Binary phase shift keying (BPSK) on orthogonal carriers for multi-channel IM-CW CO2 absorption or Lidar/Radar/Sonar mapping applications

What is claimed is: 1. A method for generating a modulation waveform in a ranging system, comprising: generating two or more orthogonal carrier waveforms; modulating the two or more orthogonal carrier waveforms with a Pseudo Noise (PN) code; combining the modulated two or more orthogonal carrier waveforms to produce a combined waveform; transmitting the combined waveform toward a target; receiving a reflected signal from the target; selecting a reference signal form; demodulating the reflected signal using the selected reference signal form; determining at least one of a range and differential absorption of the target based on the demodulation; and wherein the PN code is the Maximum Length (ML)-sequence having P repeats; wherein the period of each repeat is τ; and wherein the two or more orthogonal carrier waveforms have respective center frequencies equal to a respective mutually exclusive integer divided by 2Pτ. 2. The method of claim 1 , wherein the ML-sequence is oversampled. 3. The method of claim 2 , wherein the modulated two or more orthogonal carrier waveforms take on the form for the first channel σ first (n) and second channel σ second (n) of: σ first ( n )=(2 Z ( n )−1)cos(2π n f first /f s ), σ second ( n )=(2 Z ( n )−1)cos(2π n f second /f s ), wherein Z(n) is the oversampled ML-sequence, f first is the first carrier frequency, f second is the second carrier frequency, f s is the sample rate. 4. The method of claim 3 , wherein the reference signal Γ(n) form is: Γ first ( n )=(2 Z ( n )−1)exp(2π in f first /f s ), Γ second ( n )=(2 Z ( n )−1)exp(2π in f second /f s ). 5. The method of claim 3 , wherein the reference signal Γ(n) form is: Γ′ first ( n )= Z ( n )exp(2π in f first /f s ), Γ′ second ( n )= Z ( n )exp(2π in f second /f s ). 6. The method of claim 3 , wherein the first channel is the on-line channel and the second channel is the off-line channel. 7. The method of claim 1 , wherein the ranging system is a Lidar system, Radar system, or Sonar system. 8. The method of claim 1 , wherein the modulating of the two or more orthogonal carrier waveforms modulates the two or more orthogonal carrier waveforms with the same Pseudo Noise (PN) code. 9. A system, comprising: A ranging system; and a computing device connected to the ranging system, the computing device comprising a processor configured with processor executable instructions to perform operations comprising: generating two or more orthogonal carrier waveforms; modulating the two or more orthogonal carrier waveforms with a Pseudo Noise (PN) code; combining the modulated two or more orthogonal carrier waveforms and transmitting the combined two or more orthogonal carrier waveforms toward a target; receiving a reflected signal from the target; selecting a reference signal form; demodulating the reflected signal using the selected reference signal form; and determining at least one of a range and differential absorption of the target based on the demodulation; and wherein the PN code is the Maximum Length (ML)-sequence having P repeats; wherein the period of each repeat is τ; and wherein the two or more orthogonal carrier waveforms have respective center frequencies equal to a respective mutually exclusive integers divided by 2Pτ. 10. The system of claim 9 , wherein the ML-sequence is oversampled. 11. The system of claim 9 , wherein the ranging system is a Lidar system, Radar system, or Sonar system. 12. A system, comprising: a ranging system; and a computing device connected to the ranging system, the computing device comprising a processor configured with processor executable instructions to perform operations comprising: generating two or more orthogonal carrier waveforms; modulating the two or more orthogonal carrier waveforms with a Pseudo Noise (PN) code; transmitting the modulated two or more orthogonal carrier waveforms toward a target; receiving a reflected signal from the target; selecting a reference signal form; demodulating the reflected signal using the selected reference signal form; and determining at least one of a range and differential absorption of the target based on the demodulation; wherein PN code is the Maximum Length (ML)-sequence; wherein the ML-sequence is oversampled; and wherein the modulated two or more orthogonal carrier waveforms take on the form for the first channel σ first (n) and second channel σ second (n) of: σ first ( n )=(2 Z ( n )−1)cos(2π n f first /f s ), σ second ( n )=(2 Z ( n )−1)cos(2π n f second /f s ), wherein Z(n) is the oversampled ML-sequence, f first is the first carrier frequency, f second is the second carrier frequency, f s is the sample rate. 13. The system of claim 12 , wherein the reference signal Γ(n) form is: Γ first ( n )=(2 Z ( n )−1)exp(2π in f first /f s ), Γ second ( n )=(2 Z ( n )−1)exp(2π in f second /f s ). 14. The system of claim 12 , wherein the reference signal f ( n ) form is: Γ′ first ( n )= Z ( n )exp(2π in f first /f s ), Γ′ second ( n )= Z ( n )exp(2π in f second /f s ). 15. The system of claim 12 , wherein the first channel is the on-line channel and the second channel is the off-line channel.