Multi-tone continuous wave detection and ranging

What is claimed is: 1. A range detection and velocimetry apparatus ( 1000 ) comprising: a. a transmitter ( 1002 ) capable of producing a multi-tone signal comprising a plurality of simultaneous radiofrequency (RF) tones ( 1001 ) and a plurality of corresponding simultaneous RF frequencies, wherein the plurality of RF tones ( 1001 ) comprises a sum of multiple single side band modulation or double side band modulation; b. a transmit antenna or optics ( 1003 ) operatively coupled to the transmitter ( 1002 ) capable of generating a transmitted signal ( 1004 ) modulated with the plurality of RF tones ( 1001 ) to a target ( 1005 ); c. a receiver antenna or optics ( 1007 ) capable of receiving a reflected signal ( 1006 ) from the target ( 1005 ) based on the transmitted signal ( 1004 ); d. a local oscillator ( 1008 ) capable of generating a reference signal ( 1009 ); e. a beam combiner ( 1010 ) capable of receiving the reflected signal ( 1006 ) from the receiver antenna ( 1007 ) and the reference signal ( 1009 ) from the local oscillator ( 1008 ) to generate a superposition signal ( 1011 ); f. a photodetector ( 1012 ) capable of receiving the superposition signal ( 1011 ) to be converted into an electrical current; and g. an electronic processing unit ( 1013 ) comprising a processor capable of executing computer-readable instructions and a memory component comprising a plurality of computer-readable instructions comprising: i. accepting the reflected signal and the reference signal; ii. generating a superposition ( 1011 ) of the reflected signal and the reference signal, wherein generating the superposition ( 1011 ) generates beating tones; iii. determining, by a plurality of phases of the beating tones or relative amplitude variations of tones, a broad range to a target ( 1005 ); iv. identifying a Doppler shift of the superposition signal ( 1011 ); v. estimating, by the Doppler shift and the plurality of beating tones, a velocity of the target ( 1005 ); and vi. determining, based on the phase, frequency and amplitude of plurality of beating tones and the broad range to the target ( 1005 ), a precise range to the target ( 1005 ). 2. The apparatus ( 1000 ) of claim 1 , wherein the plurality of RF tones ( 1001 ) comprise a sum of multiple RF frequency tones such that the plurality of RF tones ( 1001 ) are non-harmonic, harmonic of a first common RF signal, subharmonic of a second common RF signal, phase-locked, or a combination thereof. 3. The apparatus ( 1000 ) of claim 1 , wherein the plurality of RF tones ( 1001 ) comprise a broadband RF signal such as subcarrier modulation signals with distinguishable frequency characteristics that are suitable for phase, frequency, and amplitude measurement at a selected part of the spectrum of the apparatus ( 1000 ). 4. The apparatus ( 1000 ) of claim 1 , wherein the transmitter ( 1002 ) comprises a CW or quasi CW electromagnetic signal generator selected from a group comprising laser, an RF generator, a TeraHertz (THz) generator, or a source operating at any frequency of the electromagnetic spectrum with direct modulation or external modulation capability to encode the plurality of RF tones ( 1001 ). 5. The apparatus ( 1000 ) of claim 1 , wherein the local oscillator ( 1008 ) comprises a fraction of the transmitter ( 1002 ) before or after RF modulation. 6. The apparatus ( 1000 ) of claim 1 further comprising a frequency shifter capable of generating the reference signal to compensate for at least a portion of the Doppler shift. 7. The apparatus ( 1000 ) of claim 1 , wherein the reference signal comprises a fixed frequency and a fixed phase difference from the transmitter ( 1002 ) to compensate for at least a portion of the Doppler shift. 8. The apparatus ( 1000 ) of claim 1 , wherein the reference signal comprises an independent unmodulated CW or quasi-CW signal. 9. The apparatus ( 1000 ) of claim 1 , wherein the electronic processing unit ( 1013 ) further comprise a data acquisition system, an analog filter, a digital filter, a RF spectrum analyzer, a frequency counter, a phase detector, and an amplitude detector. 10. The apparatus of claim 1 , wherein determining the precise range to the target ( 1005 ) comprising a triangulation algorithm utilizing phases of the plurality of beating tones and relative phase differences between plurality of beating tones. 11. The apparatus of claim 1 , wherein determining the precise range further comprising using time-of-arrival information of pulses of the multi-tone signal. 12. The apparatus of claim 1 , wherein determining the precise range further comprising generating, by the superposition signal ( 1011 ), a plurality of amplitude variations due to differences in phase accumulations and then fitting, by the plurality of amplitude variations, the superposition signal ( 1011 ) to a sine wave. 13. The apparatus ( 1000 ) of claim 1 , wherein the memory component further comprises instructions for: a. mixing, by an analog or digital mixer, a selected set of the plurality of beating tones to cancel common noise terms and perform ranging of the target ( 1005 ) beyond a coherence length of the transmitter ( 1002 ). 14. A RADAR ranging and velocimetry apparatus ( 1000 ) comprising: a. a transmitter ( 1002 ) capable of generating a multi-tone signal comprising a plurality of simultaneous radiofrequency (RF) tones in a continuous wave (CW) signal, a quasi-CW signal, or a TeraHertz signal, and a plurality of corresponding simultaneous RF frequencies; b. a local oscillator ( 1008 ) capable of using at least a portion of the multi-tone signal from the transmitter ( 1002 ) as a reference signal; and c. an electronic processing unit ( 1013 ) comprising a processor capable of executing computer-readable instructions and a memory component comprising a plurality of computer-readable instructions comprising: i. accepting the multi-tone signal and the reference signal; ii. generating a superposition ( 1011 ) of the multi-tone signal and the reference signal, wherein generating the superposition ( 1011 ) generates beating tones; iii. determining, by a plurality of phases of the beating tones, a broad range to a target ( 1005 ); iv. identifying a Doppler shift of the superposition signal ( 1011 ); v. estimating, by the Doppler shift and the plurality of beating tones, a velocity of the target ( 1005 ); and vi. determining, based on the plurality of beating tones and the broad range to the target ( 1005 ), a precise range to the target ( 1005 ). 15. The apparatus of claim 14 , wherein determining the precise range to the target ( 1005 ) comprising a triangulation algorithm utilizing phases of the plurality of beating tones and utilizing relative changes in phases of the plurality of beating tones. 16. The apparatus of claim 14 , wherein determining the precise range further comprising using time-of-arrival information of pulses of the multi-tone signal. 17. The apparatus ( 1000 ) of claim 14 , wherein the reference signal comprises an unmodulated CW or quasi-CW signal. 18. A global position and navigation apparatus ( 1000 ) comprising: a. a remote transmitter ( 1002 ) capable of generating a multi-tone signal comprising a plurality of simultaneous radiofrequency tones in a continuous wave (CW) signal, a quasi-CW signal, or a TeraHertz signal, and a plurality of corresponding simultaneous RF frequencies; b. a local receiver ( 1007 ) comprising a local oscillator ( 1008 ) capable of generating an independent unmodulated CW or quasi-CW signal as a reference signal; c. a photodetect