Abstract: A power management system is provided. The power management system includes a first voltage regulator having an input coupled to a first voltage supply terminal and an output. The first voltage regulator is configured to provide an operating voltage at the output. A second voltage regulator has an input coupled to the output of the first voltage regulator. The second voltage regulator is configured to provide at an output a retention voltage based on a control signal. A control circuit is coupled to the second voltage regulator and configured to provide the control signal to the second voltage regulator.

Abstract: A method of manufacturing a packaged semiconductor device including forming an assembly by coupling a semiconductor die and an antenna by way of a substrate, contacting with a conformal structure at least a portion of a first surface of the antenna, and encapsulating the assembly with an encapsulant such that the at least a portion of the first surface of the antenna contacted by the conformal structure is not encapsulated with the encapsulant.

Abstract: Accordingly, systems and methods for managing power when the number of training and data tones are increased in a wireless communications system are provided. An L-SIG field is generated that includes a set of data and pilot tones, wherein the pilot tones are inserted between the data tones in the set of data and pilot tones. A plurality of training tones is added to the L-SIG field before and after the set of data and pilot tones. A symbol is generated that includes the L-SIG field, an L-LTF field, and a data field, wherein the training tones of the L-SIG field provide channel estimates for the data field. Power of the L-LTF field is managed relative to power of the L-SIG field in the generated symbol in a time domain.

Abstract: An apparatus for determining the occurrence of a leakage current between a series connected electrochemical battery cells, comprising: a first cell connection terminal for connection to a first cell's first terminal via first filter circuitry; a second cell connection terminal for connection, via second filter circuitry, to a connection between the first cell's second terminal and a second cell's first terminal, the first and second cell adjacent in the series arrangement; a first cell balancing terminal for connection to the first cell's first terminal bypassing the first filter circuitry; a second cell balancing terminal for connection to the connection between the first cell's second terminal and the second cell's first cell terminal; balancing circuitry for providing a connection between the cell balancing terminals; the apparatus configured to provide for identification of a leakage current based at least on a voltage between the cell connection terminals and the cell balancing terminals.

Abstract: A switched-capacitor gain stage circuit and method include an amplifier connected to an input sampling circuit with sampling switched capacitors for coupling an input voltage and a first or second reference voltage to one or more central nodes during a sampling phase and for coupling the one or more central nodes to an amplifier input during a gain phase, wherein a reference loading circuit uses a plurality of sampling switched capacitors connected in a switching configuration to selectively couple a first reference voltage and/or a second reference voltage to the central node by pre-charging the plurality of sampling switched capacitors with the first and second reference voltages during the sampling phase, and by coupling each of the first and second reference voltages to at least one of the plurality of sampling switched capacitors when connected to the central node during the gain phase.

Abstract: A system, method, and apparatus are provided for operating a device to receive a first signaling state sequence on a multi-wire interface within a first voltage range to cause the device to transition to a high-speed communication mode for receiving high-speed data on the multi-wire interface within a second, smaller voltage range before returning to a low-power communication mode when the device receives on the multi-wire interface a second sequence of two signaling states within the first voltage range to signal a turnaround command without requiring any additional signaling state within the first voltage range, where the turnaround command enables the device to transmit data from the device over the multi-wire interface by transmitting on the multi-wire interface the first sequence of signaling states within the first voltage range to cause the device to transition to a high-speed communication mode for transmitting data from the device over the multi-wire interface.

Abstract: The embodiments described herein provide systems and methods for determining the health status of a sensed switch. In general, the embodiments described herein determine a measure of a health status of the sensed switch by comparing a voltage on the sensed switch, ascertaining a first comparator state under one test condition and ascertaining a second comparator state under a second test condition. The first comparator state and the second comparator state are and then compared to determine the measure of the health status of the sensed switch.

Abstract: A method for detecting defeat devices in an engine control unit (ECU) includes storing with a key-data collection unit, a first key-data determined during an environmental test of a vehicle. The key-data collection unit stores a second key-data determined before the environmental test. Wherein, one of the first key-data is determined by the ECU modified by a characteristic only present before the environmental test and the second key-data is determined by the ECU modified by a characteristic only present during the environmental test. An environmental testing device compares the first key-data with the second key-data to detect an anomaly, wherein the anomaly indicates the presence of the defeat device in the ECU.

Abstract: Disclosed is a temperature sensor including a first current generator configured to generate a proportional to absolute temperature (PTAT) current, a second current generator configured to generate an inverse PTAT (IPTAT) current, the PTAT current and IPTAT current being combined to form a reference current having a sensitivity relative to temperature, a plurality of current mirrors to adjust the sensitivity and gain of the reference current, and a variable resistor to set an output calibration voltage based on the generated current.

Abstract: One example discloses a charging system, including: a charging device configured to be coupled to a device to be charged; wherein the charging device includes a set of hardware defined charging attributes; wherein the charging device is configured to reconfigure the hardware defined charging attributes based on a specific charging protocol received from the device to be charged; and wherein the charging device is configured to output charging power to the device to be charged as defined by the specific charging protocol.

Abstract: A control flow enforcement solution for ensuring that a program or portion thereof behaves as expected during execution upon a processor. A reference control flow is pre-determined for the program using, for example, a control flow graph (CFG). The CFG is then analysed to provide a set of rules which describe how the program should behave under normal execution. As the program executes it is monitored and the rules are evaluated to enable detection of any unexpected control flow. An embodiment of this disclosure is configured to respond upon detection that a rule has been violated. The response can take the form of any appropriate intervention such as a processor interrupt, memory fault, processor reset or generation of an alert. In this way, an embodiment of this disclosure may provide a particularly effective mechanism for detecting and defending against malicious activities such as return oriented programming attacks.

Abstract: A system that incorporates teachings of the subject disclosure may include, for example, a system including an RF switch connected with an antenna system that includes a first antenna and a second antenna. The system can include, where the RF switch has a first position in which the first antenna operates as the primary antenna and the second antenna operates as the diversity antenna, and wherein the RF switch has a second position in which the second antenna operates as the primary antenna and the first antenna operates as the diversity antenna. The system can include a controller coupled with the matching network and with the RF switch, where the controller receives first measurements associated with the antenna system, and where the controller adjusts the RF switch to select between the first and second positions according to the first measurements.

Abstract: An intelligent transportation system (ITS) station (400) for a vehicle (200) is described. The ITS station (400) includes a packet count and vehicle count estimator (342) arranged to receive broadcast ITS transmissions from a plurality of neighbouring vehicles and provide an indication of a number of the plurality of vehicles and a number of packets received from the plurality of neighbouring vehicles; and a fair resource allocator circuit (410) operably coupled to the packet count and vehicle count estimator (342) and configured to adjust a broadcast message rate and a modulation data rate of an ITS transmission in a cooperative manner based on application reliability requirements, the number of the plurality of vehicles and the indication of the number of received packets; and a transmitter operably coupled to the fair resource allocator circuit (410) and configured to broadcast at least one ITS message using the adjusted broadcast message rate and adjusted modulation data rate.

Abstract: Example systems have a defrost system that can receive a first RF signal at a first frequency to defrost a load. An air treatment device can receive a second RF signal at a second frequency and perform an air treatment process. An RF signal source has a power output, and a switching arrangement selectively electrically connects the defrost system and the first air treatment device to the power output of the RF signal source. A controller can electrically connect one of the defrost system and the first air treatment device to the power output of the RF signal source. When the defrost system is electrically connected, the RF signal source outputs the first RF signal at the first frequency, and when the first air treatment device is electrically connected, the RF signal source outputs the second RF signal at the second frequency.

Abstract: A method for producing a white-box implementation of a cryptographic function using garbled circuits, including: producing, by a first party, a logic circuit implementing the cryptographic function using a plurality of logic gates and a plurality of wires; garbling the produced logic circuit, by the first party, including garbling the plurality of logic gates and assigning two garbled values for each of the plurality of wires; and providing a second party the garbled logic circuit and a first garbled circuit input value.

Abstract: An electric field sensor including a dielectric layer having a plane surface, at least one transceiver antenna disposed on one side of the dielectric layer, the at least one transceiver antenna configured to emit a wave above the plane surface of the dielectric layer and detect an event adjacent the plane surface, an integrated circuit coupled to the at least one transceiver antenna.

Abstract: A narrow band received signal strength indicator circuit and a method for operating the same are provided. The circuit, for example, may include, but is not limited to, at least one wideband analog amplifier configured to amplify a received input signal, an analog-to-digital converter configured to convert the received input signal from an analog signal to a digital signal, at least one digital filter configured to filter unwanted signal components from the digital signal, and a controller communicatively coupled to the at least one digital filter, the controller configured to determine a received signal strength based upon the filtered digital signal.

Abstract: A software update architecture, system, apparatus, and methodology are provided for performing block-based swapping of OTA software stored as a plurality of compressed blocks in a first, smaller NVM with the system software stored as a plurality of decompressed blocks in a second, larger NVM by using a first decompressor circuit and first scratch memory to sequentially decompress each compressed code block of OTA software for storage in decompressed form as updated system software in the second, larger NVM while using a first compressor circuit and second scratch memory to sequentially compress each decompressed code block of system software for storage in compressed form as backup system software in the first, smaller NVM.

Abstract: A communication unit (400, 500) is described that includes a plurality of cascaded devices that comprise at least one master device and at least one slave device configured in a master-slave arrangement and configured to process at least one of: transmit signals, and receive signals. The at least one of at least one master device and at least one slave device comprises a demodulator circuit (564, 565) configured to: receive a modulated embedded master-slave clock signal (584) that comprises a system clock signal (582) with an embedded frame start signal (580); demodulate the modulated embedded master-slave clock signal (584); and re-create therefrom the system clock signal (588, 585) and the frame start signal (590, 586).

Abstract: A method for fast-enabling a current source includes conducting a first current through a first branch including a first transistor connected in series with a first switch, in response to enabling the first switch with an enable signal. A first charge is removed from a bias rail with a first capacitance between a first gate and a first source of the first transistor. A second current is conducted through a second branch including a second switch connected in series with a second transistor, in response to enabling the second switch with the enable signal. A second charge is added to the bias rail with a second capacitance between a second drain and a second gate of the second transistor, wherein the first gate and the second gate are connected to the bias rail and biased by the mirror reference voltage.