Precision measurement of transmit power using loopback calibration in an RF transceiver

What is claimed is: 1. A method of calibrating a transmit power of a communications transceiver, comprising: transmitting a periodic signal at a selected frequency from a transmit channel in the transceiver, at a first programmed power setting; measuring a first power level of the transmitted signal as amplified by a receive amplifier in a receive channel of the transceiver, the first power level proportional to a gain of the receive amplifier; measuring a second power level of the transmitted signal as received by the receive channel of the transceiver and bypassing the receive amplifier; producing, from the transmitted signal as received by a loopback reference channel in the transceiver, a processed signal at an amplitude proportional to a regulated voltage; measuring a third power level of the processed signal; calculating the gain of the receive amplifier from a ratio of the first and second power levels; and calculating an absolute power level corresponding to the first programmed power setting from a ratio of the second and third power levels; wherein the transmit power of the communications transceiver is calibrated based on the absolute power. 2. The method of claim 1 , wherein the step of producing the processed signal comprises: centering the received signal at a mid-rail level; applying the centered signal to a series of at least one buffer to produce a square wave at an amplitude of the regulated voltage; attenuating the square wave by a selected attenuation gain. 3. The method of claim 2 , wherein the series of at least one buffer comprises: a plurality of buffers, constructed of transistors of increasing drive strength from a first buffer of the plurality of buffers receiving the centered signal to a final buffer of the plurality of buffers producing the square wave applied to the attenuating step. 4. The method of claim 2 , wherein the centering step comprises: amplifying the received signal with a self-biased amplifier. 5. The method of claim 1 , wherein the step of measuring the first power level comprises: amplifying the received signal with the receive amplifier; downconverting the amplified received signal to an intermediate frequency; converting the intermediate frequency signal to a digital baseband signal; and calculating the power level of the digital baseband signal. 6. The method of claim 5 , wherein the step of measuring the second power level comprises: attenuating the received signal along a pass-through path in the receive channel bypassing the receive amplifier; downconverting the attenuated signal to a second intermediate frequency; converting the second intermediate frequency signal to a second digital baseband signal; and calculating the power level of the second digital baseband signal. 7. The method of claim 5 , wherein the step of measuring the third power level comprises: downconverting the processed signal to a second intermediate frequency; converting the second intermediate frequency signal to a second digital baseband signal; and calculating the power level of the second digital baseband signal. 8. The method of claim 1 , further comprising: generating the regulated voltage responsive to an external direct current (DC) voltage. 9. The method of claim 1 , further comprising: producing a bandgap reference voltage; and generating the regulated voltage based on the bandgap reference voltage. 10. The method of claim 1 , further comprising: repeating the transmitting step at a second programmed power setting; and then repeating the measuring steps, repeating the producing step, and repeating the calculating steps. 11. A method of calibrating a transmit power of a communications transceiver, comprising: transmitting a periodic signal at a selected frequency from a transmit channel in the transceiver, at a first programmed power setting; measuring a first power level of the transmitted signal as amplified by a receive amplifier in a receive channel of the transceiver, the first power level proportional to a gain of the receive amplifier; amplifying the transmitted signal as received by a loopback reference channel in the transceiver by a replica receive amplifier; measuring a second power level of the amplified signal from the replica receive amplifier; and calculating an absolute power level corresponding to the first programmed power setting from a ratio of the first and second power levels; wherein the transmit power of the communications transceiver is calibrated based on the absolute power. 12. The method of claim 11 , further comprising: determining an overall front-end gain from one of the first and second power levels and the calculated absolute power level. 13. The method of claim 11 , further comprising: repeating the transmitting step at a second programmed power setting; and then repeating the measuring steps, repeating the amplifying step, and repeating the calculating step. 14. A communications transceiver, comprising: a transmit channel comprising one or more power amplifier stages; a receive channel comprising: a receive amplifier; one or more mixers for downconversion of signals from the receive amplifier, and for downconversion of signals received by the receive channel that bypass the receive amplifier; analog-to-digital converter circuitry, having an input coupled to an output of the receive amplifier; a loopback reference channel, comprising: an amplifier; at least one buffer stage having an input coupled to an output of the amplifier; and an attenuator for applying a selected attenuation to a signal from an output of the at least one buffer stage; digital circuitry coupled to a programmable power amplifier and to the analog-to-digital converter circuitry, for controlling the transceiver to perform a plurality of operations comprising: transmitting a signal from the transmit channel with the one or more power amplifier stages at a programmed power setting; measuring a first power level of the transmitted signal from a digital signal amplified by the receive amplifier and converted by the analog-to-digital converter circuitry; measuring a second power level of the transmitted signal as received by the receive channel of the transceiver and bypassing the receive amplifier; measuring a third power level of the transmitted signal from a digital signal corresponding to an output of the attenuator, the third power level being proportional to a power supply voltage; and calculating a gain of the receive amplifier from a ratio of the first and second power levels; and calculating an absolute power level corresponding to the first programmed power setting from a ratio of the second and third power levels; wherein a transmit power of the communications transceiver is calibrated based on the absolute power. 15. The transceiver of claim 14 , wherein the digital circuitry comprises: control logic for controlling the gain of the power amplifier stages; and baseband circuitry, coupled to the analog-to-digital converter circuitry, for performing the measuring steps and for performing the calculating steps. 16. The transceiver of claim 14 , wherein the amplifier of the loopback reference channel is a self-biased amplifier; and wherein the at least one buffer stage comprises: a plurality of buffer stages, constructed of transistors of increasing drive strength from a first buffer stage of the plurality of buffer stages receiving the output of the self-biased amplifier to a final buffer stage of the plurality of buffer stages, each of the plurality of buffer s