Abstract: Polyphase gm-C filters can use matching gm cell components for improved higher image rejection results. Polyphase gm-C filter cells all can be matched by incorporating a matching gmu value in each of the gm components. The matching gmu value used to replace different gm values can be determined for incorporation into each gm cell component of a filter by: calculating coupling of gmi, gmij by gmi=Ci?0 and gmij=Czij?0 for i,j; calculating Ki=gmi/gmu; rounding Ki to an integer number, Ni=round(Ki), KiNi and Nij=round(Kij), KijNij; calculating a scaling factor for circuit capacitors Ci and Czijby ?i=(Ni?Ki)/Ki and ?ij=(Nij?Kij)/Kij; and adjusting circuit capacitors Ci and Czij by CiCi*(1+?i) and CzijCzij*(1+?ij). Once the process is completed for i,j, the result can be implemented to match gm cell components of traditional and newly designed polyphase gm-C filters with the matching gmu value.

Abstract: A wheel speed sensor interface receives an analog signal from a wheel speed sensor and converts the analog signal to a digital wheel speed sensor output signal. A detector circuit is configured to detect a transient occurring within a voltage source powering the wheel speed sensor, and compensate the digital wheel speed sensor output signal as a function of the detection of the transient so that it is an accurate representation of a wheel speed detected by the wheel speed sensor. The detector circuit includes a current mirror coupled to the voltage source, and outputs a compensation current to a current comparator of the wheel speed sensor interface.

Abstract: An embodiment of a module (e.g., an amplifier module) includes a substrate, a transmission line, and a ground plane height variation structure. The substrate is formed from a plurality of dielectric material layers, and has a mounting surface and a second surface opposite the mounting surface. A plurality of non-overlapping zones is defined at the mounting surface. The transmission line is coupled to the substrate and is located within a first zone of the plurality of non-overlapping zones. The ground plane height variation structure extends from the second surface into the substrate within the first zone. The ground plane height variation structure underlies the transmission line, a portion of the substrate is present between the upper boundary and the transmission line, and the ground plane height variation structure includes a conductive path between an upper boundary of the ground plane height variation structure and the second surface.

Abstract: An electrostatic discharge protection device includes a substrate, first and second emitter regions disposed in the substrate, laterally spaced from one another on a side of the substrate, and having opposite conductivity types, and first and second base regions having opposite conductivity types and in which the first and second emitter regions are disposed in a thyristor arrangement, respectively. The first base region includes a buried doped layer that extends under the second base region. Each of the buried doped layer and the second base region includes a respective non-uniformity in dopant concentration profile. A spacing between the buried doped layer and the second base region at the respective non-uniformities establishes a breakdown trigger voltage for the thyristor arrangement.

Abstract: Upon receiving a request (203) in an initiator interface protocol identifying information to be returned in-order, an integrated circuit protocol bridge circuit device (200) allocates, to the ordered request, entries in a first ordered queue (e.g., 211) and a first static queue (e.g., 213) for the initiator interface protocol, generates a plurality of split target requests in a target interface protocol from the ordered request, and allocates the plurality of split target requests to entries in a second ordered queue (e.g., 217) and a second static queue (e.g., 218) for the target interface protocol, so that, upon receiving a plurality of out-of-order target responses, an allocated entry in the first ordered queue (211) for the first ordered initiator request is deleted only after a plurality of counter fields in the first static queue indicate that target responses have been received for all of the plurality of split target requests.

Abstract: A method, apparatus, article of manufacture, and system are provided for detecting hardware faults on a multi-core integrated circuit device by executing runtime software-based self-test code concurrently on multiple processor cores to generate a first set of self-test results from a first processor core and a second set of self-test results from a second processor core; performing mutual inter-core checking of the self-test results by using the first processor core to check the second set of self-test results from the second processor core while simultaneously using the second processor core to check the first set of self-test results from the first processor core; and then using the second processor core to immediately execute a recovery mechanism for the first processor core if comparison of the first set of self-test results against reference test results indicates there is a hardware failure at the first processor core.

Abstract: A processing system includes a first processor configured to issue a first request in a first format, an adapter configured to receive the first request in the first format and send the first request in a second format, and a memory coherency interconnect configured to receive the first request in the second format and determine whether the first request in the second format is for a translation lookaside buffer (TLB) operation or a non-TLB operation based on information in the first request in the second format. When the first request in the second format is for a TLB operation, the interconnect routes the first request in the second format to a TLB global ordering point (GOP). When the first request in the second format is not for a TLB operation, the interconnect routes the first request in the second format to a non-TLB GOP.

Abstract: A heterogeneous multi-processor device having a first processor component arranged to issue a data access command request, a second processor component arranged to execute a set of threads, a task scheduling component arranged to schedule the execution of threads by the second processor component, and an internal memory component. In response to the data access command request being issued by the first processor component, the task scheduling component is arranged to wait for activities relating to the indicated subset of threads to finish, and when the activities relating to the indicated subset of threads have finished to load a command thread for execution by the second processor component, the command thread being arranged to cause the second processor component to read the indicated data from the at least one region of memory and make the read data available to the first processor component.

Abstract: An integrated circuit including a segmented successive approximation register (SAR) analog-to-digital converter (ADC) includes a first capacitive structure with a first plurality of capacitive structure subcomponents that each include a first terminal selectively connected to one of a plurality of input voltage nodes and a second terminal connected to a common conductor, and second capacitive structure with a second plurality of capacitive structure subcomponents that each include a first terminal selectively connected to one of the plurality of input voltage nodes and a second terminal connected to the common conductor. The first and second plurality of capacitive structure subcomponents are arranged in an array in which none of the first plurality of capacitive structure subcomponents are directly adjacent to one another and none of the second plurality of capacitive structure subcomponents are directly adjacent to one another in a first row in the array.

Abstract: A transistor includes an active region bounded by an outer periphery and formed in a substrate. The active region includes sets of input fingers, output fingers, and common fingers disposed within the substrate and oriented substantially parallel to one another. The transistor further includes an input port, an output port, a first via connection disposed at the outer periphery of the active region proximate the input port and a second via connection disposed at the outer periphery of the active region proximate the output port. The second via connection has a noncircular cross-section with a second major axis and a second minor axis, the second major axis having a second major axis length, the second minor axis having a second minor axis length that is less than the second major axis length. The second major axis is oriented parallel to a longitudinal dimension of the input, output, and common fingers.

Abstract: Embodiments of a method and a device are disclosed. In an embodiment, a method for power factor correction (PFC) at a switched mode power supply (SMPS) is disclosed. The method involves receiving an input voltage, generating a reference waveform that is in phase with the input voltage, determining a time value for phase-shifting a PFC current signal, scaling the time value with a phase factor to generate a scaled time value, phase-shifting the reference waveform according to the scaled time value to generate a phase-shifted reference waveform, and generating the PFC current signal based on the phase-shifted reference waveform.

Abstract: A sub-ranging analog-to-digital converter (ADC) converts an analog input signal to a digital output signal. The sub-ranging ADC includes a coarse ADC, a fine ADC, and an error correction circuit (ECC). The fine ADC includes at least three digital-to-analog converters (DACs) that are connected in a pipeline architecture. The coarse and fine ADCs receive the analog input signal in a first half cycle of a clock signal. The coarse ADC converts the analog input signal to a first digital signal in a second half cycle of the clock signal. At least one of the first through third DACs converts the analog input signal to a second digital signal in a full cycle of the clock signal. The ECC receives the first and second digital signals and generates the digital output signal.

Abstract: A method for implementing a pseudo-random function (PRF) using a white-box implementation of a cryptographic function in N rounds, including: receiving an input to the PRF; receiving a cryptographic key in a first round; encrypting, using the white-box implementation of the cryptographic function and the cryptographic key, an input message that is one of M possible input messages based upon a portion of the input to produce a first output; for each succeeding round: encrypting, using the white-box implementation of the cryptographic function and an ith cryptographic key, further input messages that are one of M possible input messages based upon a further portion of the input to produce an ith output, wherein the ith cryptographic key is the output from the preceding round, wherein the white-box implementation of the cryptographic function only produces a correct output for the M possible input messages and produces an incorrect output for input messages that are not one of the M possible input messages.

Abstract: Aspects of the present disclosure involving tuning clock signal sources for communication. As may be implemented in accordance with one or more embodiments, trustworthiness of a message or a source of the message is validated, as indicated by data received over a data bus that communicatively couples a plurality of circuits respectively including an independent clock signal source. Data sent between the circuits can be received by adaptively sampling data that is carried by the data bus. Timing information is calculated relative to data frames of the data received over the data bus, and a clock signal source at one of the circuits is tuned in response to the validating and the calculating.

Abstract: An embodiment of an amplifier includes a first amplifier with a first output terminal, a second amplifier with a second output terminal, and a plurality of microstrip transmission lines electrically connected to the amplifiers. The transmission lines include an impedance inverter line electrically connected between the first and second output terminals, and an output line electrically connected between the second output terminal and an output of the amplifier, where the output line forms a portion of an output impedance transformer. The amplifier also includes a directional coupler formed from a main line and a coupled line positioned in proximity to the main line, where the main line is formed from a portion of one of the transmission lines. The amplifier may also include a module substrate with a plurality of metal layers, where the main line and the coupled line are formed from different portions of the metal layers.

Abstract: A low drop out, LDO, voltage regulator circuit is that includes a high gain amplifier configured to receive a current biasing signal and arranged to regulate the voltage supply signal and output a regulated voltage supply signal. A regulation adjustment circuit is operably coupled to an output of the high gain amplifier and includes a comparator configured to compare the output regulated voltage supply signal with a threshold, wherein an output of the comparator is configured to perform one of: (i) supply a dynamic current boost to the LDO current biasing signal, in response to the regulated voltage supply signal voltage dropping below the threshold; (ii) activate a dynamic current pull down circuit to reduce an over voltage output of the LDO voltage regulator circuit in response to the regulated voltage supply signal voltage exceeding the threshold.

Abstract: A front end for a radar system and method of operation are described. A timing circuit controls operation of a transmitter circuit and a receiver circuit and outputs a valid data signal indicating whether the receiver circuit will be receiving a reflected radar signal. A converter converts a received radar signal and outputs digital data. A serialising circuit receives the digital data and supplies a serial data stream including the digital data for a data processing device. The valid data signal is also communicated to the converter to cause the converter to output a bit pattern corresponding to a code word when the valid data signals indicates that the receiver circuit will not be receiving the reflected radar signal and to output a bit pattern corresponding to a data word including radar data when the valid data signals indicates that the receiver circuit will be receiving the reflected radar signal.

Abstract: Verifying a device under test (DUT) in which the DUT includes a bridge with a late write buffer includes storing write requests provided to the bridge in an initiator queue, and storing write requests provided to the target memory in a target queue. Upon both the initiator and target queues being non-empty, when entry addresses of top entries of the initiator and target queue match, data entries of the top entries of the initiator and target queue do not match, and the initiator queue has more than one entry, determining whether an entry address of a next entry in the initiator queue matches the entry address of the top entry in the initiator queue, and when the entry addresses of the next entry and the top entry in the initiator queue match, merging the top and next entry of the initiator queue and deleting the top entry of initiator queue.

Abstract: An integrated circuit delay cell includes an input circuit to establish a current level in the circuit, a switch configured to control an on/off time of a delay circuit, a delay circuit including at least one current starved stage configured to mirror the current level, the delay circuit configured to control a speed of a rise and/or fall time of an output signal, and a glitch discharging circuit connected to the delay circuit configured to tolerate and discharge unwanted charge of the delay circuit.

Abstract: An electronic device is described that includes: a host processor comprising at least one input port configured to receive a plurality of data signals on a plurality of virtual channels; and a memory operably coupled to the host processor and configured to receive and store data. The host processor is configured to enable and disable individual virtual channels from the plurality of virtual channels and is configured to only store data in memory associated with enabled virtual channels, and discard data from disabled channels.