Abstract: A microcontroller using an optimized buffer replacement strategy comprises a memory configured to store instructions, a processor configured to execute said program instructions, and a memory accelerator operatively coupled between the processor and the memory. The memory accelerator is configured to receive an information request and overwrite the buffer from which the prefetch was initiated with the requested information when the request is fulfilled by a previously initiated prefetch operation.

Abstract: A satellite digital radio receiver for receiving first and second radio services. The first and second radio services are broadcast in first and second respective different radio frequency bands. At least one radio programme is broadcast substantially simultaneously on both radio services and one of the frequency bands can produce interference in the other frequency band.

Abstract: An audio-processing device having an audio input, for receiving audio signals, each audio signal having a mixture of components, each corresponding to a sound source, and a control input, for receiving, for each sound source, a desired gain factor associated with the source, by which it is desired to amplify the corresponding component, and an auxiliary signal generator, for generating at least one auxiliary signal from the audio signals, and with a different mixture of components as compared with a reference audio signal; and a scaling coefficient calculator, for calculating scaling coefficients based upon the desired gain factors and upon parameters of the different mixture, each scaling coefficient associated with one of the auxiliary signal and optionally the reference audio signal, and an audio synthesis unit, for synthesizing an output audio signal by applying scaling coefficients to the auxiliary signal and optionally the reference audio signal and combining the results.

Abstract: The invention proposes a smart card which comprises a digital signal processing receiver that can automatically identify the type of a smart card reader based on the error vector magnitude of signals received from the reader. The digital signal processing receiver is able to reconfigure itself at runtime in order to optimally minimize its power consumption in dependence on the type of reader it is communicating with. Furthermore, the invention proposes a new preamble structure that comprises a basic part and an optional additional part.

Abstract: A non-volatile memory circuit includes memory rows and supporting circuits coupled to the memory rows, where at least one of the memory rows include at least one Electrically Erasable Programmable Read-Only Memory (EEPROM) memory element and at least one Flash memory element. The EEPROM and Flash elements are configured to share some of the supporting circuits and can be accessed in parallel.

Abstract: A method of estimating the transmission channel of a received multi-carrier signal in a mobile environment, by identifying pilots present on carriers of the received multi-carrier signal, which pilots comprise continual pilots, performing channel estimation on the received multi-carrier signal using a time-domain interpolator to give a first interpolator output, and performing channel estimation on the received multi-carrier signal using a frequency-domain interpolator to give a second interpolator output. A frequency offset in a continual pilot is detected, and either the first or second interpolator output is selected based on the detected frequency offset. The invention also relates to a system for estimating the transmission channel of a received multi-carrier signal in a mobile environment.

Abstract: A class H amplifier circuit includes a Buck converter 20 and a charge pump 30 which are used to generate voltages which are used in turn to power an output driver 10. A feedback path 36 controls the loop. The circuit is particularly suitable as a high efficiency circuit for driving headphones or loudspeakers.

Abstract: A method for authentication of devices (D1, D2, D3) in a wireless network, wherein—a device (D1, D2, D3) periodically switches its mode from a read mode, in which it is able to receive authentication data from one or more other devices (D1, D2, D3), to a write mode, in which it sends out authentication data to the one or more other devices (D1, D2, D3), according to a random time slot scheme, —the device (D1, D2, D3) authenticates itself after having received authentication data from another device (D1, D2, D3) during the read mode, and—the device (D1, D2, D3) switches permanently its mode to the write mode after being authenticated.

Abstract: The present invention relates to MEMS device that comprises a first electrode, and a second electrode suspended with a distance to the first electrode with the aid of a suspension structure. The MEMS device further comprises at least one deformation electrode. The second electrode or the suspension structure or both are plastically deformable upon application of an electrostatic deformation force via the deformation electrode. This way, variations in the off-state position of the second electrode that occur during fabrication of different devices or during operation of a single device can be eliminated.

Abstract: A method of forming a pattern in at least one device layer in or on a substrate comprises: coating the device layer with a first photoresist layer; exposing the first photoresist using a first mask; developing the first photoresist layer to form a first pattern on the substrate; coating the substrate with a protection layer; treating the protection layer to cause a change therein where it is in contact with the first photoresist, to render the changed protection layer substantially immune to a subsequent exposure and/or developing step; coating the substrate with a second photoresist layer; exposing the second photoresist layer using a second mask; and developing the second photoresist layer to form a second pattern on the substrate without significantly affecting the first pattern in the first photoresist layer, wherein the first and second patterns together define interspersed features having a spatial frequency greater than that of the features defined in each of the first and second patterns separately.

Abstract: An RFID tag (1, 1?) comprises at least one antenna (2, 2?) and electronic tag components (4) cooperating with the antenna, wherein the antenna (2, 2?) and the electronic tag components (4) are positioned on a common substrate (3), wherein portions (3b) of the substrate encircled by the antenna (2, 2?) and not occupied by the electronic tag components (4) have been removed.

Abstract: Magnetic field sensors (1) comprising field detectors (10) for detecting magnetic fields are provided with environment detectors (11) for detecting environments and with processors (12) for, in response to detected environments, performing processes such as loading calibration parameter sets and (re)calibrations for the field detectors (10), to allow the magnetic field sensors (1) to be used in different subsequent environments. The environment detectors (11) may comprise code detectors for detecting codes indicative for environments and may comprise user interfaces (13) for, in response to detected environments and via user interactions, selecting processes to be performed by the processors (12). Devices (2) comprise magnetic field sensors (1). Apparatuses (3) such as cradles removably fix the devices (2) and may comprise code generators (30) for generating the codes indicative for the environments.

Abstract: An analog memory circuit, i.e. a sample and hold circuit, wherein the source and the gate of the switching transistor is maintained at a same potential prior and after the sampling process using a transistor circuitry. The analog memory circuit comprises a memory capacitor (102) connected at a first end to a first port (104), which is connected a reference potential (106). A drain of a first transistor (108) —switch transistor—is connected to a second end of the memory capacitor (102). A source of the first transistor (108) is connected to a second port (110), which is connected to circuitry (112) for providing an input signal for storage in the memory capacitor (102), and a gate of the first transistor (108) is connected to a third port (114), which is connected to a first current sink (116). A source of a second transistor (118) is connected to the source of the first transistor (108) and a drain of the second transistor (118) is connected to the gate of the first transistor (108).

Abstract: The present invention relates to a low noise amplifier comprising a transformer, a first amplifier and a feedback resistor, the transformer comprising a primary stage and a secondary stage. The secondary stage is connected to the input of the first amplifier and the output of the first amplifier is connected in series with a feedback resistor and the primary stage of said transformer.

Abstract: A circuit is implemented for a near field communication (NFC) system which includes a communication partner appliance. The circuit is a data carrier which includes activators, a receiver, a detector, and a processor. The activators activate a first or second communication mode. The receiver receives a carrier signal that is transmitted to the communication partner appliance by another communication partner appliance. The detector detects the presence of the received carrier signal and transmits a carrier signal present signal or a carrier signal not-present signal. The processor recognizes a command signal transmitted with the carrier signal. The processor also generates and transmits a command-end signal that is separate from the transmitted command signal and represents the end of the transmitted command signal. The processor also determines whether, after the occurrence of the command-end signal, the carrier signal present signal is present. The processor also transmits a first or second activation signal.

Abstract: There is provided a method that comprises identifying a parasitic signal transfer in a filter using a signal-directed graph; and adding compensation paths to the filter to reduce or eliminate the effect of the parasitic signal transfer A corresponding filter is provided which comprises a plurality of amplifier stages that generate one or more filter poles; at least one component coupled to at least one of the amplifier stages, the component causing a parasitic effect in the filter; and means for applying a compensation current to the at least one amplifier stage to reduce or eliminate the parasitic effect.

Abstract: A MEMS resonator comprises a resonator body (34), and an anchor (32) which provides a fixed connection between the resonator body (34) and a support body. A resistive heating element (R1,R2) and a feedback control system are used to maintain the resonator body (34) at a constant temperature. A location for thermally coupling the anchor (32) to the resistive heating element (R1,R2) is selected which has a lowest dependency of its temperature on the ambient temperature during the operation of the feedback control.

Abstract: Consistent with an example embodiment a repeater device is provided for handling signal transmissions, in particular in a DisplayPort environment. The repeater is to be coupled with an upstream device and a downstream device, the repeater being adapted for transmitting signals received from the upstream device to the downstream device and for conditioning the signals before transmission. The repeater is configured to provide a transparent communication path between the upstream device and the downstream device for DPCD access transactions belonging to a second group of DPCD access transactions. For DPCD access transactions belonging to a first group of DPCD access transaction, the repeater is configured to process the DPCD access transactions by accessing one or more DPCD registers included in the repeater.

Abstract: A system and method for driving a relay circuit involves driving a relay circuit using a first driver circuit if a voltage of a battery supply for the relay circuit is lower than a voltage threshold and driving the relay circuit using a second driver circuit if the voltage of the battery supply for the relay circuit is higher than the voltage threshold.

Abstract: In a circuit (3) for a data carrier (1), which data carrier (1) comprise a sensor (2) that is designed for providing a sensor signal (SS) that represents an environment parameter and a communication element (CM) that is designed for the contact-less communication with an interrogator station, first connection elements for connecting the circuit (3) to the communication element (CM) and second connection elements for establishing an electronic connection of the circuit (3) to the sensor (2) are provided, wherein the second connection elements are realized by the first connection elements and wherein the circuit (3) comprises a sensor signal processing stage (11A) designed for receiving said sensor signal (SS) via the first connection element and for processing said received sensor signal (SS).