Abstract: Techniques to perform bandgap circuit trimming that maximize the operating range and minimize the trimming time at which the bandgap will be accurate. A bandgap circuit output voltage may be trimmed by heating the circuit, supplying increasing input power to the bandgap circuit, and adjusting operational parameters of the bandgap circuit to generate a constant bandgap circuit output voltage. When the bandgap circuit output voltage may remain constant, a constant input power may be applied to the bandgap circuit and its output voltage may be adjusted to a predetermined voltage level.

Abstract: A circuit for expanding a dynamic range. In one embodiment, the circuit includes: a transducer generating a signal current on an output terminal in response to a physical quantity, the signal current comprising an AC current and a DC current; a dynamic range enhancement circuit having a digital control signal input terminal and producing a variable opposition current in response to a digital signal applied to the digital control signal input terminal; an amplifier; an analog to digital converter in electrical communication with the amplifier; and a digital feedback circuit in communication with the output terminal of the analog to digital converter and in electrical communication with the digital control signal input terminal of the dynamic range enhancement circuit, wherein the opposition current from the dynamic range enhancement circuit is set substantially equal to the DC current portion of the signal current from the transducer.

Abstract: A composite resistor includes a thin film resistor element having a first temperature coefficient of resistance and a metal resistor element having a second temperature coefficient of resistance. A portion of the metal resistor element overlaps a portion of the thin film resistor element such that the portion of the metal resistor element is in thermal communication with the portion of the thin film resistor element to compensate for a resistance drift arising during operation of the composite resistor.

Abstract: An amplifier system has an amplifier for amplifying a plurality of input signals from a plurality of different channels, and a plurality of demodulators each operatively coupled with the amplifier for receiving amplified input signals from the amplifier. Each demodulator is configured to demodulate a single amplified input channel signal from a single channel of the plurality of different channels. The system thus also has a plurality of filters, coupled with each of the demodulators, for mitigating the noise.

Abstract: Aging effects on devices fabricated using deep nanometer complementary metal-oxide semiconductor (CMOS) processes can cause circuits to exhibit an undesirable mismatch buildup over time. To address the aging effects, the connections to an array of M differential circuits are controlled to limit and systematically minimize or reverse the aging effects. In one embodiment, the controlling permutation sequence is selected to stress the array of M differential circuits under opposite stress conditions during at least two different time periods. Imposing opposite stress conditions, preferably substantially equal opposite stress conditions, can reverse the direction of a mismatch buildup and limit the mismatch buildup over time within acceptable limits. The controlling permutation sequence can be applied to an array of comparators of an analog-to-digital converter, or an array of differential amplifiers of a folding analog-to-digital converter.

Abstract: A system is provided for updated processing of audio signals in a vehicle. The system includes a microphone, a transceiver and head unit. The microphone receives audio signals. The transceiver sends the received audio signals to a cloud computing system for processing, and receives the processed audio signals from the cloud computing system. The head unit receives the processed audio signals from the transceiver and plays the processed audio data through the vehicle's audio system.

Abstract: A circuit, system, machine-readable storage medium and method for detecting the leakage impedance in a voltage source is described. The method for identifying a presence of a leakage path in a multi-cell floating voltage source may include supplying a current to a node of the floating voltage source and sampling the voltage of the floating voltage source using a pair of amplifiers connecting in inverting configurations. The method may include sampling a reference ground potential using a reference amplifier connected in an inverting configuration. Each of the amplifiers may output an output signal. The method may include adjusting the current supplied to the node of the floating voltage source and resampling the voltage of the floating voltage source and the reference ground potential. The value of the leakage impedance may be calculated using the sampled and resampled values. The measurements may be performed independent of the battery voltage.

Abstract: Analog-to-digital converters (ADCs) can have errors which can affect their performance. To improve the performance, many techniques have been used to compensate or correct for the errors. When the ADCs are being implemented with sub-micron technology, ADCs can be readily and easily equipped with an on-chip microprocessor for performing a variety of digital functions. The on-chip microprocessor and any suitable digital circuitry can implement functions for reducing those errors, enabling certain undesirable artifacts to be reduced, and providing a flexible platform for a highly configurable ADC. The on-chip microprocessor is particularly useful for a randomized time-interleaved ADC. Moreover, a randomly sampling ADC can be added in parallel to a main ADC for calibration purposes. Furthermore, the overall system can include an efficient implementation for correcting errors in an ADC.

Abstract: An embodiment of a power supply circuit to generate a supply voltage for a gate driver circuit can include an isolated power supply circuit to receive a first voltage in a first isolated system and provide power to a cyclic charging power supply circuit, the cyclic charging power supply circuit providing a supply voltage to the gate driver circuit in a second isolated system, the isolated power supply circuit providing the power to the cyclic charging power supply circuit while the gate driver circuit drives a transistor in an on state. The isolated power supply circuit can include a control circuit to regulate the power provided to maintain or increase the supply voltage while the gate driver circuit drives the transistor in an on state. The power supply circuit can also include the cyclic charging power supply circuit to receive a second voltage in the second isolated system and provide the supply voltage to the gate driver circuit.

Abstract: An apparatus including an electrostatic discharge (ESD) protection device comprising a semiconductor having first, second and third regions arranged to form a transistor, wherein the first region is doped with a first impurity of a first conductivity type and is separated from the second region which is doped with a second impurity of a second conductivity type opposite the first type, and wherein a dimensional constraint of the regions defines an operational threshold of the ESD protection device. In one example, the separation between a collector and an emitter of a bipolar transistor defines a trigger voltage to cause the electrostatic discharge protection device to become conducting. In another example, a width of a bipolar transistor base controls a holding voltage of the electrostatic discharge protection device.

Abstract: A die is packaged by flip-chip mounting the die with the active side facing a low loss substrate. A ground plane is coupled to the active side of the die by vias through the low loss substrate. The ground plane is positioned to concentrate high frequency electromagnetic fields in the low loss substrate. A tuning height can be adjusted to tune the center frequency of a circuit in the die.

Abstract: Heart rate monitors are plagued by noisy photoplethysmography (PPG) data, which makes it difficult for the monitors to output a consistently accurate heart rate reading. Noise is often caused by motion. Using known methods for processing accelerometer readings that measure movement to filter out some of this noise may help, but not always. The present disclosure describes an improved filtering approach, referred to herein as an iterative frequency-domain mask estimation technique, based on using frequency-domain representation (e.g. STFT) of PPG data and accelerometer data for each accelerometer channel to generate filters for filtering the PPG signal from motion-related artifacts prior to tracking frequency of the heartbeat (heart rate). Implementing this technique leads to more accurate heart rate measurements.

Abstract: Embodiments of the present invention provide an integrated circuit system including a first active layer fabricated on a front side of a semiconductor die and a second pre-fabricated layer on a back side of the semiconductor die and having electrical components embodied therein, wherein the electrical components include at least one discrete passive component. The integrated circuit system also includes at least one electrical path coupling the first active layer and the second pre-fabricated layer.

Abstract: Embodiments of the present invention may provide a battery monitor for a battery system that avoids current loops. A battery monitor may be provisioned as an integrated circuit and may include a pair of supply pins for reception of power to the integrated circuit, a third high impedance pin, and a voltage regulation circuit. When the circuits are deployed, the supply pins of several battery monitors may be connected to each other to form a stack. The high impedance inputs of each battery monitor may be coupled to low voltage terminals of an associated battery cell. A voltage reference circuit within the battery monitor may maintain the voltage at a low voltage supply of the monitors at a level that matches the voltage present on the high impedance input. Thus, the voltages on the monitors' low voltage supplies may be regulated. As a result, no current should flow through the high impedance pins of the battery monitor.

Abstract: Disclosed herein are systems for calibrating an analog-to-digital converter (ADC) device, as well as related devices and methods. In some embodiments, a system for calibrating an ADC device may include an ADC device, wherein the ADC device includes an ADC and a dither source, and wherein the ADC device is to apply a set of calibration parameters to generate digital outputs. The system may also include calibration circuitry, coupled to the ADC device, to determine which of multiple sets of values of calibration parameters results in the digital outputs having the lowest amount of noise, and to cause the ADC device to apply the calibration parameters associated with the lowest noise.

Abstract: An accelerometer or other motion sensor is used to provide power to an entire processor system such that the processor does not need to be powered to process the motion signals for initial power-on control. After the processor system is powered on, the processor system may receive and process motion signals as normal, including, for example, performing various power-control functions such as power-down of certain components or the entire system upon detection of a lack of motion for a predetermined amount of time.

Abstract: Speakers do not always operate linearly. Linearity of the speaker can affect the quality of the sound produced by the speaker, i.e., causing distortions in the sound, if the nonlinearites are not accounted for. To determine nonlinearities of the speaker, the speaker is often modeled and measurements are made to estimate the characteristics of the speaker based on the model. By using an angle sensor and a light source, a speaker manager can make a direct measurement of excursion or displacement of the speaker. Moreover, when the angle sensor, the light source, and the light beam are configured appropriately with respect to the moving cone of the speaker, the measurement can be substantially linear with respect to the amount of excursion or displacement. Such measurements are far simpler to use and in some cases more accurate than measurements made by other types of systems.

Abstract: Image capturing systems with interline CCD structures designed to reduce the delay between captures of subsequent image frames are disclosed. Proposed interline CCD structures include two or more sets of storage units associated with a given set of photodetecting elements, where each photodetecting element is associated with one storage unit of each set of storage units in that the charge generated by the photodetecting element during the acquisition of a particular image frame (i.e. during a particular exposure period) may be stored any one of these storage units prior to read-out. Providing multiple sets of storage units allows read-out of charge corresponding to one image frame and stored in one set of storage units while accumulating charge corresponding to another image frame in another set of storage units, thus reducing the delay between captures of different image frames. Consequently, errors and artifacts of the image capturing system can be minimized.

Abstract: Analog-to-digital converters (ADCs) can have errors which can affect their performance. To improve the performance, many techniques have been used to compensate or correct for the errors. When the ADCs are being implemented with sub-micron technology, ADCs can be readily and easily equipped with an on-chip microprocessor for performing a variety of digital functions. The on-chip microprocessor and any suitable digital circuitry can implement functions for reducing those errors, enabling certain undesirable artifacts to be reduced, and providing a flexible platform for a highly configurable ADC. The on-chip microprocessor is particularly useful for a randomized time-interleaved ADC. Moreover, a randomly sampling ADC can be added in parallel to a main ADC for calibration purposes. Furthermore, the overall system can include an efficient implementation for correcting errors in an ADC.

Abstract: Apparatus and methods for multi-channel autozero and chopper amplifiers are provided herein. In certain configurations, an amplifier includes at least three channels that operate using multiple phases, including at least a non-inverting chop phase, an inverting chop phase, and an autozero phase. The amplifier further includes an autozero and chopping timing control circuit, which at least partially interleaves or staggers timing of the channels' phases. For example, in certain configurations, when one or more of the channels are being autozeroed at a certain time instance, at least some of the remaining channels operate in the non-inverting chop phase or the inverting chop phase.