A synchronously driven linear power amplifier (6) parallel to class D power amplifier (2) achieves an active filter equivalent, minimizing the scale of the passive filter (3), and effectively suppressing high frequency noise. Signal delay introduced by the passive filter (3) is also compensated by means of a phase compensation circuit (7) for phase compensating an audio signal applied from a signal input terminal (21).

A parallel, synchronously driven linear power amplifier (6) and class D power amplifier (2) form an equivalent active filter, minimizing the scale of the passive filter (3), and effectively suppressing high frequency noise. First to third muting circuits (17-19) are used when the power supply is turned on and off to interrupt signal supply from the signal input terminal, and control operation of the class D power amplifier (2) and linear voltage amplifier (15), thereby preventing extraneous irritating noises such as popping sounds from a loudspeaker.

Linear power amplifiers tend to be inefficient. This is a particular problem for RF amplifiers in a cellular base station. In order to improve the efficiency of such amplifiers, attempts have been made to modulate the power supply to the amplifier proportional to the envelope of the signal to be amplified. An UMTS signal requires power supply modulation at frequencies of the order of 10 to 20 megahertz. When quantization noise is taken into account, oversampling becomes desirable. However, switching power supplies at frequencies of the order of 40 or 80 or even 160 megahertz becomes difficult. By modifying the coding of phases of the power supply to be switched so that the number of phases enabled is proportional to the desired power supply output voltage rather than the length of a pulse in a time domain on any particular phase being proportional to the output voltage, dramatic improvements are achieved in switching losses, balance between phases and accurate tracking of the input signal. Rotation of switching across the phases achieves good balance and by jittering or randomizing the rotation, switching noise may be moved out of band.

Systems and methods for amplifying an RF input signal include employing a moderately power efficient wide bandwidth device, such as an AB-type amplifier, to amplify the power residing in the high frequency components of the input signal, and a highly power efficient narrow bandwidth device, such as a synchronous buck DC/DC converter, to amplify the power residing in the low frequency components of the input signal. The amplified low frequency components and high frequency components are then combined to produce an amplified replica of the RF input signal. A positive feedback loop is provided between the output of the AB-type amplifier and the input of the DC/DC converter to provide stability to the amplified RF signal. A negative feedback loop is provided between the output of the DC/DC converter and the input of the AB-type amplifier to minimize interference introduced by the DC/DC converter.

A signal processing circuit and method for processing an input signal are described. The circuit includes a frequency selective network, an amplification stage, and at least one continuous-time feedback path from the output of the amplification stage to the frequency selective network. The amplification stage includes a switching amplifier and an analog amplifier. Switching circuitry alternately enables the switching and analog amplifiers for processing of the input signal.