first storage element. A switch is selectively actuated to pass electrical energy from the first storage element to a second storage element. The selective actuation of the switch is driven by sensing electrical energy stored in the second storage element. The switch is closed when electrical energy in the second storage element is sensed to fall below a first threshold. The switch is opened when electrical energy in the second storage element is sensed to rise above a second threshold.

Abstract: A rectifier circuit includes a first, second, third and fourth parasitic diodes electrically connected to form a full-wave diode-bridge rectifier. A first switch and a second switch are connected in parallel, respectively, to the first and second parasitic diodes, and a third switch and a fourth switch connected in parallel, respectively, to the third and fourth parasitic diodes. A first biasing network is configured to drive in conduction the first and second switches, during turning-on of the rectifier circuit, using a first turning-on signal that is a function of the input signal. A second biasing network is configured to close the third and fourth switches, during turning-on of the rectifier circuit, using a second turning-on signal that is a function of the input signal.

Abstract: Various embodiments of the invention allow for low-noise, high performance input common mode voltage control in capacitive sensor front end amplifiers. In certain embodiments overcome the shortcomings of the prior art by implementing a full voltage swing common mode voltage comparator in a parallel feed-forward path to compensate large common mode input signal variations.

Abstract: The input terminals of an energy-scavenging interface are connectable to a transducer including a storage element, and output terminals of the interface are connectable to an electrical load. The interface includes a first switch that is closed to pass current and store electrical energy in the storage element for a first time interval. The first time interval is based on at least one of a first delay proportional to a time constant of the transducer and sensed current flowing through the first switch reaching a first threshold. The first switch is thereafter opened so to permit the stored electrical energy to be delivered through a first current-conduction element for a second time interval. The second time interval is based on sensed current flowing through the first current-conduction element reaching a second threshold. The first current-conduction element may comprise a second switch actuate out of phase with the first switch.

Abstract: A transducer converts energy coming from an energy source into an electrical signal for storage as electrical energy on a first storage element. A switch is selectively actuated to pass electrical energy from the first storage element to a second storage element. The selective actuation of the switch is driven by sensing electrical energy stored in the second storage element. The switch is closed when electrical energy in the second storage element is sensed to fall below a first threshold. The switch is opened when electrical energy in the second storage element is sensed to rise above a second threshold.

Abstract: A rectifier circuit includes a first, second, third and fourth parasitic diodes electrically connected to form a full-wave diode-bridge rectifier. A first switch and a second switch are connected in parallel, respectively, to the first and second parasitic diodes, and a third switch and a fourth switch connected in parallel, respectively, to the third and fourth parasitic diodes. A first biasing network is configured to drive in conduction the first and second switches, during turning-on of the rectifier circuit, using a first turning-on signal that is a function of the input signal. A second biasing network is configured to close the third and fourth switches, during turning-on of the rectifier circuit, using a second turning-on signal that is a function of the input signal.

Abstract: A DC-DC converter independently supplies electrical loads. The converter includes a charge switch and a discharge switch connected between an input supply and a reference. An inductor has a first terminal connected between the charge switch and the discharge switch and a second terminal. Coupling switches are provided between the inductor second terminal and the electrical loads. An adaptive-control circuit acquires, during supply of each electrical load, a signal indicating the voltage value across the inductor and generates a first time interval as a function of the signal indicating the voltage value detected. Each electrical load is supplied during the first time interval, and completely discharged during a second time interval subsequent to the first time interval.