Cartesian loop circuits, transmitters, devices, and related methods

We claim: 1. A Cartesian loop circuit comprising: a reference signal amplifier to provide a baseband reference signal; a forward path coupled to the reference signal amplifier to receive the baseband reference signal and obtain a forward path signal from the baseband reference signal and a down-mixed feedback signal, the forward path including an up-mixer to up mix the forward path signal to a radio frequency signal; a feedback path coupled to the forward path to obtain a feedback signal from the radio frequency signal of the forward path, the feedback path including a down-mixer to down mix the feedback signal to a frequency of the baseband reference signal, the feedback path further coupled to the forward path to provide the down-mixed feedback signal to the forward path; and a controller coupled to the reference signal amplifier and the feedback path, the controller to perform power control at a low power by controlling a gain of the reference signal amplifier and to perform power control at a high power that is higher than the low power by controlling a gain of the down-mixer. 2. The circuit of claim 1 , wherein the controller is further coupled to the forward path, and wherein the controller is to perform power control at the high power by further controlling a gain at the up-mixer. 3. The circuit of claim 1 , wherein the feedback path includes a variable attenuator and the controller is to control attenuation of the feedback signal. 4. The circuit of claim 1 , wherein the controller is to activate Cartesian loop phase training at the high power and is to deactivate Cartesian loop phase training at the low power. 5. The circuit of claim 1 , further comprising an antenna at an output of the forward path, the antenna to transmit the radio frequency signal. 6. A Cartesian loop transmitter device comprising: an antenna; a reference signal amplifier to provide a baseband reference signal; a forward path including a forward path amplifier and a mixer, the forward path coupled to the reference signal amplifier, the forward path to up mix the baseband reference signal as combined with a down-mixed feedback signal to obtain a radio frequency signal; a feedback path including an attenuator and a mixer, the feedback path coupled to the forward path to down mix a representation of the radio frequency signal and provide a down-mixed feedback signal to the forward path; and a controller coupled to the reference signal amplifier and to the attenuator, the controller to control a gain of the reference signal amplifier and a gain of the attenuator based on a power level to transmit the radio frequency signal at the antenna; wherein the controller is to decrease the gain of the attenuator when the power level is increased and is above a threshold power level; and wherein the controller is further to control a gain of the forward path amplifier based on the power level. 7. The device of claim 6 , wherein the controller is further to control a gain of the forward path amplifier based on the power level. 8. The device of claim 7 , wherein the controller is to increase the gain of the forward path amplifier when the power level is increased and is above the threshold power level. 9. The device of claim 8 , wherein the controller is to activate Cartesian loop phase training when the power level is above the threshold power level and to deactivate Cartesian loop phase training when the power level is below the threshold power level. 10. The device of claim 6 , further comprising a terrestrial trunked radio encoder coupled to the forward path. 11. A method for power control in a Cartesian loop circuit, the method comprising: performing power control of the Cartesian loop circuit at a low power by controlling a gain of a reference signal provided to a forward path of the Cartesian loop circuit based on a power level at which to operate the Cartesian loop circuit when the power level is below a threshold power level; and performing power control of the Cartesian loop circuit at a high power that is higher than the low power by controlling a gain of a feedback signal in a feedback path of the Cartesian loop circuit based on the power level at which to operate the Cartesian loop circuit when the power level is above the threshold power level. 12. The method of claim 11 , further comprising controlling a gain of a forward path amplifier based on the power level. 13. The method of claim 12 , wherein controlling the gain of the forward path amplifier further comprises controlling the gain of the forward path amplifier when the power level is above the threshold power level. 14. The method of claim 11 , further comprising activating Cartesian loop phase training when the power level is above the threshold power level and deactivating Cartesian loop phase training when the power level is below the threshold power level. 15. The method of claim 11 , further comprising transmitting a terrestrial trunked radio signal via the forward path. 16. The method of claim 11 , further comprising selecting the power level from an indexed series of discrete power levels that are above and below the threshold power level.