Radio transmitter with transmit signal strength indicator and method thereof

What is claimed is: 1. A radio transmitter comprising: a power amplifier configured to receive an input voltage signal and output an output voltage signal; a transformer configured to receive the output voltage signal and output a load voltage signal to a load; a sensing inductor configured to output a sensed current signal in accordance with a magnetic coupling with the transformer; a digitally controlled phase shifter configured to receive the output voltage signal and output a phase-shifted voltage signal in accordance with a phase control code; a mixer configured to output a mixed current signal in accordance with a mixing of the sensed current signal and the phase-shifted voltage signal; and a transimpedance amplifier with of a low-pass response configured to convert the mixed current signal into a mean voltage. 2. The radio transmitter of claim 1 , wherein the digital control phase shifter comprises a poly-phase filter configured to receive the output voltage signal and output a four-phase voltage signal, and a digitally controlled phase rotator configured to receive the four-phase voltage signal and output the phase-shifted voltage signal in accordance with the phase control code. 3. The radio transmitter of claim 1 , wherein the mixer is a double-balanced passive mixer. 4. The radio transmitter of claim 1 , wherein in the transimpedance amplifier comprises an operational amplifier configured in a negative feedback topology using a feedback network comprising a parallel combination of a resistor and a capacitor. 5. The radio transmitter of claim 1 , wherein the phase control code is set such that a phase delay between an output current signal output from the power amplifier into the transformer and the sensed current signal is approximately equal to a phase delay between the output voltage signal and the phase-shifted voltage signal. 6. The radio transmitter of claim 5 , wherein the mean voltage signal multiplied by a power scaling factor is approximately equal to a power delivered to the load. 7. The radio transmitter of claim 6 , wherein the phase control code that leads to the phase delay between the output current signal and the sensed current signal being approximately equal to the phase delay between the output voltage signal and the phase-shifted voltage signal is found using a calibration. 8. The radio transmitter of claim 7 , wherein the calibration is done by using a power measuring instrument as the load. 9. The radio transmitter of claim 8 , wherein the phase control code that leads to the phase delay between the output current signal and the sensed current signal being approximately equal to the phase delay between the output voltage signal and the phase-shifted voltage signal is found by identifying the setting that leads to a largest mean voltage signal. 10. The radio transmitter of claim 9 , wherein the power scaling factor is found by calculating a ratio between a reading of the power measuring instrument and a value of the mean voltage signal. 11. A method comprising receiving an input voltage signal; converting the input voltage signal into an output voltage signal using a power amplifier; transforming the output voltage signal into a load voltage signal at a load using a transformer; outputting a sensed current signal using a sensing inductor in accordance with a magnetic coupling with the transformer; converting the output voltage signal into a phase-shifted voltage signal in accordance with a phase control code using a digitally control phase shifter; mixing the sensed current signal with the phase-shifted voltage signal into a mixed current signal using a mixer; and converting the mixed current signal into a mean voltage signal using a transimpedance amplifier with a low-pass response. 12. The method of claim 11 , wherein the digital control phase shifter comprises a poly-phase filter configured to receive the output voltage signal and output a four-phase voltage signal, and a digitally controlled phase rotator configured to receive the four-phase voltage signal and output the phase-shifted voltage signal in accordance with the phase control code. 13. The method of claim 11 , wherein the mixer is a double-balanced passive mixer. 14. The method of claim 11 , wherein in the transimpedance amplifier comprises an operational amplifier configured in a negative feedback topology using a feedback network comprising a parallel combination of a resistor and a capacitor. 15. The method of claim 11 , wherein the phase control code is set such that a phase delay between an output current signal output from the power amplifier into the transformer and the sensed current signal is approximately equal to a phase delay between the output voltage signal and the phase-shifted voltage signal. 16. The method of claim 15 , wherein the mean voltage signal multiplied by a power scaling factor is approximately equal to a power delivered to the load. 17. The method of claim 16 , wherein the phase control code that leads to the phase delay between the output current signal and the sensed current signal being approximately equal to the phase delay between the output voltage signal and the phase-shifted voltage signal is found using a calibration. 18. The method of claim 17 , wherein the calibration is done by using a power measuring instrument as the load. 19. The method of claim 18 , wherein the phase control code that leads to the phase delay between the output current signal and the sensed current signal being approximately equal to the phase delay between the output voltage signal and the phase-shifted voltage signal is found by identifying the setting that leads to a largest mean voltage signal. 20. The method of claim 19 , wherein the power scaling factor is found by calculating a ratio between a reading of the power measuring instrument and a value of the mean voltage signal.