Abstract: A dead band compensation system is provided that provides dead time compensation for a three-phase inverter in connection with counting the time difference between a pulse width without a dead time interval and a pulse width available at the output of the inverter (100). An error measurement is determined, a portion of which is fed back subsequently. Harmonic components, among other things, are reduced, to an extent, in the load current through an inverter load (120). Further, compensation for inverter voltage output errors may be provided.

Abstract: A circuit includes a serializer module that includes an input stage that samples an input signal to capture an edge location for each of the input signal in a given time frame. An edge encoder encodes the edge location for the input signal into a packet frame to specify where the edge location occurs in the given time frame for the input signal. A transmitter receives the packet frame from the edge decoder and converts the packet frame into a serial data stream. The transmitter communicates the edge location for the input signal via the serial data stream.

Abstract: A voltage reference circuit includes a bandgap circuit and a temperature compensation circuit. The temperature compensation circuit includes a first trim circuit, a second trim circuit, and a resistive digital-to-analog converter. The resistive digital-to-analog converter is coupled to the first trim circuit, the second trim circuit, and the bandgap circuit. The resistive digital-to-analog converter is configured to generate a temperature compensation voltage, and to provide the temperature compensation voltage to the bandgap circuit.

Abstract: In described examples, a first die includes a primary LC tank oscillator having a natural frequency of oscillation to induce a forced oscillation in a secondary LC tank oscillator of a separate second die via a magnetic coupling between the primary LC tank oscillator and the secondary LC tank oscillator.

Abstract: Methods and apparatus providing a smooth transition from a pulse width modulation mode to a linear mode to drive a voice coil motor are disclosed. An example apparatus includes an H-bridge; a pulse generator to generate a pulse when the voice coil motor driver transitions from pulse width modulation mode to linear mode; a first boost circuit to, when the pulse is generated, increase a first current being applied to a first gate of a first transistor in the H-bridge, the increase in the first current enabling the first transistor; and a second boost circuit to, when the pulse is generated, provide an additional path to ground from a node coupled to a second gate of a second transistor of the H bridge, the path to ground corresponding to a voltage drop that disables the second transistor.

Abstract: Methods for depositing a measured amount of a species in a sealed cavity. In one example, a method for depositing molecules in a sealed cavity includes depositing a selected number of microcapsules in a cavity. Each of the microcapsules contains a predetermined amount of a first fluid. The cavity is sealed after the microcapsules are deposited. After the cavity is sealed the microcapsules are ruptured to release molecules of the first fluid into the cavity.

Abstract: An IC includes logic groups each including a launch and a capture FF with a logic cloud in between. A power switch is in series with a power supply node of the logic groups. The logic groups have a clock-gating and power control (PCGC) block for dynamically generating a power supply enable (PS_EN) signal output coupled to a control node of the power switch and a clock output (CLK_OUT) signal coupled to a clock input of the launch or capture FF for clocking the logic groups. The PCGC blocks receive an EN signal and a CLK_IN signal and dynamically generate the PS_EN signal and CLK_OUT signals. During clock cycles at least one logic group(s) does not contribute to an intended logic result for the IC the CLK_OUT signal disables switching of at least a portion of the logic group(s) while the PS_EN signal turns off power to the logic group(s).

Abstract: A duty cycle correction circuit includes a charge pump and a controller. The charge pump includes a current source, a first output, and a second output. The charge pump routes current from the current source to the first output during a positive portion of a clock, and routes current from the current source to the second output during a negative portion of the clock. The controller compares charge accumulated from the first output to charge accumulated from the second output over a plurality of clock cycles to determine which of the positive portion of the clock and the negative portion of the clock is longer. The controller also generates a digital value that indicates an amount of adjustment to apply to a duty cycle of the clock based on which of the positive portion of the clock and the negative portion of the clock is longer.

Abstract: Methods, apparatus, systems, and articles of manufacture are disclosed for cross-conduction detection. An example apparatus includes a cross detector circuit including a first transistor and a second transistor, the first transistor coupled to a load, a third transistor coupled to a first controlled delay circuit and the first transistor, a fourth transistor coupled to a second controlled delay circuit and to the third transistor at a phase node, and a control circuit coupled to the first controlled delay circuit, the second controlled delay circuit, and the load.

Abstract: A touch sensor mounting assembly includes a carrier with a front-side surface for attaching a touch sensor circuit (such as a flex circuit board), and a back-side spring structure. The touch sensor mounting assembly can be used for mounting at least one touch sensor in a device case with at least on touch button area defined on a surface of the device case. The touch sensor mounting assembly can include a carrier including a front-side sensor-attach surface, and a back-side spring structure including at least two spring arms integral with the carrier. Touch sensor circuitry can be mounted on the front-side sensor-attach surface of the carrier, such that when, the touch sensor mounting assembly is installed in the device case adjacent the at least one touch button area, the back-side spring arms are flexed to urge the carrier with front-side mounted touch sensor circuitry toward an interior side of the touch button area of the device case.

Abstract: Systems and methods are provided for performing a dot product. Each of a first series of numbers is divided into a first value, comprising the N most significant bits of the number, and a second value to form first and second sets of values. Each of a second series of numbers is divided into a third value, comprising the N most significant bits of the number, and a fourth value to form third and fourth sets of values. A dot product of the first and fourth sets of values is computed to provide a first partial sum. A dot product of the first and third sets of values is computed to provide a second partial sum. A dot product of the second and third sets of values is computed to provide a third partial sum. The partial sums are summed to provide a result for the dot product.

Abstract: A system includes a ferroelectric random access memory (FRAM) array having one or more memory elements. A cycle controller cycles data to be fixed in a subset of the one or more memory elements by reading or writing the data a predetermined number of times to fix the data to a non-volatile stable state.

Abstract: This disclosure describes die test architectures that can be implemented in a first, middle and last die of a die stack. The die test architectures are mainly the same, but for the exceptions mentioned in this disclosure.

Abstract: In described examples, an electronic circuit for delaying a signal (received at an input node) includes a delay line with multiple tap locations, a tap line proximate to the delay line and coupled to an output node, and multiple groups of switches. Switches in the groups of switches are severally coupled between tap locations corresponding to the respective group of switches, and the tap line. When the signal is propagated through the delay line, a first number of the switches corresponding to a selected tap location are closed, a second number of the switches corresponding to an adjacent tap location are closed, and the signal is transmitted with a delay through the closed switches, to the tap line, to the output node. The delay includes an average, weighted using the first and second numbers, of delays corresponding to the selected and adjacent tap locations.

Abstract: An integrated circuit including a ferroelectric random access memory (FRAM) for storing firmware, and a method of updating that firmware. The FRAM is constructed to selectively operate as a 2T2C FRAM memory in a normal operating mode, and as a 1T1C FRAM memory in an update mode. Updating of the stored firmware is performed by placing the FRAM in its update (1T1C) mode and writing the updated code into alternate rows of the 1T1C half-cells at each of a plurality of memory locations, while the other 1T1C half-cells in the other alternate rows retain the original data. Following verification of the updated contents, the original data in the other half-cells are overwritten with the verified updated data, and the operating mode is changed back to the normal (2T2C) operating mode.

Abstract: This disclosure generally relates to USB TYPE-C, and, in particular, DISPLAYPORT Alternate Mode communication in a USB TYPE-C environment. In one embodiment, a device determines a DISPLAYPORT mode and determines an orientation of a USB TYPE-C connector plug. A multiplexer multiplexes a DISPLAYPORT transmission based in part on the determined orientation of the USB TYPE-C connector plug.

Abstract: In one embodiment, a method includes receiving an output of a first combinational logic at an enable terminal of a first flip-flop. The first combinational logic inputs include a disable first clock signal from a clock switchover circuit and a disable second clock signal from the clock switchover circuit. A set terminal of the first flip-flop receives an output of a logic gate, and the logic gate receives a select signal and a first clock signal. An input terminal of the first flip-flop receives, an output of a second flip-flop. A reset terminal of the first flip-flop receives an output of a second combinational logic. The second combinational logic inputs include a first clock stopped signal, a power-on-reset signal, and the select signal, the first clock stopped signal indicating a stop in the first clock signal. An output terminal of the first flip-flop outputs a modified select signal.

Abstract: A method and system includes receiving, at a computing device including a design tool application, design parameters indicative of a plurality of power supply loads to be powered. The method further includes generating power supply solutions that do not include multi-channel voltage regulators and generating power supply solutions that do include multi-channel voltage regulators. The method also includes ranking all power supply solutions and providing the ranked power supply solutions to a user.

Abstract: Described examples provide integrated circuits and methods, including forming a conductive seed layer at least partially above a conductive feature of a wafer, forming a conductive structure on at least a portion of the conductive seed layer, performing a printing process that forms a polymer material on a side of the wafer proximate a side of the conductive structure, curing the deposited polymer material, and attaching a solder ball structure to a side of the conductive structure.

Abstract: A semiconductor device contains a vertical MOS transistor having a trench gate in trenches extending through a vertical drift region to a drain region. The trenches have field plates under the gate; the field plates are adjacent to the drift region and have a plurality of segments. A dielectric liner in the trenches separating the field plates from the drift region has a thickness great than a gate dielectric layer between the gate and the body. The dielectric liner is thicker on a lower segment of the field plate, at a bottom of the trenches, than an upper segment, immediately under the gate. The trench gate may be electrically isolated from the field plates, or may be connected to the upper segment. The segments of the field plates may be electrically isolated from each other or may be connected to each other in the trenches.