A semiconductor device with reduced power consumption can be provided. The semiconductor device includes a first transistor and a second transistor. The first transistor is a p-channel transistor including silicon in a channel formation region and the second transistor is an n-channel transistor including a metal oxide in a channel formation region. The metal oxide includes indium, an element M (e.g., gallium), and zinc. A gate of the first transistor is electrically connected to a gate of the second transistor, and one of a source and a drain of the first transistor is electrically connected to one of a source and a drain of the second transistor. The first transistor and the second transistor can each operate in a subthreshold region.

Certain aspects of the present disclosure provide a digital-to-analog converter (DAC) system. The DAC system generally includes a plurality of current steering cells, each comprising a current source coupled to at least two current steering switches, wherein control inputs of the at least two current steering switches are coupled to an input path of the DAC system. The DAC system may also include a current source toggle circuit configured to selectively disable the current source of at least one of the plurality of current steering cells, and a feedforward path coupled between the input path and at least one control input of the current source toggle circuit.

A communication device includes a power amplifier that generates power signals according to one or more operating bands of communication data, with the amplitude being driven and generated in output stages of the power amplifier. A number of capacitive digital analog converter (CDAC) cells of a power amplifier can be sized to provide defined power signals along a signal path. In response to an optimization component that is coupled to a CDAC cell of the plurality of CDAC cells operating in a high efficiency enable mode and the CDAC cell being powered off in an off mode, the optimization component can increase a power efficiency of the power amplifier by reducing an impedance of an output capacitor of the CDAC cell.

Analog to digital conversion circuitry has an input sampling buffer, which has an input sampling capacitor for sampling an analog signal. The conversion circuitry also has a successive-approximation-register analog to digital converter (SAR-ADC) which converts the sampled analog signal to a digital signal. The input sampling buffer has an amplifier and a gain-control capacitor, and has an amplification configuration and an error-feedback configuration. In the amplification configuration, the input sampling capacitor is coupled to the amplifier and gain-control capacitor, with the gain-control capacitor connected in feedback with the amplifier, for applying gain to the sampled analog signal. In the error-feedback configuration, the gain-control capacitor is decoupled from the input sampling capacitor and receives a residue voltage from the SAR-ADC, such that the level of the analog signal determined in the amplification configuration varies depending on the residue voltage received onto the gain-control capacitor in the error-feedback configuration.

An electronic device includes analog-to-digital converters each configured to receive an analog input signal and output a digital output signal corresponding to the analog input signal, an analog input signal generator configured to generate analog input signals provided to each analog-to-digital converter based on input voltages and weight data, an input signal distribution information generator configured to generate input signal distribution information indicating a distribution of the analog input signals for each of the analog-to-digital converters, an analog-to-digital converter group classifier configured to classify the analog-to-digital converters into a plurality of first analog-to-digital converter groups based on the input signal distribution information, and an analog-to-digital converter input range optimizer configured to determine an input range of each first analog-to-digital converter group based on the input signal distribution information, and each analog-to-digital converter is configured to operate according to an input range of a corresponding first analog-to-digital converter groups.

A circuit includes an amplifier having first and second inputs and an output, and a feedback circuit configured to generate a feedback voltage in response to a voltage at the output of the amplifier. The feedback circuit is coupled to the first input of the amplifier to provide the feedback voltage to the first input of the amplifier. An output circuit is configured to generate a variable bias current in response to the voltage at the output of the amplifier. A switch circuit is configured to switch the second input of the amplifier from receiving a first reference voltage during a first mode of operation to receiving a second reference voltage during a second mode of operation.

Analog signal measurement and related circuitry, systems, and methods are disclosed. Circuitry includes timing circuitry configured to assert a first enable signal at a first time and a second enable signal at a second time. The circuitry also includes an operational amplifier circuit configured to enable responsive to the assertion of the first enable signal. The operational amplifier circuit is configured to receive an analog input signal and, if enabled, generate an amplified analog input signal responsive to the analog input signal. The circuitry further includes signal analyzing circuitry configured to enable responsive to the assertion of the first enable signal, compare the amplified analog input signal to one or more threshold values responsive to the assertion of the second enable signal, and generate an alert signal responsive to a determination that the amplified analog input signal falls outside of the one or more threshold values.

Certain aspects of the present disclosure provide a digital-to-analog conversion circuit. The digital-to-analog conversion circuit generally includes a detection circuit configured to detect digital transitions in a digital input signal. The digital-to-analog conversion circuit also includes a clock-gating circuit having an input coupled to an output of the detection circuit. The clock-gating circuit is configured to gate a clock signal for the digital-to-analog conversion circuit based on an output signal from the detection circuit.

The present disclosure relates generally to digital microphone and other sensor assemblies including a transduction element and a successive-approximation (SA) quantizer configured to reuse a digital code generated for a prior sample period for a current sample period when a reuse condition is satisfied. The SA quantizer does not regenerate a new digital code for the current sample period when the digital code generated for the prior sample period is used thereby reducing power consumption.

Certain aspects of the present disclosure are directed to a radio frequency digital-to-analog converter (RFDAC). The RFDAC generally includes a plurality of digital-to-analog (DAC) unit cells. At least one DAC unit cell is capable of being configured in an active state or in a sleep state. For the at least one DAC unit cell, an output impedance of the DAC unit cell in the active state is equal to an output impedance of the DAC unit cell in the sleep state.