Abstract: A power-supply circuit includes a transformer with primary and secondary windings, and an energy accumulator on the secondary winding. A circuit monitors the secondary winding and generates a feedback signal that is transferred by a transmission circuit through the secondary winding by selectively transferring energy from the energy accumulator. The transmission circuit includes: a) an electronic switch having a control terminal; and b) a driver circuit for driving the electronic switch. The driver circuit includes a charge-accumulation capacitor connected to the control terminal, and a charge circuit configured to draw energy from the secondary winding and charge the charge-accumulation capacitor.

Abstract: An electronic device includes: a semiconductor body; a front metallization region; a top buffer region, arranged between the front metallization region and the semiconductor body; and a conductive wire, electrically connected to the front metallization region. The top buffer region is at least partially sintered.

Abstract: An estimate of the initial position of a rotor is made by monitoring sensed motor current signals which are amplitude and phase modulated with the rotor flux position in response to a high frequency voltage signal injection. The motor current signals are envelope detected to determine zero crossing points. Samples are taken of the motor current signals at positive and negative offsets from the zero crossing point, with the samples processed to identify a direction of the rotor flux axis. Further samples of at least one motor current signal are taken with respect to a certain phase reference, and the samples compared to resolve a polarity of the rotor flux axis which is indicative of the angular position of the rotor.

Abstract: An electronic device includes at least one chip and an insulating body embedding the chip. The electronic device further includes a heat-sink in contact with the chip. The heat-sink includes a plate having a first thickness. A recess is provided in the plate that defines a central portion of the plate having a second thickness less than the first thickness. The chip is mounted to the central region of the heat-sink within the recess. The insulating body includes a surface, such as a mounting surface, including an opening exposing at least a portion of the heat-sink. The device may further include a reophore extending through a side surface of the insulating body, that reophore being in contact with the heat sink.

Abstract: An integrated electronic device includes an electronic component and a temperature transducer. The temperature transducer is electrically arranged between a control terminal and a conduction terminal of the electronic component and includes a first diode. The first diode has a bulk resistance of at least 1 k?.

Abstract: A gyroscope includes: a mass, which is movable with respect to a supporting body; a driving loop for keeping the mass in oscillation according to a driving axis; a reading device, which supplying an output signal indicating an angular speed of the body; and a compensation device, for attenuating spurious signal components in quadrature with respect to a velocity of oscillation of the mass. The reading device includes an amplifier, which supplies a transduction signal indicating a position of the mass according to a sensing axis. The compensation device forms a control loop with the amplifier, extracts from the transduction signal an error signal representing quadrature components in the transduction signal, and supplies to the amplifier a compensation signal such as to attenuate the error signal.

Abstract: A rectifier cell includes a first cell branch and a second cell branch that extend in parallel between two opposite nodes receiving an a.c. signal. The first cell branch includes a first pair of transistors arranged with their current paths cascaded, with a first intermediate point in-between. The second cell branch includes a second pair of transistors arranged with their current paths cascaded, with a second intermediate point in-between. Each of the pairs of transistors includes a first transistor with a control terminal coupled to one of the two opposite nodes and a second transistor with a control terminal coupled to the other of the two opposite nodes. The bulks of the transistors receive voltages in order to vary the transistor threshold voltage by bringing the threshold voltage to a first value during forward conduction and to a second value during reverse conduction.

Abstract: A MEMS device includes a platform carried by a frame via elastic connection elements configured to enable rotation of the platform about a first axis. A bearing structure supports the frame through first and second elastic suspension arms configured to enable rotation of the frame about a second axis transverse to the first axis. The first and second elastic suspension arms are anchored to the bearing structure through respective anchorage portions arranged offset with respect to the second axis. A stress sensor formed by first and second sensor elements respectively arranged on the first and second suspension arms is positioned in proximity of the anchorage portions, on a same side of the second axis, in a symmetrical position with respect to the first axis.

Abstract: A PWM controlled multi-phase resonant voltage converter may include a plurality of primary windings powered through respective half-bridges, and as many secondary windings connected to an output terminal of the converter and magnetically coupled to the respective primary windings. The primary or secondary windings may be connected such that a real or virtual neutral point is floating.

Abstract: A resonant converter includes a primary switching circuit with a primary winding and a primary full-bridge switching stage that drives the primary winding. A resonance inductor is in series with the primary winding. A secondary resonant circuit has a secondary winding magnetically coupled to the primary winding and a resonance capacitor electrically connected in parallel with the secondary winding. A secondary rectification stage is electrically connected in parallel to the resonance capacitor. A driving module receives a signal representing the voltage measured across an upper or lower switching half-bridge. The drive module detects a negative voltage in the signal. At each cycle, the drive module anticipates a control signal for control of the switches of the lower or upper switching half-bridge that is to be activated the next switching cycle by a shift time that is reduced cycle until the condition of absence of negative voltage in the signal is satisfied.

Abstract: A method is provided for controlling a converter of the multiphase interleaving type. According to the method, there is detected when a change of the load applied to an output terminal of the converter occurs. All the phases of the converter are simultaneously turned off, and a driving interleaving phase shift is recovered so as to restart a normal operation of the converter. A controller for carrying out such a method is also provided.

Abstract: A microfluidic device (1000-1005), comprising: a semiconductor body (2) having a first side (2a) and a second side (2b) opposite to one another, and housing, at the first side, a plurality of wells (4), having a first depth; an inlet region (30) forming an entrance point for a fluid to be supplied to the wells; a main channel (6a) fluidically connected to the inlet region, and having a second depth; and a plurality of secondary channels (6b) fluidically connecting the main channel to a respective well, and having a third depth. The first depth is higher than the second depth, which in turn is higher than the third depth.

Abstract: A control unit is for a bridge circuit. The control unit may include a signal generator configured to generate first and second periodic drive signals for the bridge circuit, and determine a switch-on duration of the first and second periodic drive signals based upon a first digital data value having a first resolution. The control unit may include a controller configured to receive a second digital data value having a second resolution. The second resolution may be greater than the first resolution. The controller may be configured to generate the first digital data value so that, over periods of the first and second periodic drive signals, the first digital data value corresponds to an average of the second digital data value.

Abstract: The integrated electronic device detects the pressure related to a force applied in a predetermined direction within a solid structure. The device includes an integrated element that is substantially orthogonal to the direction of application of the force. First and second conductive elements are configured to face an operating surface. A measure module includes first and second measurement terminals which are electrically connected to the first and second conductive elements, respectively. A detecting element is arranged in the predetermined direction such that the operating surface is sandwiched between the first and second conductive elements and this detecting element. An insulating layer galvanically insulates the first and second conductive elements.

Abstract: A power supply may include power generation circuits, each configured to drive a respective winding of a multiphase motor; converter circuits, each configured to generate a digital driving signal for a respective power generation circuit, and a memory configured to store a plurality of fast recirculation compensation values corresponding to combinations of the digital driving signals that would otherwise result in a fast recirculation condition. The power supply may also include a controller coupled to the memory and configured to determine when a given combination of the digital driving signals would otherwise result in a fast recirculation condition, and based upon the determination, substitute at least one corresponding fast recirculation compensation value for the given combination of the digital driving signals.

Abstract: An arrayed waveguide grating multiplexer/demultiplexer includes an array of optical waveguides ordered in sequence from a shortest waveguide up to a longest waveguide, and identical phase shifters configured to be controlled by a same control signal. Each phase shifter increases/decreases an optical path of an optical waveguide by the same quantity based on the control control signal.

Abstract: An electro-optic device may include a photonic chip having an optical grating at a surface, and an IC coupled to the photonic chip. The electro-optic device may include an optical element defining an optical path above the optical grating, and a dichroic mirror above the optical grating and aligned with the optical path.

Abstract: A control device for controlling a switching power supply adapted to convert an input voltage into an output voltage according to a switching rate of a switching element. The control device includes first control means for switching the switching element in a first working mode at a constant frequency and second control means for switching the switching element in a second working mode at a variable frequency, under a maximum frequency, in response to the detection of a predefined operative condition of the switching power supply. The control device further includes means for selecting the first working mode or the second working mode.

Abstract: A transmission channel transmits high-voltage pulses and receives echos of the high-voltage pulses. The transmission channel includes a current generator circuit, which generates current-integrator drive currents. The control circuitry generates one or more control signals to control generation of current-integrator drive currents by the current generator circuit during transducer-driving periods. A current integrator integrates current-integrator drive currents generated by current generator circuit to generate transducer drive signals.

Abstract: An IC may include a substrate and a layer, and an array of GMAPDs in the layer. The layer may have trenches extending between adjacent GMAPDs. The IC may include an optically reflective material within the trenches. The optically reflective material may also be electrically conductive. For example, the optically reflective material may comprise a metal. Also, the trenches may be arranged in a honeycomb pattern.