Low power harmonic wake up radio

What is claimed is: 1. An apparatus for converting a radio frequency (RF) signal with multiple local oscillator phases, the apparatus comprising: a receiver mixer comprising: an input configured to receive an RF signal, an output, and at least three sets of switches, wherein each set of switches is configured to be connected to the input to receive the RF signal and to selectively pass a portion of the RF signal to the output, wherein each set of switches is configured to be activated at a different phase of a local oscillator to effect passing of different phases of the RF signal to the output using a local oscillator frequency which is an integer submultiple of the frequency of the RF signal; wherein each set of switches comprises: a first pair of switches configured to receive a first phase of a local oscillator to thereby receive the RF signal with a first phase shift; and a second pair of switches configured to receive a second phase of the local oscillator to thereby receive the RF signal with a second phase shift; wherein the first and second phases are different among the respective sets of switches. 2. The apparatus of claim 1 further comprising a controller configured to receive an output from the receiver mixer and to wake up the apparatus from a low power mode in response to receiving a harmonic or subharmonic of a main receiver frequency for the apparatus. 3. The apparatus of claim 1 wherein the first pair of switches within each set are configured to receive the first phase of the local oscillator are connected to receive the first phase of the local oscillator at respective gates of the first pair of switches, and wherein the second pair of switches within each set are configured to receive the second phase of the local oscillator are connected to receive the second phase of the local oscillator at respective gates of the second pair of switches. 4. The apparatus of claim 3 wherein the first and second pairs of switches are connected to provide equal loading to a local oscillator network. 5. The apparatus of claim 1 wherein a drain/source from a first switch of the first pair of switches configured to receive the first phase is electrically connected to a first node of the output and to a drain/source from a first switch of the second pair of switches configured to receive the second phase, and wherein a second node of the output, different from the first node, is electrically connected to a drain/source from a second switch of the first pair of switches configured to receive the first phase and to a drain/source from a second switch of the second pair of switches configured to receive the second phase. 6. The apparatus of claim 1 wherein the receiver mixer is configured to receive multi-phase square waveforms from the local oscillator to receive a signal at a first RF frequency and to create a selective harmonic null at a second RF frequency. 7. The apparatus of claim 1 further comprising a phase controller operatively connected to a local oscillator network and configured to control opening and closing of individual switches of the at least three sets of switches to control phasors of the local oscillator received by the receiver mixer. 8. The apparatus of claim 1 further comprising: at least one antenna operatively connected to provide the RF signal to the input; a baseband processing unit connected to receive signals from the output, wherein a subset of the baseband processing unit is used for fast detection of a wake up signal. 9. The apparatus of claim 8 further comprising: a second receiver mixer comprising: a second mixer input configured to receive a second RF signal that is one of the RF signal from the antenna or a different RF signal from a second antenna, a second mixer output, and at least two sets of switches connected to selectively pass a portion of the second RF signal to the second mixer output, with individual ones of the sets of switches connected to be activated at different phases of the local oscillator to effect passing of different phases of the second RF signal to the second mixer output; wherein individual ones of the at least two sets of switches comprise: two switches configured to provide a first phase from the local oscillator network to the receiver mixer to receive the second RF signal with a first second-receiver phase shift; another two switches configured to provide a second phase from the local oscillator network that is a harmonic of the first phase to the receiver mixer to receive the second RF signal with a second second-receiver phase shift; wherein the baseband processing unit is configured to operate in a time multiplexed fashion between the receiver mixer and the second receiver mixer. 10. The apparatus of claim 9 wherein a same clock generator network is connected to provide phases from the local oscillator to both the receiver mixer and the second receiver mixer. 11. The apparatus of claim 9 further comprising a wake up radio receiver configured to operate at a first carrier frequency F 1 and a main radio receiver configured to operate at a second carrier frequency F 2 where F 1 =N*F 2 ; wherein N is an integer and where the local oscillator's frequency is one or an integral submultiple of F 1 or F 2 , whichever is lowest. 12. The apparatus of claim 1 further comprising a local oscillator network configured to provide the local oscillator, wherein the local oscillator network comprises a ring oscillator. 13. A method of converting among multiple phases in a radio frequency (RF) signal setting, the method comprising: receiving first and second RF signals by first and second receiver mixers respectively, each receiver mixer having at least three sets of switches; receiving different phases of a local oscillator at different gates of each set of switches to effect opening and closing of the switches; in response to receiving the different phases, outputting, by the receiver mixer, a first output current proportional to the first RF signal and creating a selective harmonic null at a second RF frequency and outputting, by the second receiver mixer, a second output current proportional to the second RF signal and creating a selective harmonic at a second RF frequency. 14. The method of claim 13 further comprising: receiving one or both of the first RF frequency and the second RF frequency at a baseband processing unit; detecting at the baseband processing unit receipt of a wake up signal at one of the first frequency and the second frequency; and in response to detecting the wake up signal, waking up a radio receiver including the at first and second receiver mixers and configuring the radio receiver to receive a primary radio signal that uses one of the first RF frequency and the second RF frequency. 15. The method of claim 14 further comprising operating the baseband processing unit in a time multiplexed fashion between individual ones of the first and second receiver mixers. 16. The method of claim 14 further comprising creating a selective harmonic null by combining outputs of the first and second receiver mixers at an interface between the first and second receiver mixers and the baseband processing unit. 17. The method of claim 14 further comprising creating a selective harmonic null by combining outputs of the baseband processing unit and at least one other baseband processing unit either in an analog domain or a digital domain. 18. The method of claim 13 further comprising opening and closing individual switches of the at least three sets of swi