Sampling threshold detector for direct monitoring of RF signals

What is claimed: 1. A sampling threshold detector for monitoring a radio frequency (RF) signal in a receiver having a mixer for generating a baseband intermediate frequency (IF) signal from the RF signal, the IF signal having a band of interest, the detector comprising: an input for receiving a threshold voltage value, the threshold voltage value for comparing to an amplitude of the RF signal; a clocked sampler configured to sample the RF signal at a sampling clock frequency (f SAMP ) and to generate a status signal when the amplitude exceeds the threshold voltage value, wherein the sampling clock frequency (f SAMP ) produces kickback intermodulation products at an output of the mixer, and the sampling clock frequency (f SAMP ) is chosen based on a local oscillator frequency (f LO ) of the mixer in order to position the kickback intermodulation products outside of the band of interest of the IF signal. 2. The sampling threshold detector of claim 1 wherein the clocked sampler comprises a single high bandwidth sampler. 3. The sampling threshold detector of claim 1 wherein the sampling clock frequency (f SAMP ) is determined based on the local oscillator frequency (f Lo) and a baseband intermediate frequency (f IF ). 4. The sampling threshold detector of claim 3 wherein the sampling clock frequency (f SAMP ) is determined according to f SAMP =f LO +N*f IF , where N is an integer that results in a positive sampling frequency within an acceptable operating range of the clocked sampler. 5. The sampling threshold detector of claim 1 further comprising a machine readable memory storing a set of candidate sampling clock frequency values from which the sampling clock frequency for the clocked sampler is selected. 6. The sampling threshold detector of claim 1 further comprising: a passive attenuator configured to receive the RF signal to monitor higher voltages to provide a reverse path attenuation of noise generated by the clocked sampler; and a continuous time pre-amplifier configured to receive the output of the passive attenuator and to subtract the threshold voltage value therefrom, wherein the threshold voltage value is provided by a static programmable threshold voltage, and to provide a resulting signal to the clocked sampler as the RF signal to be sampled. 7. The sampling threshold detector of claim 6 further comprising: a filter provided before the continuous time pre-amplifier and configured to capture a peak of the RF signal within a particular frequency band. 8. The sampling threshold detector of claim 1 wherein the clocked sampler comprises a single high bandwidth sampler directly attached to the RF signal, enabling direct monitoring of the RF signal. 9. A method of sampling threshold detection comprising: monitoring a radio frequency (RF) signal using a single high bandwidth clocked sampler in a receiver having a mixer for generating a baseband intermediate frequency (IF) signal from the RF signal, the IF signal having a band of interest; selecting a sampling clock frequency (f SAMP ) based on a local oscillator frequency (f LO ); sampling an amplitude of the RF signal at the selected sampling clock frequency (f SAMP ); and generating a status signal when the amplitude exceeds a threshold voltage value, wherein the sampling clock frequency (f SAMP ) produces kickback intermodulation products at an output of the mixer, and selecting the sampling clock frequency (f SAMP ) comprises positioning the kickback intermodulation products outside the band of interest of the IF signal. 10. The method of claim 9 further comprising: pre-calculating intermodulation products for each signal to be received; and selecting the sampling clock frequency additionally based on the pre-calculated intermodulation products. 11. The method of claim 10 further comprising: calculating at run-time intermodulation products for each signal to be received; and selecting the sampling clock frequency additionally based on the pre-calculated intermodulation products. 12. The method of claim 9 wherein a final folded results of the kickback intermodulation products are positioned out of band, or are of low enough power in-band so as to be inconsequential. 13. The method of claim 9 wherein the sampling clock frequency is determined based on the local oscillator frequency (f LO ) and a baseband intermediate frequency (f IF ). 14. The method of claim 13 wherein the sampling clock frequency (f SAMP ) is determined according to f SAMP =f LO +N*f IF , where N is an integer that results in a positive sampling frequency within the acceptable operating range of the clocked sampler. 15. The method of claim 9 further comprising storing a set of candidate sampling clock frequency values from which the sampling clock frequency for the single high bandwidth clocked sampler is selected. 16. The method of claim 9 further comprising: receiving the RF signal to monitor higher voltages to provide a reverse path attenuation of noise generated by the clocked sampler; and subtracting the threshold voltage value from the RF signal, wherein the threshold voltage value is provided by a static programmable threshold voltage, to provide a resulting signal to the clocked sampler as the RF signal to be sampled. 17. The method of claim 9 further comprising: capturing a peak of the RF signal within a particular frequency band. 18. The method of claim 9 further comprising directly monitoring the RF signal by sampling the RF signal using the single high bandwidth clocked sampler directly attached to the RF signal.