Abstract: Wireless power and data transfer can be implemented for powering and communicating with a variety of devices, in a manner that facilitates device access under such wireless power conditions. As consistent with one or more embodiments, wireless power and data are communicated in an apparatus such as a mobile device having a power circuit (e.g., a battery) that powers a processor under normal operating conditions, and that also operates in a low-power state (e.g., in which the processor is not operating and/or not operating using the power circuit). Power is generated using wireless power signals and used to power the power circuit and to both extract and store data from wireless data signals. With this approach, data can be transferred in a low-power state, and the processor can use the stored data upon transitioning to an on state in which the processor is active and powered by the power circuit/battery.

Abstract: A processor (110) is disclosed for processing a plurality of Fourier-transformed instances of a symbol, each instance being comprised in one of a plurality of frequency-divided multiplexed subcarriers, said processor being arranged to estimate, for each instance, the channel gain and the inter-carrier interference contribution to said symbol from neighboring subcarriers due to a time-varying channel response of the received signal, and combine the instances into a single representation of said symbol based on the estimated channel gain and the inter-carrier interference contributions. A receiver comprising such a processor and a method for processing such signals are also disclosed.

Abstract: A switched mode power converter is disclosed, together with a method for operating the same. The power converter is adapted to be operable in the boundary conduction mode, and operation is interruptible in the absence of any load requirement.

Abstract: Equalization circuits and methods are implemented for a variety of applications. According to one such application, a transmitting device wirelessly communicates using an antenna. The device has a transmission circuit that is configured and arranged to transmit a first wireless signal using magnetic coupling between the antenna and a remote device, the coupling occurring over a wireless medium. A receiver circuit of the transmitting device is configured and arranged to receive a second wireless signal that is from the antenna and that represents the first wireless signal as modified by the coupling occurring over the wireless medium. An error circuit of the device is configured and arranged to generate an error signal by comparing the first wireless signal to the second wireless signal. An equalizer circuit of the device is configured and arranged to pre-code the first wireless signal with coding that compensates for inter-symbol interference by compensating for the error signal.

Abstract: In order to reduce latency of elliptical curve digital signature generation a portion of the digital signature is pre-calculated before receipt of the message hash using an unmodified ECDSA computing engine. After the message hash is received, the digital signature is completed without using the ECDSA computing engine. Applications include generating digital signatures for the safety messages in Intelligent Transport Systems.

Abstract: Various exemplary embodiments relate to a product assembly including: a product; and a code tag that carries a uniform resource identifier (URI) that includes an identifier for the product, wherein the code tag is configured to be read by a user device to read the URI, wherein the URI points to a lead distribution server and is configured to cause the lead distribution server to redirect the user device to a web page. Various embodiments relate to a method and related user device including: reading information from a code tag associated with a product, wherein the information includes a URI, wherein the URI points to a server and includes an identification of the product; transmitting an access request to the server based on the URI; and communicating, in response to transmitting the access request, with a device to place an order.

Abstract: A computer-implemented method for assisting in recording video content on a video recording device. The method involves displaying a cross which comprises two orthogonal intersecting lines, displaying an indicator token, and changing the state of at least one of the cross and the indicator token in response to a control signal from the video recording device to provide visual notification to a user of the video recording device.

Abstract: Various exemplary embodiments relate to a method, device, and storage medium including: receiving an NDEF message by an NFC device including a payload and at least one of a digital signature and a reference to a digital signature; stripping data from the payload to produce a stripped payload; verifying the payload using the digital signature and the stripped payload; and conditionally interpreting the payload based on whether the payload is verified. Various embodiments are described wherein: the payload includes a URI including a fragment denoted by a pound character; and stripping data includes stripping the fragment from the URI. Various embodiments are described wherein the payload is verified, the fragment comprises fragment data, and interpreting the payload comprises: transmitting a message requesting a resource identified by the URI, wherein the request omits the fragment data; executing a received script to transmit the fragment data to a device.

Abstract: A method of securely implementing functions in a secure software application, including: determining, by a processor, two functions to be implemented by the secure software application; generating a first function lookup table; encrypting the first function lookup table; sorting the first function lookup table by encrypted operand; generating a second function lookup table; encrypting the second function lookup table; sorting the second function lookup table by encrypted operand; generating a flattened lookup table from a combination of the encrypted first and second function lookup tables; permutating the flattened table indices e.g. by use of public key cryptography encryption; and sorting the flattened table by the permutated flattened table indices.

Abstract: An integrated Doherty amplifier circuit comprising a main input terminal, a peak input terminal and an output terminal, a main input conductor and a peak input conductor that are offset from one another in a first direction, the main and peak input conductors extend in a second direction that is perpendicular to the first direction, and wherein an input end of the main input conductor is coupled to the main input terminal and an input end of the peak input conductor is coupled to the peak input terminal, an output conductor that extends in the second direction, an output end of the output conductor is coupled to the output terminal, a main amplifier stage extends in the second direction and has a main stage input and a main stage output, a peak amplifier stage extends in the second direction and has a peak stage input and a peak stage output.

Abstract: A power transistor circuit uses first and second power transistors in differential mode. An inductor arrangement of inductors is formed by wire bonds between the drains. The transistors are in a mirrored configuration, and the inductor arrangement comprises wire bonds which extend between the drain connections across the space between the mirrored transistors.

Abstract: An integrated circuit package for an integrated circuit having one or more sensor elements in a sensor element area of the circuit. An encapsulation covers bond wires but leaves an opening over the sensor element area. A protection layer is provided over the integrated circuit over which the encapsulation extends, and it has a channel around the sensor element area to act as a trap for any encapsulation material which has crept into the opening area.

Abstract: According to an example embodiment, a device provides cryptographic processing functions using secret data. The device can include protection from differential power analysis (DPA). The encryption processing circuit and its memory can be decoupled from external power source(s) during encryption-related computations. A local power storage element, such as a capacitive element, can provide power while the encryption processing circuit is decoupled from the external power source(s). The local power storage element can then be reconnected and charged once the encryption-related computations are completed or paused.

Abstract: A method for handling collision in an identification system where the identification system includes a reader, a first transponder and a second transponder. The method involves the reader transmitting an initialization command to the first transponder and to the second transponder; upon receiving the initialization command, the first transponder and the second transponder enter into a muted state where the first transponder and the second transponder do not respond to commands from the reader; in a randomly determined first start time slot the first transponder enters into an un-muted state and the first transponder remains in the un-muted state until the reader sends a mute command to the first transponder; in a randomly determined second start time slot the second transponder enters into an un-muted state and the second transponder remains in the un-muted state until the reader sends a mute command to the second transponder.

Abstract: A method and controller for power dependant mains under-voltage (“brown-out”) protection is disclosed. Brown-out protection is meant for protection against overheating due to low mains voltage and associated high mains current. The disclosed method and controller allow for lower mains voltages at low load by comparing the mains voltage with a signal indicating the actual power level of the power supply. In converters such as flyback converters, this brown-out protection can be implemented by comparing the actual peak voltage of the mains voltage with a control signal that indicates the power level. In other embodiments, the mains voltage is compared to a preset level by means of a comparator. Provided the voltage passes the preset level prior to opening the control window, the SMPS functions normally. Conversely, brown-out protection is initiated if the voltage does not pass the preset level before the control window opens.

Abstract: A transponder (140) for communicating with a reader device (120), the transponder (140) comprising a processing unit (142) adapted for generating an identifier (210) during an initialization phase of a communication session with the reader device (120), the identifier (210) being generated as a combination of a first part (214) being a random number and of a second part (212) being identical to a portion (202) of a previous identifier (200) used during a previous communication session preceding the present communication session with the reader device (120), and a transmission unit (136) adapted for transmitting the identifier (210) to the reader device (120).

Abstract: Embodiments of a method for controlling a charge pump and a control device for a charge pump are described. In one embodiment, a method for controlling a charge pump involves monitoring a power-on status of the charge pump, calculating a duty cycle of the charge pump within a time period based on the power-on status of the charge pump, and adjusting at least one of a clock frequency setting and a capacitance setting of the charge pump in based on the duty cycle of the charge pump. Other embodiments are also described.

Abstract: A receiver is disclosed, wherein a re-ordering means comprises a multiplexer, a finite-state machine, and a plurality of buffers. the finite-state machine is arranged to control the multiplexer to load the buffers from a bus such that the output of the buffers is directly decodable by the decoder. A receiving method is also disclosed, comprising the steps of: determining a transmission mode and a bus configuration; entering an initializing state of branching of a finite-state machine according to said determined transmission mode and bus configuration; performing transitions between state of the said finite-state machine for each received set of soft data provided on a bus; multiplexing said soft data to a plurality of buffers in dependence on the state of said finite-state machine; and writing said multiplexed data into said plurality of buffers.

Abstract: The present invention provides a capacitive MEMS device comprising a first electrode lying in a plane, and a second electrode suspended above the first electrode and movable with respect to the first electrode. The first electrode functions as an actuation electrode. A gap is present between the first electrode and the second electrode. A third electrode is placed intermediate the first and second electrode with the gap between the third electrode and the second electrode. The third electrode has one or a plurality of holes therein, preferably in an orderly or irregular array. An aspect of the present invention integration of a conductive, e.g. metallic grating as a middle (or third) electrode. An advantage of the present invention is that it can reduce at least one problem of the prior art. This advantage allows an independent control over the pull-in and release voltage of a switch.

Abstract: A distributed radio system comprising a first receiver (1) and a second receiver (2) each receiver comprising a tuner (11, 21) adapted to receive radio signals and to transmit tuned radio signals, a first baseband unit (12, 22) coupled to the tuner (11,21) and adapted to receive the tuned radio signals and to partially demodulate the tuned radio signals, the first baseband unit (12,22) being further adapted to transmit partially demodulated signals, a second baseband unit (14, 24). The distributed radio system further comprising a digital communication channel (3) adapted to receive the partially demodulated signals and to redistribute the partially demodulated signals to the second baseband unit (14, 24).