Abstract: A circuit for generating a bandgap voltage includes a circuit module for generation of a base-emitter voltage difference comprising a pair of PNP bipolar substrate transistors which identify a first current path and a second current path. A first current mirror of an n type is connected between the first and second branches and is further connected via a resistance for adjustment of the bandgap voltage to the second bipolar transistor. A second current mirror of a p type is connected between the first and second branches, and connected so that the current mirrors repeat current of each other. In operation to generate the bandgap voltage, current flows from the supply voltage to ground only through said the first and second bipolar substrate transistors.

Abstract: A process for manufacturing a membrane of nozzles of a spray device, comprising the steps of laying a substrate, forming a membrane layer on the substrate, forming a plurality of nozzles in the membrane layer, forming a plurality of supply channels in the substrate, each supply channel being substantially aligned in a vertical direction to a respective nozzle of the plurality of nozzles and in direct communication with the respective nozzle.

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 SIM module includes a SIM and a plastic support on which the SIM is attached. A discontinuity channel between the plastic support and the SIM is formed all around the SIM, the discontinuity channel being interrupted in at least two points of the plastic support attaching the SIM to the plastic support. The points are on a short side and on a long side of the SIM.

Abstract: An energy harvesting interface receives an electrical signal from an inductive transducer and outputs a supply signal. An input branch includes a first switch and a second switch connected in series between a first input terminal and an output terminal, and further a third switch and a fourth switch connected in series between a second input terminal and the output terminal. A first electrical-signal-detecting device coupled across the second switch detects a first threshold value of an electric storage current in the inductor of the transducer. A second electrical-signal-detecting device coupled across the fourth switch detects whether the electric supply current that flows through the fourth switch reaches a second threshold value lower than the first threshold value.

Abstract: An integrated circuit on a substrate includes a peripheral portion that surrounds an active area and is positioned close to a scribe line providing separation with other integrated circuits realized on a same wafer. The integrated circuit includes at least one conductive structure that extends in the peripheral portion on different planes of metallizations starting from the substrate and forms an integrated antenna. Magnetic trench structures are provided adjacent the integrated antenna.

Abstract: An amplifier circuit may include an input amplification stage comprising a first amplifier having first and second differential inputs and a first output, and a second amplifier having first and second differential inputs and a second output. The amplifier circuit also includes an output amplification stage having first and second inputs respectively coupled to the first and second outputs of the input amplification stage, and an output configured to supply an output voltage based upon the input voltage by an amplification factor. The amplifier circuit comprises a feedback stage with a common-mode control stage configured to implement a comparison between the first differential voltage and the second differential voltage, and a reference voltage, and generate respective regulation currents on the first and second inputs of the output amplification stage to compensate for a common-mode variation of the first differential voltage and the second differential voltage.

Abstract: A depth map is generated from at least a first and a second image. A plurality of reference pixels are selected in the first image. A cost function is used to associate each reference pixel with a respective pixel in the second image. A masking operation is used to identify a subset of pixels in a block of pixels surrounding a reference pixel and the cost function is based on the identified subset of pixels. A disparity between each reference pixel and the respective pixel in said second image is determined, and a depth value is determined for each reference pixel as a function of the respective disparity. A depth map is generated based on the determined depth values.

Abstract: An electronic semiconductor device including a semiconductor body having a first structural region and a second structural region, which extends on the first structural region and houses a drain region; a body region, which extends into the second structural region; a source region, which extends into the body region; and a gate electrode, which extends over the semiconductor body for generating a conductive channel between the source region and the drain region. The device includes a first conductive trench extending through, and electrically insulated from, the second structural region on one side of the gate electrode; and a second conductive trench extending through the source region, the body region, and right through the second structural region on an opposite side of the gate electrode, electrically insulated from the second structural region and electrically coupled to the body region and to the source region.

Abstract: A method of performing a cryptographic operation including: receiving a plurality of binary input values; splitting the binary input values into a plurality of non-binary digits of base r, where r is an integer greater than 2 and not equal to a power of 2; and performing, by a cryptographic block on each of the plurality of non-binary digits, a different modulo r operation to generate at least one output digit) of base r.

Abstract: An electronic device is integrated on a chip of semiconductor material having a main surface and a substrate region with a first type of conductivity. The electronic device has a vertical MOS transistor, formed in an active area having a body region with a second conductivity type.

Abstract: A system for correction of the phase error in in-phase and quadrature signals may include a first signal and a second signal. The system includes a first circuit and a second circuit, each circuit configured for receiving a square-wave input signal and supplying a respective square-wave output signal. The output signal is delayed with respect to the input signal and each circuit is configured in such a way that the propagation delay of a rising edge and the propagation delay of a falling edge between the input signal and the output signal are configurable. The first circuit is configured for receiving the first signal, and the second circuit is configured for receiving the second signal.

Abstract: A manufacturing method of an electrochemical sensor comprises forming a graphene layer on a donor substrate, laminating a film of dry photoresist on the graphene layer, removing the donor substrate to obtain an intermediate structure comprising the film of dry photoresist and the graphene layer, and laminating the intermediate structure onto a final substrate with the graphene layer in electrical contact with first and second electrodes positioned on the final substrate. The film of dry photoresist is then patterned to form a microfluidic structure on the graphene layer and an additional dry photoresist layer is laminated over the structure. In one type of sensor manufactured by this process, the graphene layer acts as a channel region of a field-effect transistor, whose conductive properties vary according to characteristics of an analyte introduced into the microfluidic structure.

Abstract: An electronic device includes an output terminal, an output transistor having a control terminal and a conduction terminal coupled to the output terminal, and a resistor-capacitor (RC) compensation network configured to act on the control terminal of the output transistor. In addition, the electronic device includes a transconductance amplifier configured to drive the output terminal through the control terminal of the output transistor, and a Miller effect stage coupled to the RC compensation network and having an input port coupled to the transconductance amplifier and an output port coupled to the control terminal of the output transistor.

Abstract: An integrated microelectromechanical structure is provided with: a die, having a substrate and a frame, defining inside it a detection region and having a first side extending along a first axis; a driving mass, anchored to the substrate, set in the detection region, and designed to be rotated in a plane with a movement of actuation about a vertical axis; and a first pair and a second pair of first sensing masses, suspended inside the driving mass via elastic supporting elements so as to be fixed with respect thereto in the movement of actuation and so as to perform a detection movement of rotation out of the plane in response to a first angular velocity; wherein the first sensing masses of the first pair and the first sensing masses of the second pair are aligned in respective directions, having non-zero inclinations of opposite sign with respect to the first axis.

Abstract: A communication system is arranged to interface a plurality of transmission circuits with an interconnection network. Each transmission circuit generates read requests and/or write requests. The communication system includes a first circuit that operates independently of the communication protocol of the interconnection network. In particular, the first circuit includes, a) for each transmission circuit a communication interface configured for receiving the read requests and/or write requests from the respective transmission circuit, b) a segmentation circuit configured for dividing, i.e., segmenting, the read requests and/or write requests received from the transmission circuits into transfer segments, and c) an interleaving circuit configured for generating, via an operation of interleaving of the transfer segments, a series of segments.

Abstract: Embodiments disclose herein are directed to a microfluidic delivery device that has a predominantly semiconductor structure, such as silicon. In particular, the structure for delivering fluid may be formed from polycrystalline silicon, also called polysilicon, or epitaxial silicon. The microfluidic delivery device that predominantly uses silicon based materials to form the structures that are in contact with the dispensed fluid results in a device that is compatible with a wide set of fluids and applications.

Abstract: A control apparatus of an engine ignition spark plug includes a switch having a control terminal and an output terminal connected to an external transformer. The switch assumes a closed state for supplying energy to the transformer, and an open state for the transformer to supply energy to the spark plug. A measuring module measures a time duration where, in the open state, a voltage at the output terminal of the switch decreases from a first value to a second value. A detecting module detects an operating condition of the spark plug based on comparing the measured time duration to a time threshold, and to generate a detecting signal based on the comparing.

Abstract: An AC/DC converter includes a first terminal and a second terminal to receive an AC voltage and a third terminal and a fourth terminal to deliver a DC voltage. A rectifying bridge is provided in the converter. A controllable switching or rectifying element has a control terminal configured to receive a control current. A first switch is coupled between a supply voltage and the control terminal to inject the control current. A second switch is coupled between the control terminal and a reference voltage to extract the control current. The first and second switches are selectively actuated by a control circuit.

Abstract: Described herein is a modular system for a system for electrically stimulating a biological tissue, which includes: a first device (32) including a number of electrodes (45), which in use contact the biological tissue; and a second device (34) including an electronic control circuit (55), which transmits stimulation signals. The second device may be operatively coupled in a releasable way to the first device, in such a way that the first device receives the stimulation signals transmitted by the second device.