Abstract: The Dual frequency HF-UHF identification device comprises a RFID integrated circuit with a power supply having a HF part, formed by a HF rectifier connected to a HF antenna, and a UHF part formed by a UHF rectifier connected to a UHF antenna. The RFID integrated circuit comprises a storage capacitor common to the HF and UHF parts of the power supply. The HF rectifier output and the UHF rectifier output are both continuously connected to the supply terminal of the common storage capacitor. Further, the supply terminal of the common storage capacitor is connected, on the one hand, to the output of the HF rectifier through a diode arranged so as to block a current from said supply terminal to the HF rectifier output and, on the other hand, directly to the output of the UHF rectifier formed by a charge pump.

Abstract: An electronic measuring device for measuring a physical parameter includes a differential analogue sensor formed from two capacitances—an excitation circuit of the differential analogue sensor providing to the sensor two electrical excitation signals which are inverted—a measuring circuit which generates an analogue electrical voltage which is a function determined from the value of the sensor, and a circuit for compensating for a possible offset of the sensor, which is formed from a compensation capacitance, which is excited by its own electrical excitation signal. The excitation circuit is arranged in order to be able to provide to an additional capacitance of the compensation circuit its own electrical excitation signal having a linear dependence on the absolute temperature with a determined proportionality factor in order to compensate for a drift in temperature of an electrical assembly of the measuring device comprising at least the compensation capacitance.

Abstract: The integrated circuit connection device (1) enables an external component to be connected. The integrated circuit is powered by a supply voltage (VDD) and part of the circuit operates using at least one internal regulated voltage (VREG). The connection device includes two active transistors (N1, P1) of different conductivity connected in series between the supply voltage (VDD) and earth (VSS). The drains of these two active transistors (N1, P1) are connected to each other so as to form an external contact pad (2). The gates of these active transistors are controlled by voltage signals that have the same amplitude (Vesd). The connection device further includes switching means (3) for modifying the control signals (Vesd) applied across the active transistor gates, without exceeding the highest voltage between the supply voltage (VDD) and the internal regulated voltage (VREG).

Abstract: The measuring device determines the luminous intensity received by a photovoltaic cell electrically connected at output to an electrical energy storage unit via a DC-DC converter and to an external capacitor arranged in parallel to the DC-DC converter. It includes: a variable resistor arranged between an input terminal and an earth terminal; a control unit arranged to vary the value of the variable resistor within a plurality of determined resistance values; a discharge unit for the external capacitor controlled by the control unit so as to discharge said external capacitor to a reference voltage; and a photovoltaic cell voltage change detector which is arranged to be capable of determining, when a measurement is made, whether the voltage at said input terminal increases or decreases between two instants separated by a given time interval.

Abstract: A method for providing identification and access with respect to a passive radio-frequency tag in a tag population, the passive tag receiving ACK commands includes an identification parameter in the form of a 16-bit number. The method includes a step of receiving a command for initiating an inventory round or a command for initiating a tag access, generating a 16-bit value referred to as first or second binding handle, backscattering the first or second binding handle, receiving an ACK command, and analyzing the identification parameter of the ACK command, and in a case where the identification parameter includes the reader identifier then ignoring the ACK command.

Abstract: An electronic system is provided, including an integrated circuit die having at least 2 bond pads, and a redistribution layer having at least one solder pad including 2 portions separated from each other and configured to provide an electrical connection between each of the 2 portions by a solder ball disposed on the solder pad, and to electrically isolate the 2 portions in an absence of the solder ball on the solder pad, and at least 2 redistribution wires, each connecting a different one of the portions to a different one of the bond pads, a second bond pad being connected via a second redistribution wire to a second portion being dedicated to die testing; and a grounded printed circuit board track, wherein the solder ball is disposed between the solder pad and the track, and neither of the redistribution wires traverses a separation space between the 2 portions.

Abstract: The present invention relates to an interface circuit for a capacitive accelerometer sensor for measuring an acceleration value sensed by the sensor. The interface circuit comprises a plurality of electrical switches and three programmable capacitors. Two of the programmable capacitors are arranged to implement gain trimming of the interface circuit, while one of the programmable capacitors is arranged to implement acceleration range selection.

Abstract: An electronic device including: a calculation unit configured to generate a signal representative of a physical magnitude, for a motor driving a display device, the motor including two terminals, one positive and one negative, via which the calculation unit controls the motor; at least one shock detection circuit connected between the calculation unit and one terminal of the motor for detection of an external shock applied to the motor. The shock detection circuit includes a comparison part comparing an induced voltage generated in the motor following a shock to a predetermined reference voltage to identify a shock, and a selection part.

Abstract: The self-polarised quartz oscillator circuit comprises an amplifier with an output which is connected to a first electrode of the quartz and an input which is connected to a second electrode of the quartz, an output capacitor which is connected to the first electrode of the quartz and an input capacitor which is connected to the second electrode of the quartz. The amplifier is polarised by a current through a MOS polarisation transistor, which is generated in an amplitude regulation assembly which comprises also an amplitude regulation stage. The second electrode of the quartz is connected to the gate of the polarisation transistor and to the amplitude regulation stage in order to modulate the polarisation current and to regulate the oscillation amplitude of the quartz.

Abstract: A voltage regulator for driving a digital circuit includes an input terminal and an output terminal, a pass device and a first capacitor, and a boost circuit connected to the pass device or to the first capacitor and having a regulator boost input terminal connectable to the boost signal output terminal. The output terminal is connectable to a power terminal of a digital or switching circuit having at least a boost signal output terminal. The boost circuit includes a boost capacitor and a switching arrangement connected to the regulator boost input terminal and connected to the boost capacitor. The switching arrangement is controllable by a boost signal generated by the digital or switching circuit.

Abstract: An integrated circuit die having at least two bond pads, a redistribution layer, the redistribution layer including at least one solder pad including comprising two portions arranged to enable an electrical connection between each other by a same solder ball placed on the solder pad, but electrically isolated of each other in the absence of a solder ball on the solder pad at least two redistribution wires, each one connecting one of the two portions to one of the two bond pads, a first bond pad connected via a first redistribution wire to a first portion of the solder pad being dedicated to digital ground and a second bond pad connected via a second redistribution wire to a second portion of the solder pad being dedicated to analog ground.

Abstract: A voltage regulator for driving a digital circuit includes an input terminal and an output terminal, a pass device and a first capacitor, and a boost circuit connected to the pass device or to the first capacitor and having a regulator boost input terminal connectable to the boost signal output terminal. The output terminal is connectable to a power terminal of a digital or switching circuit having at least a boost signal output terminal. The boost circuit includes a boost capacitor and a switching arrangement connected to the regulator boost input terminal and connected to the boost capacitor. The switching arrangement is controllable by a boost signal generated by the digital or switching circuit.

Abstract: The present invention concerns an electronic oscillator comprising: an LC resonant circuit comprising an inductive component and a capacitive component, the LC resonant circuit being connected to a first reference voltage node and to an oscillator output node; a first transistor connected to the oscillator output node and arranged to periodically operate in a conducting state and a non-conducting state; and a phase shift circuit. A phase shift circuit output is connected to the first transistor, while a phase shift circuit input is connected by a first feedback circuit to the oscillator output node. The phase shift circuit comprises a signal phase shifter for shifting the phase of a first feedback signal from the first feedback circuit by substantially 180 degrees.

Abstract: The present invention relates in one aspect to a voltage regulation circuit for an RFID circuit (10), the voltage regulation circuit comprising: an input (20) connectable to a rectifier circuit (14), an output (22) connectable to a processor (18) of the RFID circuit, at least one switch (24) arranged between the input (20) and the output (22) and connected to the input (20) and the output (22), wherein the switch (24) is capable to electrically connect the output (22) to the input (20) and to disconnect the output (22) from the input (20).

Abstract: A method for providing identification and access with respect to a passive radio-frequency tag in a tag population, the passive tag being configured for receiving ACK commands including an identification parameter, the method including receiving an initiating command for identifying and accessing a tag, the initiating command including a slot number having a first value if a value in a slot counter of the tag is equal to the first value, then transitioning to an Open or a Secured state, otherwise transitioning to an Arbitrate state in a case where the tag has transitioned to the Arbitrate state, receiving a command for repeating a tag access request, referred to as repetition command, the command including a slot number having a second value, different from the first value, the second value being equal to the value in the slot counter of the tag, transitioning to the Open or Secured state, receiving an ACK command, ignoring the ACK command.

Abstract: The present invention concerns a capacitive accelerometer for measuring an acceleration value. The accelerometer comprises: a first electrode; a second electrode; a third, mobile electrode arranged between the first and second electrodes, and forming with the first electrode a first capacitor with a first capacitance value, and with the second electrode a second capacitor with a second capacitance value, the third electrode being arranged to be displaced when the capacitive accelerometer is subject to acceleration thereby arranged to generate a capacitance difference value between the first and second capacitances transformable to electrical charges; a first voltage source and a second voltage source for selectively applying a first voltage value to the first electrode, a second voltage value to the second electrode and a third voltage value to the third electrode, and arranged to generate electrostatic forces acting on the third electrode.

Abstract: A receiver unit for a radio frequency (RF) tag is provided, including a first input terminal and a second input terminal each being connected to an antenna; a communication stage configured to demodulate and/or to modulate an incoming signal in the communication stage; and a power stage including a voltage converter circuit being configured to supply power to the receiver unit, and a regulation circuit being configured to limit an output voltage of the voltage converter circuit, wherein the regulation circuit includes a regulator circuit being configured to determine a first current value and a second current value, the second current value being a current value provided in addition to the first current value, and, if the second current value exceeds a predetermined threshold value, to supply a control signal to a limiter circuit configured to limit an input voltage of the voltage converter circuit.

Abstract: A humidity sensor is provided, including a silicon base plate on which several intermetallic dielectric layers, each of which is provided with a metallic zone, and a metal layer are disposed, wherein the metal layer is etched to form two electrodes, each including an armature provided with a plurality of arms, wherein each armature is mounted so that the arms are interlaced to have arms positioned to face one another. The sensor also includes a temperature module or a heating module.

Abstract: A method for transmitting a beacon message, the method generating, with a beacon generating device at least one beacon message, wherein the at least one beacon message is defined by a beacon message format, wherein the beacon message format comprises a preamble field, an access address field, a protocol data unit (PDU) field and a cyclic redundancy check (CRC) field, wherein the PDU field comprises at least one electronic product code (EPC) encoded EPC-PDU field, and transmitting, with the beacon generating device, the at least one beacon message using a Bluetooth Low Energy (BLE) wireless communication protocol to a transmission area within a transmission range of the beacon generating device for reception by one or more beacon receiving devices located in the transmission area.

Abstract: The invention relates to an electronic system comprising: an integrated circuit die having: at least 2 bond pads a redistribution layer, said redistribution layer having: at least a solder pad comprising 2 portions arranged to enable an electrical connection between each other by a same solder ball placed on said solder pad, but electrically isolated of each other in the absence of a solder ball on the solder pad at least 2 redistribution wires, each one connecting one of the 2 portions to one of the 2 bond pads, a second bond pad connected via a second redistribution wire to a second portion of the solder pad being dedicated to testing said integrated circuit die a grounded printed circuit board track, a solder ball being placed between the solder pad and the printed circuit board track.