Abstract: A FinFET (100) comprises a fin-shaped layer-section (116) of a single-crystalline active semiconductor layer (104) extending on an insulating substrate layer (106) along a longitudinal fin direction between, a source layer-section (122), and a drain layer-section (124) of the single-crystalline active semiconductor layer (104). Furthermore, two separate gate-electrode layers (138.1, 138.2) are provided, which do not form sections of the single-crystalline active semiconductor layer, each of the gate-electrode layers facing one of the opposite side faces of the fin-shaped layer-section (116). Each gate-electrode layer is connected with a respective separate gate contact (154, 156).

Abstract: The invention relates to high power radiofrequency amplifiers, in particular to amplifiers having output impedance matching networks, exemplary embodiments of which include a radiofrequency amplifier having an active device mounted on a substrate within a device package, the amplifier having an output impedance matching network comprising a high pass network provided at least partly on the active device and a low pass network having a first inductive shunt connection between an output of the active device and a first output lead and a second inductive shunt connection between the output of the active device and a second output lead, wherein part of the second output lead forms an inductance contributing to the inductance of the low pass network.

Abstract: Existing ANC headsets have active noise reduction circuitry and a power supply in the headset. Alternate ANC headsets rely on ANC circuitry in the player and have non-standard connectors meaning that they cannot be used with any other players. An audio headset (90) having an encoder (54) and active noise cancellation audio processing device (80) having a decoder (32) are described. The encoder (54) enables the audio headset to be used in enhanced (ANC) mode when connected to a compatible audio processing device and in normal mode when connected to a non-compatible audio processing device since a standard audio jack plug can be used. Similarly the decoder (62) in the active noise cancellation audio processing device (80) enables the active noise cancellation audio processing device to be used in enhanced mode when connected to a compatible audio headset and in normal mode connected to a non-compatible audio headset since a standard audio socket can be used.

Abstract: A switch module is designed to facilitate user definition of a group of switch modules that control the same lamp. A lamp unit (12) containing the lamp responds selectively to messages from the switch modules (10, 10?) when the messages comprise ID information matching with ID information stored in the lamp unit (12). A group is formed by detecting user control operation of sensors (100) in the switch modules (10, 10?), transmitting messages from the switch modules (10, 10?) in response and determining from the messages whether the switch modules (10?) have both been operated within a time interval with a duration of less than a predetermined threshold. If so, the ID information value in memories (104) of the switch module (10) and/or the further switch module (10?) are set to matching ID values, for use in the messages to control the lamp unit.

Abstract: A matching network is integrated into a multilayer surface mount device containing an RFID integrated circuit to provide both an antenna and a matching network for the RFID integrated circuit in the ultra high frequency regime. The surface mount device may be mounted on a printed circuit board to provide RF and RFID functionality to the printed circuit board.

Abstract: A smartcard having a microcontroller kernel and a non-secure memory capable of storing a Random-ID code, where the non-secure memory is electrically coupled to the microcontroller kernel. A random number generator is for generating a new Random-ID code and the random number generator is electrically coupled to the microcontroller kernel. A user interface is electrically coupled to the random number generator so that the user may initiate generation of the new Random-ID code by the random number generator for storage in the non-secure memory.

Abstract: A pass-gate has a passageway between an input node and an output node. The pass-gate selectively opens or closes the passageway for a signal at the input node under control of a voltage. The pass-gate has a field-effect transistor with a gate electrode and a current channel. The current channel is arranged between the input node and the output node. The gate electrode receives the voltage. The pass-gate is configured so as to have the voltage at the control electrode substantially follow the signal at the input node when the passageway is open to the signal.

Abstract: A method for low-level security based on the UID. In particular it enhances an RFID system by adding the ability to dynamically modify the UID of the smartcard or to randomly generate a new UID for the smartcard.

Abstract: A resonant converter comprises switching circuitry (1) for supplying pulses, at a controllable frequency, to a resonant circuit so as to power the primary circuit (3, 12) of a transformer (4). The secondary winding (5a, 5b) of the transformer (4) delivers an AC signal which is rectified and then produces a load current. On the primary side, the converter has a resistor (13) for deriving a first electrical signal representative of the current in the primary circuit (3, 12), and an auxiliary winding (14) which is closely coupled to the secondary winding (5a, 5b) and across which an auxiliary voltage is induced as a consequence of the close coupling of the winding (14) to the secondary winding (5a, 5b). A resistor/capacitor combination (16, 17) integrates the auxiliary voltage with respect to time to derive a second electrical signal.

Abstract: An oscillation signal with a selectable frequency is generated with a phase locked loop (10, 12, 14). The oscillator (10) of the loop receives a feedback signal, to which an offset is added in order to reduce transient effects when a frequency modification is made. A first and second offset control value are used to control the offset successively. The first offset control value is controlled by a combination of the frequency settings before and after the modification. The second offset control value is controlled by the frequency settings after the modification. The first and second offset control values are used to control an offset of applying to a frequency control signal of an oscillator (10) of the phase locked loop (10, 12, 14). The offset controlled by the first control offset value is applied during a predetermined time interval before the offset controlled by the second control offset value is applied.

Abstract: A method for verifying a software application to a user of a device such as a mobile phone. The device receives (102) the software application, for example a Java ME MIDIet, and checks (104) a signature associated with the software application. Where the signature is recognized, the phone indicates (108) this status to the user, for example by displaying the familiar padlock icon. The mobile phone then establishes (110) a secure code known only to the user and a trusted entity, the entity being for example the manager of the Java ME environment. The device identifies (114) the software application to the trusted entity which then checks (116) the status of the software application. If the status is verified, the entity sends (118) the status to the device; which in turn indicates (120) the secure code to the user, for example as an additional displayed number, pictogram or the like.

Abstract: The present invention relates to a video decoder for decoding a bit stream corresponding to pictures of a video signal. The invention is such that, motion vectors having values coded at a nominal resolution in the bit stream, said video decoder includes a rounding unit for rounding decoded nominal motion vectors to a resolution different from the nominal resolution in a way that minimizes the error accumulation along prediction path by assigning to rounded successive motion vectors along the prediction path, successive values such that their average value is equal to the value of the nominal motion vector.

Abstract: It is described a method for providing an electronic key within an integrated circuit (100) including both a volatile memory (102) and a non-volatile memory (104). The described comprises starting up the integrated circuit (100), reading the logical state of predetermined data storage cells (102a) assigned to the volatile memory (102), which data storage cells (102a) are characterized that with a plurality of start up procedures they respectively adopt the same logical state, and generating an electronic key by using the logical state of the predetermined data storage cells (102a). Preferably, the predetermined data storage cells (102a) are randomly distributed within the volatile memory (102). It is further described an integrated circuit (100) for providing an electronic key.

Abstract: A common-mode voltage generator for a battery-supplied apparatus is provided with a battery voltage ripple-insensitive sensor comprising a voltage dividing circuit and a number of hysteresis comparators, by means of which a battery voltage, or a fraction thereof is compared with a series of reference voltages. These reference voltages are derived from an on-chip voltage by means of said voltage dividing circuit. The hysteresis of said hysteresis comparators is larger than the ripple on said battery voltage. Further there is an adjustable regulation loop. The sensor detects a battery voltage range and adjusts the regulation loop on the basis of this range. The regulation loop provides an output commonmode voltage, which is equal to a fraction, preferably half the battery voltage.

Abstract: To provide alphanumeric data, such as a PIN code, to a smart card (2) a terminal (1) is used which is capable of communicating with the smart card. The terminal comprises a keypad (4) for entering the alphanumeric data and an associated keypad matrix (5) for producing key signals, which the keypad matrix (5) is scanned for any pressed keys using a scanning sequence so as to produce key signals. To securely enter the data without the risk of the terminal intercepting them it is proposed that said scanning sequence is determined by the smart card (2). In this way, the terminal has no knowledge of the actual keys pressed and the secrecy of the alphanumeric data is ensured.

Abstract: The invention relates to a voltage-boosting stage (100) comprising a first capacitive voltage circuit (S1, S2, S3, S4, C0, Cb) coupled to a power supply (Vs) and providing an output voltage at an output terminal. The voltage-boosting stage further comprises a second capacitive voltage circuit (S5, S6, S7, S8, C1, Cb) coupled to a power supply (Vs) and providing another output voltage at another output terminal the output terminal and the other terminals being coupled together and further coupled to a supply terminal of a power stage (S9, S10) for implementing a two-level boosted power stage.

Abstract: In an RFID system a method for communication between a reader (1) and a tag (2) comprises: at the reader (1), switching on an electromagnetic signal (SS) for energizing the RFID tag (2) and/or transmitting an instruction (INST, RNREQ) or first data (D1) to the tag (2); at the tag (2), generating a random number (RN), converting said random number (RN) into a random time period (tx) and transmitting a response to the reader (1) after a delay time that corresponds to the random time period (tx); at the reader (1), measuring the random time period between transmitting the instruction (INST, RNREQ) or first data (D1) to the tag (2), receiving the response (RESP) from the tag (2), reconverting the measured random time period (tx) into the random number (RN), encrypting second data (D2) with the random number (RN) and transmitting said encrypted data (ED) to the tag (2); at the tag (2), decrypting the encrypted data (ED) by the use of the random number (RN).

Abstract: The present invention relates to an oscillator circuit and a method of controlling the oscillation frequency of an in-phase signal and a quadrature signal. First oscillator means (2) with a first differential oscillator circuit and a first differential coupling circuit are provided for generating the quadrature signal. Furthermore, second oscillator means (4) with a second differential oscillator circuit and a second differential coupling circuit are provided for generating the in-phase signal. A frequency control means is provided for varying the oscillation frequency of the in-phase signal and the quadrature signal by controlling at least one of a common-mode current and a tail current of the first and second oscillator means. Thereby, a high-frequency IQ oscillator with high linearity is obtained.

Abstract: A wireless transmitter (100) comprises a signal generator (10) for generating a signal, an amplifier (50) for amplifying the signal, and a phase shifting circuit (20) coupled between the signal generator (10) and the amplifier (50) and arranged to shift the phase of the signal to cancel remodulation of the signal generator (10) by the amplified signal.

Abstract: A communication device (9) has a Wi-Fi® device (14) for communicating with another communication device (9). The Wi-Fi® device (14) has one output connected to an antenna (13) and another output connected to a coaxial cable jack (10) via a coupler (11). The antenna (13) therefore provides a wireless communications link and the coupler (11) provides a wired communications link. A diversity switch (18) of the Wi-Fi® device (14) uses antenna diversity switching provided for in the Wi-Fi® standards to switch between the wireless communications link and the wired communications link.