Abstract: A device including a first circuit, a second circuit. The first circuit to receive a first signal, a second signal, and a third signal, and the first circuit to provide a fourth signal and a fifth signal. The second circuit to receive the fourth signal and the fifth signal, and the second circuit to control a first set of components to maintain a difference between a first amount of power provided to a first terminal of a driver and a second amount of power provided to a second terminal of the driver or to control a second set of components to maintain the difference between the first amount of power provided to the first terminal of the driver and the second amount of power provided to the second terminal of the driver.

Abstract: An example integrated circuit (IC) includes a semiconductor substrate having a first well and a second well; a first resistor disposed on the semiconductor substrate over the first well within a boundary thereof; a second resistor disposed on the semiconductor substrate over the second well within a boundary thereof, the boundary of the second well disjoint from the boundary of the first well; and a first contact to bias the semiconductor substrate at a first voltage, a second contact to bias the first well at a second voltage, and a third contact to bias the second well at a third voltage.

Abstract: A device including a first circuit, a second circuit, and a third circuit. The first circuit to receive a first signal and a second signal, and the first circuit to provide a third signal. The second circuit to receive a fourth signal and a fifth signal, and the second circuit to provide a sixth signal. The third circuit to receive the third signal and the sixth signal, and the third circuit to provide a seventh signal to indicate whether to track a difference between an amount of voltage provide to a driver and an amount of voltage provided by the driver or track a difference between an amount of voltage provided by a source and the amount of voltage provided to the driver.

Abstract: A device including a first circuit, a second circuit, and a third circuit. The first circuit to receive a first signal and a second signal, and the first circuit to provide a third signal. The second circuit to receive a fourth signal and a fifth signal, and the second circuit to provide a sixth signal. The third circuit to receive the third signal and the sixth signal, and the third circuit to provide a seventh signal to indicate whether to track a difference between an amount of voltage provide to a driver and an amount of voltage provided by the driver or track a difference between an amount of voltage provided by a source and the amount of voltage provided to the driver.

Abstract: A device including a first circuit, a second circuit. The first circuit to receive a first signal, a second signal, and a third signal, and the first circuit to provide a fourth signal and a fifth signal. The second circuit to receive the fourth signal and the fifth signal, and the second circuit to control a first set of components to maintain a difference between a first amount of power provided to a first terminal of a driver and a second amount of power provided to a second terminal of the driver or to control a second set of components to maintain the difference between the first amount of power provided to the first terminal of the driver and the second amount of power provided to the second terminal of the driver.

Abstract: A device including a first circuit, a second circuit, and a third circuit. The first circuit to receive a first signal and a second signal, and the first circuit to provide a third signal. The second circuit to receive a fourth signal and a fifth signal, and the second circuit to provide a sixth signal. The third circuit to receive the third signal and the sixth signal, and the third circuit to provide a seventh signal to indicate whether to track a difference between an amount of voltage provide to a driver and an amount of voltage provided by the driver or track a difference between an amount of voltage provided by a source and the amount of voltage provided to the driver.

Abstract: An interference tolerant capacitive touch sensor readout circuit having improved power and area efficiency is disclosed. Interference rejection for the capacitive touch sensing system is realized by transferring charge between a capacitive touch sensor and the readout circuit at frequencies outside bands where a level of interference is unacceptable. Improved power and area efficient come from the simplicity of the readout circuit which comprises a switched-capacitor integrator, a comparator, a digital accumulator and number of switches for driving a touch sensor and a capacitive feedback loop. The readout circuit is capable of interfacing with both self and mutual capacitance sensor to achieve compatibility with a larger collection of sensors and provides additional sensing and diagnostic functionalities.

Abstract: An interference tolerant capacitive touch sensor readout circuit having improved power and area efficiency is disclosed. Interference rejection for the capacitive touch sensing system is realized by transferring charge between a capacitive touch sensor and the readout circuit at frequencies outside bands where a level of interference is unacceptable. Improved power and area efficient come from the simplicity of the readout circuit which comprises a switched-capacitor integrator, a comparator, a digital accumulator and number of switches for driving a touch sensor and a capacitive feedback loop. The readout circuit is capable of interfacing with both self and mutual capacitance sensor to achieve compatibility with a larger collection of sensors and provides additional sensing and diagnostic functionalities.

Abstract: A digital Class-D amplifier distortion suppression circuit design is disclosed. A distortion suppression feedback loop is described to improve audio performance by suppressing output stage non-linearity and improving power supply noise rejection achieving reduced THD+N. The feedback loop is placed around the power stage. It forces tracking between the audio band signals at the input and output of the power stage by automatically adjusting the gating signal timing based on sensed effective duty ratio error. Error sensing and compensation are performed using techniques that lend to simple circuit implementation.

Abstract: A digital Class-D amplifier distortion suppression circuit design is disclosed. A distortion suppression feedback loop is described to improve audio performance by suppressing output stage non-linearity and improving power supply noise rejection achieving reduced THD+N. The feedback loop is placed around the power stage. It forces tracking between the audio band signals at the input and output of the power stage by automatically adjusting the gating signal timing based on sensed effective duty ratio error. Error sensing and compensation are performed using techniques that lend to simple circuit implementation.