Abstract: A system, method, and apparatus are provided for processing packets received over Controller Area Network (CAN) interface where a CAN protocol controller computes a CRC value from header and payload values in a received CAN data frame to verify frame integrity of the received CAN data frame across a physical media layer, and then stores the header and payload values and the CRC value in a memory buffer of the CAN protocol controller so that a host core can compute a reconstructed CRC value from the header and payload values retrieved from the memory buffer, and then compare the reconstructed CRC value to the CRC value retrieved from the memory buffer to verify frame integrity of the received CAN data frame at a transaction layer.

Abstract: A radar system, apparatus, architecture, and method are provided for generating a transmit reference or chirp signal that is applied to a waveform generator having a frequency offset generator and a plurality of single channel modulation mixers configured to generate a plurality of transmit signals having different frequency offsets from the transmit reference signal for encoding and transmission as N radio frequency encoded transmit signals which are reflected from a target and received at a receive antenna as a target return signal that is down-converted to an intermediate frequency signal and converted by a high-speed analog-to-digital converter to a digital signal that is processed by a radar control processing unit which performs fast time processing steps to generate a range spectrum comprising N segments which correspond, respectively, to the N radio frequency encoded transmit signals transmitted over the N transmit antennas.

Abstract: A method of manufacturing a packaged semiconductor device is provided. The method includes attaching a semiconductor die to a package substrate. A bond pad of the semiconductor die is coupled to an antenna radiator formed on the package substrate. A waveguide is attached to the package substrate. An opening of the waveguide includes sidewalls substantially surrounding the antenna radiator. An epoxy material is deposited over at least a portion of the package substrate while leaving the opening void of epoxy material.

Abstract: A memory controller includes a large combinational cloud to serve multi-core-to-multi-bank memory accesses which causes congestion and routing delays at physical design level especially in lower technology nodes thus limiting the frequency of operation. Present invention proposes an architecture to process sequences of access requests from multiple processing cores using alternating processing to generate sequences of granted access requests to one or more memory banks. For each processing core, first and second buffers store access requests. When an access request from one buffer is granted, that buffer is configured to receive a new access request and processing is performed to determine whether to grant an access request stored in the other buffer. The invention can maintain optimal bandwidth while providing desired sequences of the granted access requests and solving physical congestion issues.

Abstract: One example discloses a power controller for a power device, wherein the power device includes a normal state, the power controller having: an input configured to receive fault detection signals attributable to the power device; an output configured to be coupled to the power device; and wherein the power controller is configured to send a state change signal over the output to change the normal state of the power device to a first fault state for a first time period in response to a first fault detection signal; and wherein the power controller is configured to send a state change signal over the output to change the first fault state of the power device to a second fault state for a second time period in response to a second fault detection signal.

Abstract: A communication device of a first wireless network determines that a first value of a first basic service set (BSS) color identifier is the same as a value of a second BSS color identifier corresponding to a neighboring second wireless network. In response, the communication device determines a second value of the first BSS color identifier. The communication device transmits one or more packets that each include i) an indication that the first BSS color identifier is changing, ii) the second value of the first BSS color identifier, and iii) a respective integer number of remaining beacon intervals corresponding to a start time when the second value of the first BSS color identifier will supersede the first value of the first BSS color identifier. Based on the start time, the communication device begins to use the second value of the first BSS color identifier with communications in the first wireless network.

Abstract: A communication device determines an identifier of a wireless network with which the communication device is not associated. While the communication device is not associated with the wireless network, the communication device participates in a ranging procedure with an access point (AP) of the wireless network. The ranging procedure is for estimating a distance between the communication device and the AP based on measuring times of flight of transmissions between the communication device and the AP. Participating in the ranging procedure includes: the communication device transmitting a packet to the AP as part of the ranging procedure. The packet includes a PHY preamble, and the PHY preamble includes a signal field. The signal field includes a wireless network identifier subfield set to the identifier of the wireless network.

Abstract: Embodiments of overvoltage protection devices and a method for operating an overvoltage protection device are disclosed. In an embodiment, an overvoltage protection device includes a switch circuit connected between an input terminal from which an input voltage is received and an output terminal from which an output voltage is output and including multiple NMOS transistors and multiple PMOS transistors connected in series between the input terminal and the output terminal, a first voltage generation circuit configured to, generate a first voltage that is applied to the NMOS transistors and a second voltage that is applied to a body of each of the PMOS transistors, in response to the input voltage and a supply voltage, and a second voltage generation circuit configured to generate a third voltage that is applied to the PMOS transistors in response to the input voltage and the first voltage.

Abstract: An inertial sensor includes a substrate, a movable element having an edge, and a suspension system retaining the movable element in spaced apart relationship above a surface of the substrate. The suspension system includes an anchor attached to the surface of the substrate, the anchor having a first side laterally spaced apart from the edge of the movable element, and a spring structure having a first attach point coupled to the first side of the anchor and a second attach point coupled to the edge of the movable element. The spring structure includes beam sections serially adjoining one another, the beam sections extending from the first side of the anchor and surrounding the anchor to couple to the edge of the movable element. The spring structure makes no more than one coil around the anchor to position the first attach point in proximity to the second attach point.

Abstract: One example discloses a near-field electromagnetic induction (NFEMI) device configured to be coupled to a non-planar conductive host surface, including: a coil antenna portion configured as a magnetic field antenna; and a conductive antenna surface configured as an electric field antenna; wherein the conductive antenna surface geometrically conforms to the non-planar host surface.

Abstract: The present disclosure may include, for example, a tunable capacitor having a decoder for generating a plurality of control signals, and an array of tunable switched capacitors comprising a plurality of fixed capacitors coupled to a plurality of switches. The plurality of switches can be controlled by the plurality of control signals to manage a tunable range of reactance of the array of tunable switched capacitors. Additionally, the array of tunable switched capacitors is adapted to have non-uniform quality (Q) factors. Additional embodiments are disclosed.

Abstract: A method for triggering and detecting a malicious circuit on an integrated circuit device is provided. A first run of test patterns is provided to logic circuits on the integrated circuit device. Each test pattern of the first run of test patterns includes a plurality of bits, a first portion of the plurality of bits being bits that do not influence a value of a resulting first test output vector, and a second portion of the plurality of bits being bits that will influence the value of the first test output vector. The value of the first test output vector is compared to first expected values. Bit values of the first portion of the plurality of bits for each test pattern of the first run of test patterns are changed to generate a second run of test patterns. The second run of test patterns is provided to the logic circuits on the integrated circuit device. A value of the second run of test patterns is compared to second expected values.

Abstract: There is described a method of determining an MRC coefficient vector for a RAKE receiver. The method comprises (a) estimating a channel impulse response vector, (b) estimating a noise variance vector, (c) calculating a multiplication factor vector based on the estimated channel impulse response vector and the estimated noise variance vector, (d) calculating a modified channel impulse response vector by multiplying each element in the estimated channel response vector with a corresponding element in the multiplication factor vector, and (e) calculating the MRC coefficient vector as the complex conjugate of the modified channel impulse response vector. There is also described a corresponding device, an UWB receiver, a computer program and a computer program product.

Abstract: A data processing system includes a monitoring system, the monitoring system includes a processor and a data analysis block. The processor executes a monitoring application for monitoring an operation of a monitored system coupled to the monitoring system. When assistance is needed from the monitored system, the processor has an output coupled to the monitored system for providing an assistance request. When the assistance request is sent to the monitored system, the processor also sends a disturbance indication to the data analysis block. The disturbance indication indicates that the output data from the monitored system may be disturbed by the assistance request. The data analysis block can then take an action to reduce the effect the disturbance may have on the analysis results. A method for monitoring the monitored system is also provided.

Abstract: A data processing system includes a plurality of subsystems, a plurality of local security controllers, and a central security controller. Each subsystem of the plurality of subsystems has a security component for providing a security function. A local security controller corresponds to each one of the subsystems. Each local security controller ensures compliance of the security component with local security policies of the subsystem to which the local security controller corresponds. The central security controller is coupled to the local security controller of each of the plurality of subsystems. The central security controller ensures data processing system compliance with system wide security policies. In the event of a detected security violation, the local security controller may respond automatically, without involvement of the central security controller. A method for securing the data processing system is also provided.

Abstract: In accordance with a first aspect of the present disclosure, a radio frequency identification (RFID) transponder is provided, comprising a modulator and a modulator controller, wherein the modulator is configured to generate a modulated signal to be transmitted to an external RFID reader, and wherein the modulator controller is configured to control a duty cycle of the modulator in dependence on an available amount of power. In accordance with a second aspect of the present disclosure, a method of operating a radio frequency identification (RFID) transponder is conceived, comprising: generating, by a modulator of the RFID transponder, a modulated signal to be transmitted to an external RFID reader; controlling, by a modulator controller of the RFID transponder, a duty cycle of the modulator in dependence on an available amount of power.

Abstract: The present application relates to an apparatus for verifying fragment processing related data and a method of operating thereof. The fragment shader unit is coupled to the at least one data buffer. A fragment shader unit of a graphics processing pipeline receives fragment data and records fragment processing related data in the at least one data buffer on processing one or more fragments in accordance with the received fragment data. A comparator unit coupled to the at least one data buffer compares the recorded fragment processing related data in the at least one data buffer to reference data and issues a fault indication signal in case the recorded fragment processing related data and the reference data mismatch.

Abstract: In some embodiments a method of manufacturing a sensor system can comprise forming a first structure having a substrate layer and a first sensor that is positioned on a first side of the substrate layer, bonding a cap structure over the first sensor on the first side of the substrate layer, and depositing a first dielectric layer over the cap structure. After bonding the cap structure and depositing the first dielectric layer, a second sensor is fabricated on the first dielectric layer. The second sensor includes material that would be adversely affected at a temperature that is used to bond the cap structure to the first side of the substrate layer.

Abstract: Various embodiments relate to a demodulator configured to receive a legacy signal and a secured signal using orthogonal frequency division multiplexing (OFDM) modulation, including: an analog to digital converter (ADC) configured to receive an OFDM modulated signal; an fast Fourier transform (FFT) unit configured to receive the output of the ADC; a frequency de-mapper configured to map the output of the FFT to legacy frame samples and secured signal samples including a secured hash; a sample to bit converter, a channel de-interleaver, and a channel decoder configured to process the legacy samples to produce a legacy frame; frame checking logic configured to check the validity of the legacy frame and produce a frame validity signal; a de-channelization module configured to convert the sample rate of secured signal samples; a channel decoder configured to decode the converted secured signal bits; a frame selector configured to select specific portions of the input legacy frame to produce a secured frame; a hash

Abstract: Various embodiments relate to a key protocol exchange that provide a simple but still secure key exchange protocol. Security of key exchange protocols has many aspects; providing and proving all these properties gets harder with more complex protocols. These security properties may include: perfect forward secrecy; forward deniability; key compromise impersonation resistance; security against unknown key share attack; explicit or implicit authentication; key confirmation; protocol is (session-)key independent; key separation (different keys for encryption and MACing); extendable, e.g., against DOS attacks; support of early messages; small communication footprint; and support of for public-key and/or password authentication.