Abstract: Technologies are provided for adaptive control of bias settings in a digital microphone. In some embodiments, a device includes a first component that provides data indicative of a clock frequency of operation in a functional mode of a digital microphone. The clock frequency clocks one or more microphone components having switching activity. The device also can include a second component that determines, using the clock frequency, an amount of bias current to supply to at least a first microphone component of the one or more microphone components. The device can further include a memory device that retains control parameters that include at least one of a first subset of parameters defining a relationship between current and frequency and a second subset of parameters defining a quantization of the relationship. The quantization including multiple bias current levels for respective frequency intervals.

Abstract: Technologies are provided for adaptive control of bias settings in a digital microphone. In some embodiments, a device includes a first component that provides data indicative of a clock frequency of operation in a functional mode of a digital microphone. The clock frequency clocks one or more microphone components having switching activity. The device also can include a second component that determines, using the clock frequency, an amount of bias current to supply to at least a first microphone component of the one or more microphone components. The device can further include a memory device that retains control parameters that include at least one of a first subset of parameters defining a relationship between current and frequency and a second subset of parameters defining a quantization of the relationship. The quantization including multiple bias current levels for respective frequency intervals.

Abstract: An analog-to-digital converter (ADC) with split-gate laddered-inverter quantizer is presented herein. The ADC converts, via the split-gate laddered-inverter quantizer, an analog input voltage into a digital output value. The split-gate laddered-inverter quantizer separately couples, during respective phases of a clock signal via respective capacitances, a reference voltage and an input voltage corresponding to the analog input voltage to P-type metal-oxide-semiconductor (PMOS) gates of a PMOS branch of the split-gate laddered-inverter quantizer and N-type metal-oxide-semiconductor (NMOS) gates of an NMOS branch of the split-gate laddered-inverter quantizer to optimize current flow at respective frequencies. Further, the split-gate laddered-inverter quantizer separately biases, during the respective phases of the clock signal, the NMOS gates and the PMOS gates at respective bias voltages to optimize the current flow at the respective frequencies.

Abstract: A low power bandgap circuit device that generates temperature independent reference voltages and/or zero temperature coefficient currents is disclosed. The circuit comprises a first pair of transistors, an amplifier, a star connected resistive network, and a second pair of transistors, wherein zero temperature coefficient currents are generated through mirroring and reuse of current from the star connected resistive network.

Abstract: A low power bandgap circuit device that generates temperature independent reference voltages and/or zero temperature coefficient currents is disclosed. The circuit comprises a first pair of transistors, an amplifier, a star connected resistive network, and a second pair of transistors, wherein zero temperature coefficient currents are generated through mirroring and reuse of current from the star connected resistive network.

Abstract: Embodiments of the invention are generally directed to a high-speed differential energy difference integrator (EDI) for adaptive equalizers. In an embodiment, the EDI includes two differential full-wave rectifiers providing differential outputs that are cross-coupled to the inputs of an integration capacitor. In one embodiment, the active areas of the transistors of the differential full-wave rectifiers are substantially the same.

Abstract: Embodiments of the invention are generally directed to a high-speed differential energy difference integrator (EDI) for adaptive equalizers. In an embodiment, the EDI includes two differential full-wave rectifiers providing differential outputs that are cross-coupled to the inputs of an integration capacitor. In one embodiment, the active areas of the transistors of the differential full-wave rectifiers are substantially the same.

Abstract: Embodiments of the invention are generally directed to a high-speed differential energy difference integrator (EDI) for adaptive equalizers. In an embodiment, the EDI includes two differential full-wave rectifiers providing differential outputs that are cross-coupled to the inputs of an integration capacitor. In one embodiment, the active areas of the transistors of the differential full-wave rectifiers are substantially the same.

Abstract: Disclosed is a circuit, comprising an input spread spectrum enable signal, a crystal oscillator, a first, second and third sampling flip-flop clocked by the crystal oscillator, configured to sample the input spread spectrum enable signal, and a plurality of control output signals derived from or provided directly from the sampling flip-flops. A method of operating the circuit is further described.

Abstract: A phase shift and duty cycle correction circuit is disclosed herein as comprising a programmable digital to analog converter (DAC), a storage device (e.g., a capacitor), a charge sub-circuit and dump sub-circuit for charging and discharging the storage device, respectively, a comparator, and a clock driver circuit. A linearly increasing (or ramped) voltage waveform is generated within the storage device by the charging and discharging actions of the charge and dump sub-circuits; a periodic process which is controlled by opposite phases of the input clock. By programming the DAC control input to change the slicing threshold of the ramped waveform, the circuit and method described herein provides a means for programmable phase shifting and duty cycle correction.