Abstract: An RF power amplifier is described including a first amplifier and a second amplifier arranged in parallel between an RF power amplifier input and an RF power amplifier output. A phase adjuster adjusts the phase of a signal on at least one of the first amplifier signal path and the second amplifier signal path. A first impedance inverter has a first impedance inverter input coupled to an output of the second amplifier and a first impedance inverter output coupled to the RF power amplifier output. The RF power amplifier is configured to enable at least one of the first amplifier and the second amplifier dependent on an operation mode and the first impedance inverter is configured to modulate the load impedance of the second amplifier in response to the operation mode changing.

Abstract: An integrated circuit for hardware security comprises a voltage glitch detection processing system comprising an oscillator circuit that generates and outputs a local oscillator clock which is a function of a supply voltage; a counter clocked by the oscillator circuit to generate at least one count value; and a capture section that synchronizes the at least one count value into a system clock domain for detecting a voltage glitch in the supply voltage.

Abstract: An image processing circuit for correcting a distorted image includes an internal memory and a correction circuit. The internal memory of the image processing circuit is configured to store a radial look-up table (LUT), a set of tangential LUTs, and co-ordinates of a correction center of the distorted image. The radial LUT and the set of tangential LUTs include first and second sets of parameters to correct radial and tangential distortion of the distorted image, respectively. The correction circuit is configured to reconstruct portions of the correction LUT on-the-fly based on the radial LUT, the set of tangential LUTs, and the co-ordinates of the correction center, and correct portions of the distorted image based on the reconstructed portions of correction LUT to generate the portions of the corrected image.

Abstract: A Controller Area Network, CAN, transceiver configured to be connected to a CAN bus comprising; a transmitter arrangement configured to transmit signalling on the CAN bus based on transmit data, configured to operate in a first or second transmission mode, the first transmission mode configured to transmit said signalling with a first property and the second transmission mode configured to transmit said signalling with a second, different, property; a receiver arrangement configured to receive signalling from the CAN bus; a receive output configured to provide received data to the CAN controller; and wherein the transmitter arrangement is configured to operate in one of the first or second transmission modes based on a determination that the transmit data is encoded with a first line code and otherwise operate in the other transmission modes, and wherein the transceiver includes a decoder configured to decode the first line code of the transmit data.

Abstract: A communication system includes a network device including a plurality of communication ports and a plurality of communication nodes coupled with the network device through the plurality of communication ports. The communication system further includes a controller that is configured to generate a security key and to send a new configuration along with a message authentication code to the network device, wherein the controller is further configured to break the security key into parts and send the parts of the security key to at least some of the plurality of communication nodes such that each of the at least some of the plurality of communication node receiving one part of the parts of the security key. The network device is configured to retrieve the parts of the security key from the at least some of the plurality of communication nodes, to assemble the security key from the retrieved parts of the security key and using the assembled security key to authenticate the new configuration.

Abstract: Various embodiments relate to a free running oscillator, including: a voltage controlled oscillator circuit including an input configured to receive an input voltage and an output configured to provide an oscillation signal, wherein the input voltage controls a frequency of the oscillation signal; a frequency to voltage circuit including an input configured to receive the oscillation signal and an output configured to produce a voltage dependent on a frequency of the oscillation signal; a comparison circuit including an input and an output comprising: a first amplifier including a first input, a second input, and an output, wherein the output is based upon a difference in voltage between the first input and the second input, wherein the first input received one of a reference voltage and the output of frequency to voltage circuit; a second amplifier including a first input, a second input, and an output, wherein the output is based upon a difference in voltage between the first input and the second input, fir

Abstract: Various embodiments relate to a packaged radio frequency (RF) amplifier device implementing a split bondwire where the direct ground connection of an output capacitor is replaced with a set of bondwires connecting to ground in a direction opposite to the wires connecting to the output of a transistor to an output pad. This is done in order to reduce the effects of mutual inductance between the various bondwires associated with the output of the RF amplifier device.

Abstract: A wireless communication system (100) estimates a carrier frequency offset between wireless devices (101, 102) by configuring the devices through exchanging packet configuration packets (121, 125) to specify a carrier frequency offset fingerprint (CFOF) sequence in a measurement packet (133, 136) which is transmitted between the wireless devices, where the CFOF sequence in the measurement packet includes a prefix component (31), one or more signature segments (32), and a suffix component (33) for performing CFO measurements at the wireless devices which each process IQ samples corresponding to the signature segments in the received measurement packet by correlating the IQ samples against a reference vector to generate, for each of the one or more signature segments, a carrier frequency offset estimate between the first and second wireless devices.

Abstract: An integrated circuit (IC) includes a memory manager having a plurality of memory ports, each configured to communicate with a corresponding floating memory block. The IC includes a first interconnect for a first domain, wherein the first interconnect has a first set of fixed ports configured to communicate with memory blocks dedicated to the first domain and a first set of floating ports configured to communicate with the memory manager, and a second interconnect for a second domain, wherein the second interconnect has a second set of fixed ports configured to communicate with memory blocks dedicated to the second domain and a second set of floating ports configured to communicate with the memory manager. The memory manager is configured to allocate a first portion of the memory ports to the first set of floating ports and a second portion of the memory ports to the second set of floating ports.

Abstract: A method is provided for protecting a machine learning ensemble. In the method, a plurality of machine learning models is combined to form a machine learning ensemble. A plurality of data elements for training the machine learning ensemble is provided. The machine learning ensemble is trained using the plurality of data elements to produce a trained machine learning ensemble. During an inference operating phase, an input is received by the machine learning ensemble. A piecewise function is used to pseudo-randomly choose one of the plurality of machine learning models to provide an output in response to the input. The use of a piecewise function hides which machine learning model provided the output, making the machine learning ensemble more difficult to copy.

Abstract: Embodiments of a method and device are disclosed. In an embodiment, an in-vehicle network interface device includes a data port to send and receive data packets, a plurality of packet processing pipelines coupled to the data port, each to inspect a single data packet to determine an action to perform on the single data packet, and a safety module to receive the determined action from each packet processing pipeline and to select one of the determined actions to perform on the single data packet and to cause a selected one of the packet processing pipelines to perform the selected action.

Abstract: A mechanism is provided to maximize utilization of internal memory for packet queuing in network devices, while providing an effective use of both internal and external memory to achieve high performance, high buffering scalability, and minimizing power utilization. Embodiments initially store packet data received by the network device in queues supported by an internal memory. If internal memory utilization crosses a predetermined threshold, a background task performs memory reclamation by determining those queued packets that should be targeted for transfer to an external memory. Those selected queued packets are transferred to external memory and the internal memory is freed. Once the internal memory consumption drops below a threshold, the reclamation task stops.

Abstract: A method of forming a packaged semiconductor device includes attaching a backside surface of a semiconductor die to a major surface of a package substrate. A first conductive connector is formed over a portion of an active surface of the semiconductor die and a portion of the major surface of the package substrate. A first conductive connection between a first bond pad of the semiconductor die and a first substrate pad of the package substrate is formed by way of the first conductive connector. A bond wire connects a second bond pad of the semiconductor die to a second substrate pad of the package substrate. The first bond pad located between the second bond pad and an edge of the semiconductor die.

Abstract: An angular rate sensor includes first and second proof masses spaced apart from a surface of a substrate. One each of first and second drive systems is interconnected with one each of the first and second proof masses. The first and second drive systems enable drive motion of the first and second proof masses along both of first and second axes in an orbital drive direction at a drive frequency, the first axis being perpendicular to the surface of the substrate and the second axis being parallel to the surface of the substrate. The sensor is sensitive to angular velocity about a third axis oriented parallel to the surface of the substrate and perpendicular to the second axis, and the drive frequency of the drive motion of the first and second proof masses changes in response to the angular velocity of the angular rate sensor about the third axis.

Abstract: A proxy slave in a first LIN partition receives data from a proxy master in the second LIN partition which in turn receives the data from a slave in the second LIN partition. The proxy slave stores the data in a data structure and receives a read request from an originating master in the first LIN partition after the data is stored. The read request comprises a LIN message identifier subscribed to by the slave in the second LIN partition. The proxy slave accesses the data stored in the data structure based on the LIN message identifier in the read request; and sends a LIN response to the originating master with the stored data from the slave in the second LIN partition.

Abstract: A method for simultaneously communicating with multiple communication devices in a wireless local area network is described. Multiple uplink data units are received that are simultaneously transmitted by multiple second communication devices. The multiple uplink data units include a management data unit and a traffic data unit. An acknowledgment data unit is generated to acknowledge receipt of the multiple data units. The acknowledgment data unit includes (i) an indication that indicates that the acknowledgment data unit is intended for the multiple second communication devices, and (ii) respective acknowledgment information fields for the multiple second communication devices. The respective acknowledgment information fields include a first acknowledgment information field for the management data unit and a second acknowledgment information field for the traffic data unit.

Abstract: Some embodiments described herein provide a method for transmitting a preamble in accordance with a wireless local area network communication protocol. In some embodiments, a data frame may be obtained for transmission including a preamble compliant with the wireless local area network communication protocol. It may be determined that the preamble includes a first preamble portion that spans multiple symbol durations and a second preamble portion that spans a single symbol duration. The first preamble portion via beamforming may be transmitted based on a first beamforming matrix. When a transmission mode of the second preamble portion is beamforming, a second beamforming matrix may be generated based on the first beamforming matrix, each tone for the second preamble portion may be calculated based on the second beamforming matrix. Each calculated tone may be transmitted in accordance with the wireless local area network communication protocol.

Abstract: A method for transmitting a resource request for an uplink (UL) multi-user (MU) transmission is described. A High Throughput (HT) Control field that includes buffer information corresponding to media access control (MAC) protocol data units (MPDUs) that are queued for transmission by a first communication device is generated by the first communication device. The buffer information indicates a number of bytes for the MPDUs that are queued for transmission. A resource request MPDU that includes the HT Control field is generated by the first communication device. The resource request MPDU is transmitted by the first communication device to a second communication device via a wireless communication channel to request an allocation of radio resources for the UL MU transmission by the second communication device.

Abstract: An integrated circuit and a method of performing a built-in-self-test (BIST) procedure in an integrated circuit. The integrated circuit includes a plurality of radio circuits and a switching network for performing a built-in-self-test (BIST) procedure. The switching network includes a plurality of combiners, a plurality of transmitter connection switches, a combiner switch, a splitter switch, a plurality of splitters and a plurality of receiver connection switches. The switching network may also include a splitter bypass switch and/or a combiner bypass switch. The components of the switching network may operate to route signals between outputs and inputs of the radio circuit to implement the built-in-self-test procedure in one or more modes involving either parallel or sequential testing of the components of the radio circuits. A diagnostic mode is also envisaged.

Abstract: A semiconductor device package having galvanic isolation is provided. The semiconductor device package includes a package substrate having a first inductive coil. A first semiconductor die is attached to a first major surface of the package substrate. The first semiconductor die includes a second inductive coil substantially aligned with the first inductive coil. A second semiconductor die is attached to the first major surface of the package substrate. A wireless communication link between the first semiconductor die and the second semiconductor die is formed by way of the first and second inductive coils.