Apparatus and methods for compensating radio frequency transmitters for local oscillator leakage

What is claimed is: 1. A radio frequency (RF) transmitter with local oscillator (LO) leakage compensation, the RF transmitter comprising: a mixer comprising a signal input configured to receive an input signal, a clock input configured to receive an LO signal, and an output configured to generate an RF output signal; and an LO leakage compensation circuit configured to obtain a first envelope measurement indicating a signal envelope at the output based on injecting a first DC input current into the signal input, and to obtain a second envelope measurement indicating the signal envelope at the output based on injecting a second DC input current into the signal input, wherein the LO leakage compensation circuit is further configured to detect an amount of LO leakage of the mixer based on at least a comparison of the first envelope measurement to the second envelope measurement and on an amount of the first DC input current, and wherein the LO leakage compensation circuit is further configured to iteratively adjust a magnitude of the first DC input current and the second DC input current based on the comparison. 2. The RF transmitter of claim 1 , wherein the first DC input current and second DC input current have about equal magnitude but opposite polarity. 3. The RF transmitter of claim 1 , wherein the first envelope measurement and the second envelope measurement are each a DC measurement. 4. The RF transmitter of claim 1 , wherein the LO leakage compensation circuit is further configured to detect the amount of LO leakage based on determining a difference between the first envelope measurement and the second envelope measurement, and to provide LO leakage compensation based on the difference. 5. The RF transmitter of claim 1 , wherein the LO leakage compensation circuit is further configured to iteratively adjust the magnitude of the first DC input current and the second DC input current based on the comparison until the first envelope measurement and the second envelope measurement are substantially equal. 6. The RF transmitter of claim 1 , wherein the LO leakage compensation circuit comprises an envelope detector configured to obtain the first envelope measurement and the second envelope measurement, and an ADC configured to generate a digital representation of the first envelope measurement and a digital representation of the second envelope measurement. 7. The RF transmitter of claim 6 , wherein the LO leakage compensation circuit further comprises a digital subtractor configured to compute a difference between the digital representation of the first envelope measurement and the digital representation of the second envelope measurement. 8. The RF transmitter of claim 6 , wherein the LO leakage compensation circuit further comprises a digital comparator configured to compare the first envelope measurement and to the second envelope measurement, and to control an input offset to the mixer based on the comparison. 9. The RF transmitter of claim 1 , wherein the LO leakage compensation circuit comprises a DAC configured to inject, during calibration, the first DC input current and the second DC input current, and to inject, after calibration, an input offset to the mixer based on the amount of LO leakage detected to thereby compensate for the LO leakage. 10. A method of compensating a transmitter for local oscillator (LO) leakage, the method comprising: receiving an LO signal as a clock input to a mixer; injecting a first DC input current into a signal input of the mixer; obtaining a first envelope measurement indicating an output signal envelope of the mixer in response to the first DC input current; injecting a second DC input current into the signal input of the mixer; obtaining a second envelope measurement indicating the output signal envelope of the mixer in response to the second DC input current; detecting an amount of LO leakage of the mixer based on at least a comparison of the first envelope measurement and the second envelope measurement and on an amount of the first DC input current; and iteratively adjusting a magnitude of the first DC input current and the second DC input current based on the comparison. 11. The method of claim 10 , wherein the first DC input current and second DC input current have about equal magnitude but opposite polarity. 12. The method of claim 10 , wherein detecting the amount of LO leakage further comprises determining a difference between the first envelope measurement and the second envelope measurement, and providing LO leakage compensation based on the difference. 13. The method of claim 10 , wherein the magnitude of the first DC input current and the second DC input current are iteratively adjusted based on the comparison until the first envelope measurement and the second envelope measurement are substantially equal. 14. An RF communication system comprising: a power amplifier configured to provide amplification to an RF signal; and a transceiver die configured to generate the RF signal, wherein the transceiver die comprises: a local oscillator (LO) configured to generate an LO signal; a mixer comprising a signal input configured to receive an input signal, a clock input configured to receive the LO signal, and an output configured to control the RF signal; and an LO leakage compensation circuit configured to obtain a first envelope measurement indicating a signal envelope at the output of the mixer based on injecting a first DC input current into the signal input, and to obtain a second envelope measurement indicating the signal envelope at the output of the mixer based on injecting a second DC input current into the signal input, wherein the LO leakage compensation circuit is further configured to detect an amount of LO leakage of the mixer based on at least comparing the first envelope measurement to the second envelope measurement and on an amount of the first DC input current, and wherein the LO leakage compensation circuit is further configured to iteratively adjust a magnitude of the first DC input current and the second DC input current based on the comparison. 15. The RF communication system of claim 14 , wherein the first DC input current and second DC input current have about equal magnitude but opposite polarity. 16. The RF communication system of claim 14 , wherein the LO leakage compensation circuit is further configured to detect the amount of LO leakage based on determining a difference between the first envelope measurement and the second envelope measurement. 17. The RF communication system of claim 14 , wherein the LO leakage compensation circuit is further configured to iteratively adjust the magnitude of the first DC input current and the second DC input current based on the comparison until the first envelope measurement and the second envelope measurement are substantially equal. 18. The RF communication system of claim 14 , wherein the LO leakage compensation circuit is further configured to compensate for LO leakage by controlling an input offset to the mixer based on an amount of LO leakage detected. 19. The RF communication system of claim 14 , wherein the LO leakage compensation circuit comprises an envelope detector configured to output the first envelope measurement and the second envelope measurement as DC measurements. 20. The RF communication system of claim 14 , wherein the LO leakage compensation circuit comprises a DAC configured to inject, during calibration, the first DC input current and the second DC input current, and to inject,