Abstract: A subthreshold-based MOSFET temperature sensor is provided for generating a subthreshold leakage current that is proportional to a difference between a gate-to-source voltage of a first transistor and a gate-to-source voltage of a second transistor. The subthreshold leakage current is mirrored to a detector for a temperature determination.

Abstract: Methods and apparatus for noise shaping in multi-stage analog-to-digital converters (ADCs). An example ADC generally includes a first conversion stage having a residue output; an amplifier having an input selectively coupled to the residue output of the first conversion stage; a second conversion stage having an input selectively coupled to an output of the amplifier; and a switched-capacitor network having a first port coupled to the input of the amplifier and having a second port coupled to the input of the second conversion stage, the switched-capacitor network being configured to provide a second-order or higher noise transfer function for noise shaping of quantization noise of the second conversion stage.

Abstract: An apparatus is disclosed for gain stabilization. In an example aspect, the apparatus includes an amplifier and a gain-stabilization circuit. The amplifier has a gain that is based on a bias voltage and an amplification control signal. The gain-stabilization circuit is coupled to the amplifier and includes a replica amplifier. The replica amplifier has a replica gain that is based on the bias voltage and the amplification control signal. The gain-stabilization circuit is configured to adjust at least one of the bias voltage or the amplification control signal based on a gain error associated with the replica amplifier.

Abstract: Methods and apparatus for noise shaping in multi-stage analog-to-digital converters (ADCs). An example ADC generally includes a first conversion stage having a residue output; an amplifier having an input selectively coupled to the residue output of the first conversion stage; a second conversion stage having an input selectively coupled to an output of the amplifier; and a switched-capacitor network having a first port coupled to the input of the amplifier and having a second port coupled to the input of the second conversion stage, the switched-capacitor network being configured to provide a second-order or higher noise transfer function for noise shaping of quantization noise of the second conversion stage.

Abstract: An apparatus is disclosed for pipelined analog-to-digital conversion. In an example aspect, the apparatus includes a pipelined analog-to-digital converter (ADC). The pipelined ADC includes a first stage and a second stage. The first stage includes a sampler and a quantizer coupled to the sampler. The first stage also includes a current distribution circuit coupled to the sampler. The second stage includes a sampler coupled to the current distribution circuit and a quantizer coupled to the sampler of the second stage.

Abstract: A device includes a first plurality of MEOL interconnects coupled to a second node that extends in a first direction. The first plurality of MEOL interconnects includes first and second subsets of MEOL second-terminal interconnects. The device includes a second plurality of MEOL interconnects coupled to a first node that extends in the first direction. The second plurality of MEOL interconnects includes first and second subsets of MEOL first-terminal interconnects. The first subsets of MEOL first-terminal and second-terminal interconnects are interleaved and are a first subset of interleaved MEOL interconnects. The second subsets of MEOL first-terminal and second-terminal interconnects are interleaved and are a second subset of interleaved MEOL interconnects. The device includes at least one of a first plurality of gate interconnects or a first plurality of OD regions extending in a second direction orthogonal to the first direction between the first and second subsets of interleaved MEOL interconnects.

Abstract: An apparatus is disclosed for pipelined analog-to-digital conversion. In an example aspect, the apparatus includes a pipelined analog-to-digital converter (ADC). The pipelined ADC includes a first stage and a second stage. The first stage includes a sampler and a quantizer coupled to the sampler. The first stage also includes a current distribution circuit coupled to the sampler. The second stage includes a sampler coupled to the current distribution circuit and a quantizer coupled to the sampler of the second stage.

Abstract: Aspects of the disclosure relate to an apparatus for wireless communication. The apparatus may include a set of power detectors configured to generate a set of analog signals related to a set of output signal power levels of a set of transmit chains of a transmitter, respectively; an analog summer; a set of switching devices configured to send a selected one or more of the set of analog signals to the analog summer, and substantially isolated unselected one or more of the set of power detectors from the analog summer, wherein the analog summer is configured to generate a cumulative analog signal based on a sum of the selected one or more of the set of analog signals; an analog-to-digital converter (ADC) configured to generate a digital signal based on the cumulative analog signal; and a controller configured to control the set of switching devices.

Abstract: An apparatus is disclosed for gain stabilization. In an example aspect, the apparatus includes an amplifier and a gain-stabilization circuit. The amplifier has a gain that is based on a bias voltage and an amplification control signal. The gain- stabilization circuit is coupled to the amplifier and includes a replica amplifier. The replica amplifier has a replica gain that is based on the bias voltage and the amplification control signal. The gain-stabilization circuit is configured to adjust at least one of the bias voltage or the amplification control signal based on a gain error associated with the replica amplifier.

Abstract: Aspects of the disclosure relate to an apparatus for wireless communication. The apparatus may include a set of power detectors configured to generate a set of analog signals related to a set of output signal power levels of a set of transmit chains of a transmitter, respectively; an analog summer; a set of switching devices configured to send a selected one or more of the set of analog signals to the analog summer, and substantially isolated unselected one or more of the set of power detectors from the analog summer, wherein the analog summer is configured to generate a cumulative analog signal based on a sum of the selected one or more of the set of analog signals; an analog-to-digital converter (ADC) configured to generate a digital signal based on the cumulative analog signal; and a controller configured to control the set of switching devices.

Abstract: An apparatus for generating a substantially constant DC reference voltage. The apparatus includes a reference voltage generator configured to generate a substantially constant direct current (DC) reference voltage based on a voltage on a data signal transmission line, wherein the voltage is based on a bandgap reference voltage. In one implementation, the data signal transmission line is a differential signal transmission line and the voltage is a common mode voltage. In another implementation, the data signal transmission line is an I-data signal transmission line and a Q-data signal transmission line, and the voltage is an average or weighted-average of the common mode voltages of the I- and Q-differential signals. In another implementation, the reference voltage is based on a single-ended (e.g., positive- and/or negative)-component or vice-versa of I- and Q-data signals, respectively.

Abstract: Certain aspects provide a circuit for analog-to-digital conversion. The circuit generally includes a flash analog-to-digital converter (ADC) having a plurality of comparators, each comparator being configured to compare an input voltage to a reference voltage; and a calibration circuit coupled to the flash ADC and configured to tune the reference voltage prior to a conversion operation by the flash ADC.

Abstract: An apparatus for generating a substantially constant DC reference voltage. The apparatus includes a reference voltage generator configured to generate a substantially constant direct current (DC) reference voltage based on a voltage on a data signal transmission line, wherein the voltage is based on a bandgap reference voltage. In one implementation, the data signal transmission line is a differential signal transmission line and the voltage is a common mode voltage. In another implementation, the data signal transmission line is an I-data signal transmission line and a Q-data signal transmission line, and the voltage is an average or weighted-average of the common mode voltages of the I- and Q-differential signals. In another implementation, the reference voltage is based on a single-ended (e.g., positive- and/or negative)-component or vice-versa of I- and Q-data signals, respectively.

Abstract: A receiver may include a time-interleaved charge sampler comprising a charge sampler switch in series with a charge sampler capacitor. The receiver may also include a current buffer configured to drive the time-interleaved charge sampler.

Abstract: An apparatus for generating a substantially constant DC reference voltage. The apparatus includes a reference voltage generator configured to generate a substantially constant direct current (DC) reference voltage based on a voltage on a data signal transmission line, wherein the voltage is based on a bandgap reference voltage. In one implementation, the data signal transmission line is a differential signal transmission line and the voltage is a common mode voltage. In another implementation, the data signal transmission line is an I-data signal transmission line and a Q-data signal transmission line, and the voltage is an average or weighted-average of the common mode voltages of the I- and Q-differential signals. In another implementation, the reference voltage is based on a single-ended (e.g., positive- and/or negative)-component or vice-versa of I- and Q-data signals, respectively.

Abstract: Methods and apparatus for digitally controlling a common-mode voltage of a comparator. An example comparator circuit generally includes a first comparator and a sensing circuit configured to digitally track a common-mode voltage of the first comparator. The comparator circuit may further include a first capacitive array having a common terminal coupled to a first input of the first comparator and selectively coupled to an input of the sensing circuit. The comparator circuit may further include a second capacitive array having a common terminal coupled to a second input of the first comparator and selectively coupled to the input of the sensing circuit.

Abstract: A receiver may include a time-interleaved charge sampler comprising a charge sampler switch in series with a charge sampler capacitor. The receiver may also include a current buffer configured to drive the time-interleaved charge sampler.

Abstract: Methods and apparatuses for chopping a successive approximation register (SAR) analog-to-digital converter (ADC). The ADC generally includes a comparator comprising a first input and a second input; a switch connected between the first and second inputs of the comparator; a first capacitive array having a first terminal selectively coupled to the first input of the comparator; a second capacitive array having a first terminal selectively coupled to the second input of the comparator; and a reference buffer selectively coupled to second terminals of the first and second capacitive arrays and configured to apply inverse digital codes to the first and second capacitive arrays, wherein the switch is configured to short the first and second inputs of the comparator while the inverse digital codes are being applied to the first and second capacitive arrays such that charges of the first and second capacitive arrays are redistributed via the reference buffer.

Abstract: An example apparatus is disclosed for alias rejection through charge sharing. The apparatus includes a filter-sampling network, a digital-to-analog converter, and a charge-sharing switch. The filter-sampling network includes a capacitor and a first switch, which is coupled between an input node and the capacitor. The filter-sampling network is configured to connect or disconnect the capacitor to or from the input node via the first switch. The digital-to-analog converter includes a capacitor array and a second switch, which is coupled between the input node and the capacitor array. The capacitor array is coupled between the second switch and a charge-sharing node. The digital-to-analog converter is configured to connect or disconnect the capacitor array to or from the input node via the second switch. The charge-sharing switch is coupled between the charge-sharing node and the capacitor and is configured to connect or disconnect the capacitor to or from the digital-to-analog converter.

Abstract: An example apparatus is disclosed for alias rejection through charge sharing. The apparatus includes a filter-sampling network, a digital-to-analog converter, and a charge-sharing switch. The filter-sampling network includes a capacitor and a first switch, which is coupled between an input node and the capacitor. The filter-sampling network is configured to connect or disconnect the capacitor to or from the input node via the first switch. The digital-to-analog converter includes a capacitor array and a second switch, which is coupled between the input node and the capacitor array. The capacitor array is coupled between the second switch and a charge-sharing node. The digital-to-analog converter is configured to connect or disconnect the capacitor array to or from the input node via the second switch. The charge-sharing switch is coupled between the charge-sharing node and the capacitor and is configured to connect or disconnect the capacitor to or from the digital-to-analog converter.