Amplifier

1 . An amplifier for amplifying a complex input communication signal having an in-phase and quadrature component comprising: a modulation circuitry configured to convert the input signal to quantized samples by performing oversampling, and wherein the quantized samples comprise an in-phase and quadrature component representing a finite set of constellation points; a phase mapping circuitry configured to map the quantized samples onto two constant-envelope phase-modulated signals selected from a finite set of constant-envelope phase-modulated signals having a carrier frequency f c and different constant phases; and wherein the two constant-envelope phase-modulated signals are selected such that a combination of the two constant-envelope phase-modulated signals represents the respective quantized samples; a first and second power amplifier configured to amplify the two constant-envelope phase-modulated signals by a gain G; a combiner configured to combine the two amplified constant-envelope phase-modulated signals thereby obtaining a complex output communication signal with the carrier frequency f c representing an amplification of the complex input communication signal. 2 . The amplifier according to claim 1 wherein the modulation circuitry is a sigma delta modulator. 3 . The amplifier according to claim 1 further comprising a bandpass filter operable around the carrier frequency f c and configured to filter out quantization noise introduced by the modulation circuitry from the complex output communication signal thereby obtaining a filtered complex output communication signal. 4 . The amplifier according to claim 1 wherein the complex input communication signal is a digital or analogue communication signal. 5 . The amplifier according to claim 1 wherein the complex input communication signal is a baseband signal or a signal modulated onto an intermediate frequency, IF, thereby obtaining an upmixing amplifier. 6 . The amplifier according to claim 1 wherein the phase mapping circuitry is configured to perform a one-to-one mapping between the finite set of constellation points and pairs of the finite set of constant-envelope phase-modulated signals. 7 . The amplifier according to claim 1 wherein the phase mapping circuitry is configured to map at least one constellation point to a select one of different possible pairs of the finite set of constant-envelope phase-modulated signals, and to select the select one such that additional signal transitions in the two constant-envelope phase-modulated signals are minimized. 8 . The amplifier according to claim 1 wherein the phase mapping circuitry is further configured to perform the mapping in alignment with the carrier frequency f c such that no additional transition occurs in between edges of the constant-envelope phase-modulated signals. 9 . The amplifier according to claim 1 further comprising a clock generator for generating a signal at the carrier frequency f c to derive the finite set of constant-envelope phase-modulated signals, and a clock division circuitry configured to generate a clock signal for performing the oversampling delta modulation by dividing the generated signal. 10 . The amplifier according to claim 1 wherein the modulation circuitry is further configured to account for a quantization offset when performing the conversion so as to compensate for a gain or phase mismatch between the first and second amplifier. 11 . The amplifier according to claim 10 wherein the combiner is a Chireix non-isolated combiner. 12 . The amplifier according to claim 1 wherein the finite set of constant-envelope phase-modulated signals has four phases, and the modulation circuitry comprises a three-level quantizer for deriving nine constellation points. 13 . An integrated circuitry comprising the amplifier according to claim 1 . 14 . A method for determining the quantization offset in the amplifier according to claim 11 , the method comprising the following steps: selecting different combinations of the constant-envelope phase-modulated signals; measuring an output power of the amplifier when applying the selected different combinations; estimating therefrom the gain mismatch and phase mismatch between the first and second power amplifiers; using the gain mismatch and phase mismatch, calculating the output power of the respective the first and second power amplifiers for the selected different combinations; using the calculated output power, determining actual constellation points associated with the selected different combinations; and deriving the quantization offset from the difference in the actual constellation points and the finite set of constellation points. 15 . A method for amplifying a complex input communication signal having an in-phase and quadrature component comprising: converting the input signal to quantized samples by performing oversampling, and wherein the quantized samples represent a finite set of constellation points; mapping the quantized samples onto two constant-envelope phase-modulated signals selected from a finite set of constant-envelope phase-modulated signals having a carrier frequency f c and (different) constant phases; amplifying the two constant-envelope phase-modulated signals by a gain G; and combining the two amplified constant-envelope phase-modulated signals thereby obtaining a complex output communication signal with the carrier frequency f c representing an amplification of the complex input communication signal.