Abstract: A reception device comprising: at least one receiver and a corresponding delay buffer configured to receive portions of data for at least one data stream; wherein based on a request to switch from decoding delayed data portions retrieved from a host device from a first time point to decoding delayed data portions from a different, second time point, the request received while the controller is configured to receive the delayed data portion from said first time point for decoding; the controller is configured to; (a) identify one or more second-time-point delayed data portions to request from the host device; (b) request the one or more identified second-time-point delayed data portions; and (c) while one or both of requesting and receiving the one or more second-time-point delayed data portions, requesting one or more delayed data portions corresponding to the first time.

Abstract: Embodiments of an electrostatic discharge (ESD) protection device and a method of operating an ESD protection device are described. In one embodiment, an ESD protection device includes a bipolar transistor device connected between a first node and a second node, a series protection device connected in series with the bipolar transistor device, and a diode device connected between the second node and a third node. A drain terminal of an NMOS device to be protected is connectable to the first node. A body of the NMOS device to be protected is connectable to the second node. A source terminal of the NMOS device to be protected is connectable to the third node. The diode device and the bipolar transistor device are configured to form a parasitic silicon controlled rectifier. Other embodiments are also described.

Abstract: An environmental parameter sensor for a mobile device is described comprising a first acoustic transducer; a second acoustic transducer arranged at a predetermined distance from the first acoustic transducer; a controller coupled to the first acoustic transducer and the second acoustic transducer; wherein the controller is configured to determine at least one of a time-of-flight value and an attenuation value of an acoustic signal between the first acoustic transducer and the second acoustic transducer and to determine at least one environmental parameter from the at least one of the time-of-flight value and the attenuation value The environmental parameter sensor may determine environmental parameters such as temperature, wind speed, and humidity from acoustic measurements.

Abstract: The disclosure relates to a dual-interface integrated circuit (IC) card.

Abstract: The present application relates to an adaptive filter using resource sharing and a method of operating the adaptive filter. The filter comprises at least one computational block, a monitoring block and an offset calculation block. The computational block is configured for adjusting a filter coefficient, ci(n), in an iterative procedure according to an adaptive convergence algorithm. The monitoring block is configured for monitoring the development of the determined filter coefficient, ci(n), during the performing of the iterative procedure. The offset calculation block is configured for determining an offset, Offi, based on a monitored change of the filter coefficient, ci(n), each first time period, T1, and for outputting the determined offset, Offi, to the computational block if the determined filter coefficient, ci(n), has not reached the steady state. The computational block is configured to accept the determined offset, Offi, and to inject the determined offset, Offi, into the iterative procedure.

Abstract: A control arrangement is disclosed for a switch mode power supply (SMPS), the SMPS comprising an opto-coupler configured to transfer, from a secondary side to a primary side of the switch mode power supply by means of an LED current, a control signal indicative of an error between an amplifier-reference-signal and an amplifier-sensed-signal indicative of an actual value of an output parameter, the control arrangement comprising: an error amplifier configured to integrate the error to determine the LED current; and a feedback loop configured to adjust the magnitude of the LED current by modifying the amplifier-reference-signal or the amplifier-sensed-signal in order to reduce the error. A SMPS comprising such a control arrangement, and a corresponding method is also disclosed.

Abstract: A switch mode power supply is described including a primary side for coupling to a mains supply and a secondary side for coupling to a device, an isolation transformer comprising a primary coil and a secondary coil and arranged to isolate the primary side from the secondary side, and a noise filter coupled between a primary ground at the primary side and a secondary ground at the secondary side, the noise filter having a conductance value that varies with frequency. The noise filter conductance comprises a peak conductance in a peak conductance frequency region. The noise filter is operable to reduce the common-mode noise of the switch mode power supply at frequencies occurring in the peak conductance frequency region.

Abstract: An amplifier circuit comprising: a delta-PWM-modulator, a three-level-DAC, a loop-integrator, and a comparator. The delta-PWM-modulator receives a digital-input-signal; and processes the digital-input-signal and a modulator-triangular-signal to generate a delta-pulse-width-modulation-signal. The delta-pulse-width-modulation-signal is representative of the difference between a square-wave-carrier-signal and a digital-pulse-width-modulation of the digital-input-signal. The three-level-DAC receives the delta-pulse-width-modulation-signal from the delta-PWM-modulator and provides a three-level-analog-signal. The loop-integrator comprises: a virtual-ground-node-terminal configured to receive: (i) the three-level-analog-signal from the three-level DAC; and (ii) a feedback-signal from an output stage of the amplifier circuit via a feedback loop; and an integrator-output-terminal configured to provide a loop-integrator-output-signal.

Abstract: Embodiments of an electrostatic discharge (ESD) protection device and a method of operating an ESD protection device are described. In one embodiment, an ESD protection device includes an NMOS transistor configured to shunt current in response to an ESD pulse and a bigFET connected in parallel with the NMOS transistor. The NMOS transistor includes a source terminal, a gate terminal, and a body. The gate terminal and the body of the NMOS transistor are connected to the source terminal via a resistor. Other embodiments are also described.

Abstract: A power supply ready indicator circuit is described. The power supply ready indicator circuit includes a first power-supply-ready-input interfacing with a first power supply rail; a second power-supply-ready-input interfacing with a second power supply rail; and a power ready indicator output. The power supply ready indicator circuit is configured to divide the voltage on the first power supply rail, and to compare the divided voltage with the second power supply rail voltage. The power supply ready indicator circuit generates a power ready signal on the power ready indicator output in response to the divided voltage value being greater than the second power supply rail voltage value. The final value of the first power supply rail voltage is greater than the final value of the second power supply rail voltage.

Abstract: A universal serial bus (USB) link bridge device is disclosed. The USB link bridge device includes a host side module configured to be interfaced with a USB host. The host side module includes a receiver and is configured to receive serial data from the USB host, convert the received serial data into parallel data and store the parallel data into an elasticity buffer. A data controller coupled to the host side module is also included. The USB link bridge device further includes a device side module coupled to the data controller and includes a transmitter. The device side module is configured to receive parallel data from the data controller and convert the received parallel data into serial data and to transmit the serial data towards a USB device.

Abstract: An integrated circuit comprising a transceiver including a transformer. The transformer includes an input coupled to one or more primary windings. The transformer also includes a first differential output coupled to a first set of one or more secondary windings. The transformer further includes a second differential output coupled to a second, different set of one or more secondary windings. A method of making an integrated circuit comprising a transceiver. The method includes forming a plurality of components on and/or in a semiconductor substrate. At least one of the components comprises a transformer. The method includes forming the transformer by forming one or more primary windings coupled to an input, forming a first set of one or more secondary windings coupled to a first differential output, and forming a second, different set of one or more secondary windings coupled to a second differential output.

Abstract: There is disclosed a method for managing content, including generating, by a service provider, an authenticable management script configured to manage content comprised in a secure element; providing, by the service provider, the authenticable management script to the secure element. Furthermore, there is disclosed a method for managing content, comprising: receiving, by a secure element, an authenticable management script for managing content comprised in the secure element; authenticating, by the secure element, the authenticable management script; executing, by the secure element, the management script if the management script is authentic. Furthermore, there are disclosed corresponding computer program products and a corresponding secure element.

Abstract: A near field communication (NFC) device capable of operating by being powered by the field includes an NFC module for generating an electromagnetic carrier signal and modulating the carrier signal, and an antenna circuit coupled to and driven by said NFC module with the modulated carrier signal. A differential power combiner circuit is coupled to said NFC module via output terminals of said NFC module. A powered by the field circuit of the NFC device is adapted to harvest energy from an external field to power said NFC device. The power by the field circuit has a first terminal coupled to an output of said differential power combiner circuit via a first impedance block and a second terminal coupled to an input of said antenna circuit via a second impedance block. The NFC device is adapted to be able to operate in a powered by the field card mode.

Abstract: The present application relates to a reconfigurable analog front-end circuit and a reconfigurable Ethernet transceiver with a reconfigurable analog front-end circuit. The circuit is reconfigurable using the at least one signal-path switching element controlled by a mode signal to operationally establish a first or a second signal path. The first signal path comprises an optional first signal-conditioning section and a shared ADC. The second signal path comprises an optional second signal-conditioning section, an upstream ADC and the shared ADC. The signal paths are selectively switched in response to a mode signal.

Abstract: Embodiments of a device and method are disclosed. A controller area network (CAN) device includes a compare module configured to interface with a CAN transceiver, the compare module having a receive data (RXD) interface configured to receive data from the CAN transceiver, a CAN decoder configured to decode an identifier of a CAN message received from the RXD interface, and an identifier memory configured to store an entry that corresponds to at least one identifier, and compare logic configured to compare a received identifier from a CAN message to the entry that is stored in the identifier memory and to output a match signal when the comparison indicates that the received identifier of the CAN message matches the entry that is stored at the CAN device. The CAN device also includes a signal generator configured to output, in response to the match signal, a signal to invalidate the CAN message.

Abstract: A system includes a secure processor and an unsecure processor. The secure processor is configured to: split a secure scalar K into m2 random values ki, where i is an integer index; randomly select m1-m2 values ki for the indices m2<i?m1; select m1 mask values ?i; compute m1 residues ci based upon random residues ai, ??(i)?1, and k?(i), wherein ?(i) is a random permutation; compute m1 elliptic curve points Gi based upon random residues ai and an elliptic point to be multiplied; receive m1 elliptic curve points; and compute the elliptic curve scalar multiplication by combining a portion of the received elliptic curve points and removing the mask values ?i from the portion of the received elliptic curve points. The unsecure processor is configured to: receive m1 residues ci and elliptic curve points Gi; compute m1 elliptic curve points Pi based upon the m1 residues ci and elliptic curve points Gi; and send the m1 elliptic curve points Pi to the secure processor.

Abstract: One example discloses a circuit for varying a quality-factor of a wireless device: wherein the wireless device includes an antenna tuning circuit and a communications signal interface; the circuit including, a quality-factor circuit having a feedback circuit; wherein the feedback circuit is configured to be coupled between the antenna tuning circuit and the communications signal interface; wherein the quality-factor circuit is configured to measure an antenna system bandwidth of the wireless device; and wherein the feedback circuit is configured to apply positive feedback to the antenna tuning circuit if the measured bandwidth is greater than a maximum communication signal bandwidth.

Abstract: A signal processor comprising a plurality of microphone-terminals configured to receive a respective plurality of microphone-signals. A plurality of beamforming-modules, each respective beamforming-module configured to receive and process input-signalling representative of some or all of the plurality of microphone-signals to provide a respective speech-reference-signal, a respective noise-reference-signal, and a beamformer output signal based on focusing a beam into a respective angular direction. A beam-selection-module comprising a plurality of speech-leakage-estimation-modules, each respective speech-leakage-estimation-module configured to receive the speech-reference-signal and the noise-reference-signal from a respective one of the plurality of beamforming-modules; and provide a respective speech-leakage-estimation-signal based on a similarity measure of the received speech-reference-signal with respect to the received noise-reference-signal.

Abstract: There is described an electronic device, the device comprising (a) a power supply terminal for connecting to a power supply (130, 330), (b) a first circuit (110, 310) coupled to be powered by the power supply, the first circuit (110, 310) being susceptible to power supply noise within a predetermined frequency range, and (c) a second circuit (120, 320) coupled to be powered by the power supply, the second circuit (120, 320) comprising an open-loop capacitive DC-DC converter (323) having a switching frequency outside of the predetermined frequency range. There is also described a system comprising an electronic device and a reader/writer device. Furthermore, there is described a method of manufacturing an electronic device.