Abstract: A switching circuit (400) comprising an inductive component (406) including at least one winding; and a switch (404) is configured to transfer power from a voltage source (402) to the inductive component (406) in accordance with a switch control signal (412). The switching circuit (400) also comprises a controller (408) configured to integrate the voltage across the inductive component (406) in order to generate a signal representative of magnetic flux in the inductive component (406); and use the signal representative of the magnetic flux in the inductive component to account for a peak magnetization current value in order to control the switch (404).

Abstract: The present invention is related to line-based motion estimation and compensation in video image data. In particular, by performing the line-based motion estimation, a set of motion vectors for the line-based motion compensation is provided. By use of the provided set of motion vectors, the line-based motion compensation is performed by interpolating the image data of the current field/frame, wherein an interpolated image data of the image data of the current field/frame is provided as result of the performing of the line-based motion compensation. Then, it is checked, whether a region of the interpolated image data of the current field/frame comprises at least one pixel of the region, which was interpolated according to a motion vector from the set of motion vectors, which is indicated as being not reliable for the line-based motion compensation. If so, a blurring of the corresponding region is performed according to the present invention.

Abstract: A UHF-RFID antenna having a central segmented loop surrounded by passive dipole structures provides shaping of the electric and magnetic fields to reduce the number of false positive reads by a UHF-RFID reader at a point of sale.

Abstract: A duty-cycle modulated bit signalling method and circuit, comprising: signaling bits by virtue of a duty-cycle ratio; wherein the duty-cycle ratio is varied dependent upon the transmission rate of the signalling. A bit period comprises a long phase and a short phase and the duty-cycle therebetween is varied such that the ratio between the duration of the long phase and the duration of the short phase is increased for decreasing transmission rate. The duty-cycle ratio is varied dependent upon the transmission rate of the signalling according to one or more ranges of transmission rate. In a higher transmission rate range the duty-cycle is defined as a fixed ratio, and in a lower transmission range the duty-cycle is defined by a fixed length of the short phase of the bit period.

Abstract: A channel frequency response estimator for estimating the channel frequency response of a wireless RF channel having a time or frequency varying channel frequency response is disclosed. The channel frequency response estimator includes a wireless receiver. An ambiguous channel frequency response estimator is also included and configured to establish multiple channel frequency response estimate candidates for the channel frequency response of the channel. An ambiguity resolver is configured to select a channel frequency response estimate from the multiple channel frequency response estimate candidates that maximizes a goodness of fit of the selected first channel frequency response estimate, and at least two further channel frequency response estimates to a channel model. The channel model models the time or frequency dependent variance of the channel frequency response.

Abstract: Near-field communication (NFC) is effected in a manner that ensures that messages are read. In accordance with one or more embodiments, an apparatus includes a NFC antenna, a NFC tag and a host connected to the NFC tag via both a data communication circuit and a field detection circuit. The NFC tag stores and transmits an NFC data exchange format (NDEF) message via the NFC antenna. The NFC tag includes first and second registers respectively having data indicative of a read status of the NDEF message and data indicative of a last portion/byte of the NDEF message data. When the NDEF message is accessed (e.g., transmitted), the NFC tag sets the data in the first register to indicate that the NDEF message has been read (e.g., sets a bit value). The trigger circuit generates a trigger signal in response to the status, indicating that the NDEF message has been read.

Abstract: A digital down converter is disclosed. The digital down converter includes an input for receiving a sampled signal having a frequency band of interest, sampled at a first sampling rate, a commutator structure for distributing a set of real sampled signals for polyphase filtering, a complex band pass polyphase filter associated with the distributed signals, for generating in phase and quadrature filtered components, a baseband notch filter, and a frequency translator for generating in phase and quadrature components of the frequency band of interest at baseband.

Abstract: A method of encoding a digital bus message information, in particular a wake-up bus message information or configuring data, on a bus system, the method comprising: encoding a predetermined part of digital bus message information bits by means of sub-patterns in a stream of line symbols on at least one bus line, wherein sub-patterns consist of successive dominant and recessive phases, comprised of recessive and dominant line symbols, wherein a recessive phase is comprised of at least two recessive line symbols in order to establish a ratio of successive dominant and recessive phases that corresponds to a value of the predetermined part. A respective digital bus message, particularly for use on a bus system, is to be encoded in accordance with the method.

Abstract: The invention relates to a method of operating a RFID system comprising at least one reader (1) and a plurality of wireless data carriers (2), each of which comprise at least one data processing element with slow response (5), wherein the method controls the at least one reader (1) to continuously communicate with one of the plurality of wireless data carriers (2), while at least another one of the plurality of wireless data carriers (2) is processing data with its at least one slow response element (5). The invention further relates to a RFID system comprising at least one reader (1) and a plurality of wireless data carriers (2), each of which comprises at least one slow response element (5), wherein the system is capable to continuously communicate with at least one of the plurality of wireless data carriers (2), while at least another one of the plurality of wireless data carriers (2) is processing data with its at least one slow response element (5).

Abstract: In a method for processing top-up data, a server (8) receives data related to a request for issuing an NFC application (9). The data were sent by an NFC mobile device (3) and are intended for a Service Provider (2). At the server (8) transformed data are generated by transforming the data related to the request into a format complying with the Server Provider (2). The transformed data are sent to the Service Provider (2) for further processing and issuing the NFC application (9) to the mobile device (3) particularly utilizing a Trusted Service Manager (1).

Abstract: Embodiments of a latch circuit and a method of operating a latch circuit are described. In one embodiment, a latch circuit includes an input terminal configured to receive an input data signal, a switching unit configured to control application of the input data signal, a first inverter circuit connected to the switching unit, where the first inverter circuit includes a first cross-coupled pair of inverters, and a second inverter circuit connected to the first inverter circuit through the switching unit. The second inverter circuit includes a second cross-coupled pair of inverters and two transistor devices. Each inverter of the second cross-coupled pair of inverters is connected to a voltage rail through a corresponding transistor device. Each of the two transistor devices is connected to a node that is between the switching unit and the first inverter circuit or the second inverter circuit. Other embodiments are also described.

Abstract: Cross-talk is mitigated in a switching circuit. In accordance with one or more embodiments, an apparatus includes a multi-pin connector having signal-carrying electrodes that communicate with a device external to the apparatus, and respective field-effect switches that couple the signal-carrying electrodes to respective communication channels in the apparatus. The switches include a first field-effect semiconductor switch having a gate electrode adjacent a channel region that connects electrodes (e.g., source and drain regions) when a threshold switching voltage is applied to the gate, in which the electrodes are connected between one of the signal-carrying electrodes and a first channel coupled to an electrostatic discharge (ESD) circuit. A bias circuit mitigates cross-talk between the communication channels by biasing the channel region of the first field-effect semiconductor switch (in an off state) to boost the threshold switching voltage over a threshold discharge voltage of the ESD circuit.

Abstract: System and method for authenticating components of a vehicle are described. In an embodiment, a method for authenticating components of a vehicle involves transmitting an interrogation signal to tags attached to the components of the vehicle from an authentication base station in response to a trigger event, comparing an authentication code received from each of responding tags with an authentication code key at the authentication base station to authenticate the responding tags, and transmitting a disengage signal to an immobilizer installed in the vehicle from the authentication base station to enable the vehicle if all the tags have been authenticated. Other embodiments are also described.

Abstract: A user-interface for controlling a data processing system using a joystick includes a joystick for controlling input to the data processing system. The joystick has a pivoting component for assuming tilted positions by tilting in directions that lie in a reference plane associated with the component, and a sensor for sensing at succeeding sampling moments the direction corresponding to succeeding tilted positions of the component, and a difference determination device for determining a difference in direction between a first direction sensed at a first sampling moment and a second direction sensed at a second sampling moment after the first moment, and a parameter modifier for modifying a value of a parameter of the data processing system by adding or subtracting a difference value that depends upon the difference in direction.

Abstract: The disclosure relates to the implementation of multi-tasking on a digital signal processor. Blocking functions are arranged such that they do not make use of a processor's hardware stack. Respective function calls are replaced with a piece of inline assembly code, which instead performs a branch to the correct routine for carrying out said function. If a blocking condition of the blocking function is encountered, a task switch can be done to resume another task. Whilst the hardware stack is not used when a task switch might have to occur, mixed-up contents of the hardware stack among function calls performed by different tasks are avoided.

Abstract: A 3-level class D amplifier circuit comprises a first comparator for comparing an input with a first triangular reference and a second comparator for comparing the input with a second triangular reference. A phase relationship between the signals to the first comparator is 180 degrees shifted relative to a phase relationship between the signals to the second comparator. An amplifier stage generates a three-level PWM output signal using the outputs of the first and second comparators. A shared feedback path is used from the three-level PWM output signal.

Abstract: Ambient light is sensed for use in determining luminous flux. According to an example embodiment, ambient light is sensed using two light sensor arrangements that respectively respond differently to light of different relative wavelengths. The output of the sensors is nonlinearly combined to generate data indicative of the luminous flux. This luminous flux data is used to generate a control output for controlling an electronic display.

Abstract: A switched mode power converter controller outputs a switch control signal for a switch, receives sensed voltage and primary current input signals, and includes a constant current mode controller to process voltage input signals and generate output control signals for controlling converter peak current and/or switching frequency operational; a constant voltage mode controller processes the voltage input signal and generates output control signals for converter peak current and/or switching frequency operational parameters; a primary peak current adjuster processes primary current input and output control signals from the current and voltage mode controllers to configure the switch control signal to turn off the switch; a switching frequency adjuster processes output control signals from the current and voltage controllers to configure the switch control signal to turn on the switch.

Abstract: The invention relates to an electronic device comprising an RF-LDMOS transistor (1) and a protection circuit (2) for the RF-LDMOS transistor. The protection circuit (2) comprises: i) an input terminal (Ni) coupled to a drain terminal (Drn) of the RF-LDMOS transistor (1); ii) a clipping node (Nc); iii) a clipping circuit (3) coupled to the clipping node (Nc) for substantially keeping the voltage on the clipping node (Nc) below a predefined reference voltage, wherein the predefined reference voltage is designed to be larger than the operation voltage on the drain terminal (Drn) and lower than a trigger voltage of a parasitic bipolar transistor (100) that is inherently present in the RF-LDMOS transistor; iv) a capacitance (Ct) coupled between the clipping node (Nc) and a further reference voltage terminal (Gnd), and v) a rectifying element (D1, D2) connected with its anode terminal to the input terminal (Ni) and with its cathode terminal to the clipping node (Nc).

Abstract: A method for server-based managing of unique memory device identifications, such as serial numbers, of memory devices having unique memory device identifications, such as emulated MIFARE devices like SmartMX cards, which memory devices are arranged in mobile communication devices, comprises keeping a repository (DB) of available memory device identifications; fetching a memory device identification from the repository and sending it to a specific mobile communication device; and instructing the mobile communication device to change the memory device identification of its associated memory device from its present value to the received new value. Further, the server instructs the mobile communication device to return the previous value of the memory device identification of its associated memory device. Finally, the server will add the returned memory device identification value to the repository of memory device identifications.