An audio processing device includes: at least one processor configured to: generate a first signal by reducing components that fall below a first frequency in an audio signal; generate a second signal by reducing components that fall below a second frequency that is higher than the first frequency in the audio signal; select between a first state for outputting the first signal and a second state for outputting the second signal; and output one of the selected first or second signal as an output signal; and a class-D amplifier configured to amplify the output signal, in which, the at least one processor is further configured to: determine whether or not a power supply pumping phenomenon exists or a possibility of the power supply pumping phenomenon exists, in a power source that supplies a power supply voltage to the class-D amplifier; and in which, in the selecting between the first state and the second state, the at least one processor is configured to select: the first state in a case where a determination result is negative, where the power supply pumping phenomenon is determined to not exist or the possibility of the power supply pumping phenomenon is determined to not exist; and the second state in a case where the determination result is affirmative, where the power supply pumping phenomenon is determined to exist or the possibility of the power supply pumping phenomenon is determined to exist.

A Class-D amplifier having a low power dissipation mode includes first and second independent output stages that receive respective first and second level power supply voltages for driving a load coupled to the amplifier output during respective first and second operating modes. Bypass switches are controllable to disconnect the second output stage from the output during the first operating mode and to connect the second output stage to the output during the second operating mode. The operating modes are selected based on the amplifier output power level. First and second independent pre-driver stages receive the respective first and second level power supply voltages for driving the respective first and second independent output stages. During the second operating mode the first pre-driver stage is placed into a low power dissipation state and during the first operating mode the second pre-driver stage is placed into a low power dissipation state.

In one or more embodiments, an efficient scheme is provided for sampling inductor currents in a digital multiphase PWM controller used for high-bandwidth voltage regulation. Some embodiments use the data from the PWM modulator along with weighted states based on the PWM waveform and past conversions in order to prioritize which current sense input should be sampled for each conversion. In these and other embodiments, a single ADC is used to sample inductor currents from two or more phases in a multiphase PWM controller, thereby providing power and area savings, for example.

Aspects disclosed herein eliminate audible disturbances that may occur when an audio amplifier is activated and deactivated. A feedback circuit is used to maintain a closed loop when transistors of a power output stage are activate or deactivated, thereby enabling the charge to build or dissipate without causing an audible disturbance. Further, in certain implementations, the power output stage may remain in an enable state for a period of time after deactivation of the audio amplifier regardless of whether an audio input signal is received enabling dissipation of charge without causing an audible disturbance.

The present invention provides an amplifier including a DAC, an analog signal processing circuit, a digital signal processing circuit, a signal detector and a driving stage is disclosed. The DAC is configured to perform a digital-to-analog conversion operation on a digital input signal to generate an analog input signal. The analog signal processing circuit is configured to generate a first processed signal according to the analog input signal and a feedback signal. The digital signal processing circuit is configured to process the digital input signal to generate a second processed signal. The signal detector is configured to detect strength of the digital input signal to generate a mode selection signal. The driving stage is configured to refer to the mode selection signal to receive one of the first processed signal and the second processed signal to generate an output signal, wherein the feedback signal is generated by the output signal.

The present invention provides an amplifier including a DAC, an analog signal processing circuit, a digital signal processing circuit, a signal detector and a driving stage is disclosed. The DAC is configured to perform a digital-to-analog conversion operation on a digital input signal to generate an analog input signal. The analog signal processing circuit is configured to generate a first processed signal according to the analog input signal and a feedback signal. The digital signal processing circuit is configured to process the digital input signal to generate a second processed signal. The signal detector is configured to detect strength of the digital input signal to generate a mode selection signal. The driving stage is configured to refer to the mode selection signal to receive one of the first processed signal and the second processed signal to generate an output signal, wherein the feedback signal is generated by the output signal.

A power amplifier circuit includes a lower transistor having a first terminal, a second terminal connected to ground, and a third terminal, wherein a first power supply voltage is supplied to the first terminal, and an input signal is supplied to the third terminal; a first capacitor; an upper transistor having a first terminal, a second terminal connected to the first terminal of the lower transistor via the first capacitor, and a third terminal, wherein a second power supply voltage is supplied to the first terminal, an amplified signal is outputted to an output terminal from the first terminal, and a driving voltage is supplied to the third terminal; a first inductor that connects the second terminal of the upper transistor to ground; a voltage regulator circuit; and at least one termination circuit that short-circuits an even-order harmonic or odd-order harmonic of the amplified signal to ground potential.

A power amplifier circuit includes a lower transistor having a first terminal, a second terminal connected to ground, and a third terminal, wherein a first power supply voltage is supplied to the first terminal, and an input signal is supplied to the third terminal; a first capacitor; an upper transistor having a first terminal, a second terminal connected to the first terminal of the lower transistor via the first capacitor, and a third terminal, wherein a second power supply voltage is supplied to the first terminal, an amplified signal is outputted to an output terminal from the first terminal, and a driving voltage is supplied to the third terminal; a first inductor that connects the second terminal of the upper transistor to ground; a voltage regulator circuit; and at least one termination circuit that short-circuits an even-order harmonic or odd-order harmonic of the amplified signal to ground potential.

Disclosed is an apparatus including a radio frequency amplifying circuit, a power supply circuit, and a bias generating circuit. The power supply circuit includes: a first power supply terminal coupled to a first ground terminal via a first capacitor and coupled to/decoupled from the radio frequency amplifying circuit through a first switch; and a second power supply terminal coupled to a second ground terminal via a second capacitor and coupled to/decoupled from the radio frequency amplifying circuit through a second switch, wherein the first capacitor and second capacitor are coupled to/decoupled from the radio frequency amplifying circuit through the first switch and second switch respectively, the supply voltages outputted from the two power supply terminals are different, and the two switches are not concurrently turned on. The radio frequency amplifying circuit operates according to a bias voltage provided by the bias generating circuit and one of the two supply voltages.

Disclosed is an apparatus including a radio frequency amplifying circuit, a power supply circuit, and a bias generating circuit. The power supply circuit includes: a first power supply terminal coupled to a first ground terminal via a first capacitor and coupled to/decoupled from the radio frequency amplifying circuit through a first switch; and a second power supply terminal coupled to a second ground terminal via a second capacitor and coupled to/decoupled from the radio frequency amplifying circuit through a second switch, wherein the first capacitor and second capacitor are coupled to/decoupled from the radio frequency amplifying circuit through the first switch and second switch respectively, the supply voltages outputted from the two power supply terminals are different, and the two switches are not concurrently turned on. The radio frequency amplifying circuit operates according to a bias voltage provided by the bias generating circuit and one of the two supply voltages.