Abstract: An integrated circuit includes a functional core configured to execute functional logic instructions; a functional memory device coupled to the functional core; a safety core configured to execute safety check logic instructions; a monitored address memory device coupled to the functional core and the safety core, the monitored address memory device configured to store memory addresses to be monitored; and a first safety memory device coupled to the functional memory device and the safety core. When a value in one of the monitored memory addresses changes, the changed value of the one of the monitored memory addresses is stored in the functional memory device and in the first safety memory device. The safety core performs a safety check on the changed value of the one of the monitored memory addresses stored in the first safety memory device.

Abstract: A device includes a computer readable memory storing a plurality of one-time signature (OTS) keypairs and a processor that is configured to execute a hash function on a message using a first private key of a first OTS keypair of the plurality of OTS keypairs to determine a message signature, execute the hash function to calculate a leaf node value of a hash tree using the first OTS keypair, determine a plurality of authentication path nodes in the hash tree, retrieve, from the computer readable memory, values of a first subset of the plurality of authentication path nodes, calculate values for each node in a second subset of the plurality of authentication path nodes, and store, in the computer readable memory, the values for each node in the authentication path and the value of the leaf node.

Abstract: A system includes a first reset capture register configured to receive a plurality of reset signals, a last reset capture register configured to receive the plurality of reset signals, and a reset control circuit. The reset control circuit is configured to perform a startup procedure in response to assertion of a first reset signal of the plurality of rest signals. The startup procedure beings with a start state and ends in an active state in which the system operates in normal operation, and the first reset signal is asserted while the system is in the active state. The first reset capture register is configured to capture a first state of the plurality of reset signals in response to assertion of the first reset signal, and the last reset capture register is configured to capture a final state of the plurality of reset signals prior to completing the startup procedure.

Abstract: A phase shifted clock generator that includes a delay circuit, a capacitor, and a control circuit is provided. The delay circuit receives a reference clock signal and generates a phase shifted clock signal. A phase difference between the phase shifted clock signal and the reference clock signal is controlled based on a delay of the delay circuit. The control circuit controls, based on the phase shifted clock signal and the reference clock signal, a control voltage generated at the capacitor. The control circuit controls the control voltage by charging and discharging the capacitor with a constant current. The delay of the delay circuit is controlled based on the control voltage such that the phase difference between the phase shifted clock signal and the reference clock signal is within a predefined range.

Abstract: Various embodiments relate to a data processing system including instructions embodied in a non-transitory computer readable medium, the instructions for a cryptographic operation using masked coefficients of a polynomial having d arithmetic shares for lattice-based cryptography in a processor, the instructions, including: shifting an arithmetic share of the d arithmetic shares by a first bound ?0; converting the d shifted arithmetic shares to d Boolean shares; securely subtracting the first bound ?0 and a second bound ?1 from the Boolean shares to obtain z?B,k+1 having d shares, wherein k is the number of bits in the masked coefficients of the polynomial; setting the shares of a boundary check bit to a sign bit of z?B,k+1; and carrying out a cryptographic operation using the d arithmetic shares of the polynomial when the d shares of the boundary check bit indicate that the coefficients of the polynomial are within the first bound ?0 and second bound ?1.

Abstract: A memory built in self test (MBIST) controller of an MBIST circuit outputs first data. One or more errors is injected in the first data to produce second data. The second data is stored in the memory block. The memory block outputs the second data stored in the memory block. The MBIST controller receives the second data and detects an error in the second data based on a comparison with the first data, the error indicative of a failure of the MBIST. The MBIST controller provides an indication of failure of the MBIST to a processing core external to the MBIST circuit which performs diagnostic action in response to receiving the indication of failure of the MBIST. The processing core validates implementation of the diagnostic action.

Abstract: An amplifier includes a semiconductor die and a substrate that is distinct from the semiconductor die. The semiconductor die includes a first RF signal input terminal, a first RF signal output terminal, and a transistor. The transistor has a control terminal electrically coupled to the first RF signal input terminal, and a current-carrying terminal electrically coupled to the first RF signal output terminal. The substrate includes a second RF signal input terminal, a second RF signal output terminal, circuitry coupled between the second RF signal input terminal and the second RF signal output terminal, and an electrostatic discharge (ESD) protection circuit. The amplifier also includes a connection electrically coupled between the ESD protection circuit and the control terminal of the transistor. The substrate may be another semiconductor die (e.g., with a driver transistor and/or impedance matching circuitry) or an integrated passive device.

Abstract: An integrated circuit (IC) includes a memory that stores a thread and a processor that generates an instruction request to retrieve one or more instructions of the thread. The IC further includes an error control circuit that receives the instruction request from the processor and retrieves an instruction of the thread from the memory based on the instruction request. Further, the error control circuit determines whether the retrieved instruction is erroneous. Based on the determination that the retrieved instruction is erroneous, the error control circuit provides a substitute instruction to the processor as a response to the instruction request. The substitute instruction is included in an instruction set of the processor. The processor executes the received substitute instruction and suspends an execution of the thread.

Abstract: A system-on-chip (SoC) may include a plurality of terminals and a plurality of terminal controllers. Each terminal controller is configured to selectively disable a terminal. An SoC be configured to execute at least one application. An SoC may include a memory configured to store a plurality of terminal masks. Each terminal mask identifies a subset of the plurality of terminals to be disabled. An SoC may include a fault collection and reaction system configured to transmit, to the plurality of terminal controllers, a fault indication signal in response to an error in a corresponding application. Each terminal controller is further configured to determine, based on a fault indication signal and a value in a terminal mask, whether the terminal corresponding to the terminal controller is to be disabled, and when the terminal corresponding to the terminal controller is to be disabled, disable the terminal.

Abstract: A wireless communication system, apparatus, and methodology are described for enabling wireless communication station (STA) devices to generate a Physical Layer Protocol Data Unit (PPDU) that includes a resource unit (RU) having a size that is less than a spreading frequency block by using one or more predetermined pilot and/or data tone mapping plans to control how each pilot/data tone from the RU is distributed onto a disjoint set of pilot/data subcarriers forming a distributed RU included in the spreading frequency block, thereby accommodating transmission of wider bandwidth and multiple resource unit assignments in accordance with power spectrum density (PSD) limits provided for orthogonal frequency-division multiplexing (OFDM) modulated symbols supported by emerging 802.11 standards.

Abstract: Embodiments of a method and an apparatus for wireless communications are disclosed. In an embodiment, a method for wireless communications involves generating a packet for transmission to a user, where generating the packet includes: encoding user signaling parameters and setting a station-identification (STA-ID) of the user to a value, where the signaling parameters include a number of space time streams (nSTS) spatial streams, establishing a dummy user without changing the user signaling parameters, setting a STA-ID of the dummy user to a value that is different from the STA-ID value of the user, indicating the nSTS spatial streams that are allocated to the dummy user and that are to include Long Training Field (LTF) symbols, and transmitting the packet to the user with the LTF symbols.

Abstract: A device includes a semiconductor substrate, a source metallization over an active area of the semiconductor substrate, a through-substrate via electrically connected to the source metallization, and an input bond pad formed in the semiconductor substrate and spaced apart from the active area. The input bond pad is electrically connected to a set of gate structures. The device includes a first inductive coil over the semiconductor substrate between a first portion of the source metallization and a second portion of the source metallization and a first capacitor over the semiconductor substrate between the first portion of the source metallization and the second portion of the source metallization. The first inductive coil and the first capacitor are connected in series between the input bond pad and the through-substrate via.

Abstract: It is described an electronic device, comprising a secure element domain that further comprises: i) a physical memory region configured to store a plurality of data sets; and ii) a control device, coupled to the physical memory region, and configured to transfer at least one data set away from the physical memory region, wherein transferring the data set comprises at least one of: a) transferring the data set as a first data blob to a virtual memory region of the secure element domain; b) off-loading the data set as a second data blob to an external domain.

Abstract: One example discloses a communications device, including: an interface port, configured to couple the communications device to another device; a transmitter configured to transmit signals on the interface port; a receiver configured to receive signals on the interface port; and a switch configured to short the interface port to a reference potential after the transmitter transmits signals on the interface port.

Abstract: In a non-volatile memory (NVM) system of a memory device, a memory controller connected to memory cell arrays of the NVM system is configured to perform the steps of selecting a memory cell to test, energizing a test circuit connected to the memory cell under a first biasing condition, reading a measurement of an electrical property of the memory cell, and determining, based on the measurement, whether the memory cell is formed or unformed. In embodiments, the system and method include protecting the test circuit from attack by validating the results of the testing. The memory controller is further configured to energize the test circuit under a second biasing condition that produces a known test result whether the memory cell is formed or unformed; if the result of the second test is not the expected result, the memory controller determines that the testing circuit is malfunctioning or under attack.

Abstract: One example discloses a sensor calibration circuit, including: a controller configured to transmit a first modulation signal to the sensor and receive a first output signal from the sensor in response; wherein the controller configured to transmit a second modulation signal to the sensor and receive a second output signal from the sensor in response; and wherein the controller is configured to calibrate the sensor based on the first and second modulation signals and the first and second output signals.

Abstract: An RF amplifier includes an amplifier input, a transistor die with a transistor and a transistor input terminal, a fundamental frequency impedance matching circuit coupled between the amplifier input and the transistor input terminal, and a harmonic frequency termination circuit coupled between the transistor input terminal and a ground reference node. The harmonic frequency termination circuit includes a first inductance coupled between the transistor input terminal and a first node, and a tank circuit coupled between the first node and the ground reference node. The tank circuit includes a first capacitance coupled between the first node and the ground reference node, and a second inductance coupled between the first node and the ground reference node. The tank circuit is configured to shunt signal energy at or near a second harmonic frequency, while appearing as an open circuit to signal energy at a fundamental frequency of operation of the RF amplifier.

Abstract: A multiple-input multiple-output (MIMO) antenna system for a mobile cellular network and method is described. The MIMO antenna system includes an array of dual-polarization patch antennas each having first and second polarization feed-points, a first polarization radio chain and a second polarization radio chain. The MIMO antenna system includes a beamformer coupled to the first and second polarization radio chains. The beamformer includes a beamformer channel for a respective feedpoint and further includes a transmit amplifier and a detector (coupler) coupled to a transmit amplifier output. In one mode of operation, a signal is transmitted via the first polarization feed-point of a dual-polarisation patch antennas and a replica of the transmitted signal may be sensed using the coupler at the output of the transmit amplifier and routed via the second polarization radio chain to a digital predistortion module.

Abstract: Power transmission associated with wireless charging of a battery of an electronic device or powering of the electronic device comprises determining a power loss associated with transmitting a power signal having a transmitted power from the wireless power transmitter to a wireless power receiver. A closed loop power loss control based on the power loss is performed which comprises outputting a target transmit power to meet a power loss limit. The power signal having the target transmit power is wirelessly transmitted to the wireless power receiver to charge the battery of the electronic device or power the electronic device and balance charging performance and safety.

Abstract: Placement of a field plate in a field-effect transistor is optimized by using multiple dielectric layers such that a first end of field plate is separated from a channel region of the transistor by a first set of one or more distinct dielectric material layers. A second end of the field plate overlies the channel region and a control electrode from which it is separated by the first set of dielectric layers and one or more additional dielectric layers.