Atmospheric transmissometer using a modulated optical source

We claim: 1. A method comprising the steps of: detecting a modulated optical signal from an atmospheric propagation channel, wherein the modulated optical signal comprises an optical signal from an optical source modulated with a periodic signal at a modulation frequency greater than the bandwidth of turbulence within the atmospheric propagation channel; converting the detected modulated optical signal into a digitized electrical signal; determining the power spectral density (PSD) of the digitized electrical signal; extracting, from the PSD, the magnitude of the peak component at the modulation frequency f 0 , referred to as S atmos (f 0 ); and determining the effective optical depth τ eff of the atmospheric propagation channel using the magnitude of the peak component at the modulation frequency. 2. The method of claim 1 , wherein τ eff is determined according to the equation τ eff =ln [S clear (f 0 )/S atmos (f 0 )], where S clear (f 0 ) is the magnitude of a fundamental PSD component from a reference waveform taken in optimal clear-visibility conditions. 3. The method of claim 1 , wherein the modulation frequency is greater than about 1 kHz. 4. The method of claim 1 , wherein the step of converting the detected modulated optical signal into a digitized electrical signal comprises the steps of: converting the detected modulated optical signal into an electrical current; amplifying the electrical current and converting the amplified electrical current into a voltage; high-pass filtering the voltage to block a DC signal component of the voltage; and converting the filtered voltage into the digitized electrical signal using an analog-to-digital converter. 5. A method comprising the steps of: detecting a modulated optical signal from an atmospheric propagation channel, wherein the modulated optical signal comprises an optical signal from an optical source modulated with a periodic signal at a modulation frequency greater than the bandwidth of turbulence within the atmospheric propagation channel; converting the detected modulated optical signal into a digitized electrical signal; determining the root mean square (RMS) signal power of an AC component of the digitized electrical signal at the modulation frequency; using the determined RMS signal power to determine a received RMS signal power of the detected modulated optical signal at the modulation frequency; and determining the transmission of the atmospheric propagation channel by calculating a ratio between the received RMS signal power of the detected modulated optical signal and the expected RMS signal power of the detected modulated optical signal. 6. The method of claim 5 , wherein the step of determining the RMS signal power comprises the steps of: creating a filtered signal by filtering the digitized electrical signal with a bandpass filter centered at the modulation frequency; time-sampling the filtered signal during a defined time interval; squaring the time-sampled filtered signal; determining the mean of the squared time-sampled filtered signal; and determining the RMS signal power by taking the square root of the mean of the squared time-sampled filtered signal. 7. A system comprising: a modulator configured to modulate an optical signal from an optical source with a periodic signal at a modulation frequency greater than the bandwidth of turbulence within an atmospheric propagation channel; a transmitter configured to propagate the modulated optical signal into the atmospheric propagation channel; an optical detector configured to detect the propagated modulated optical signal from the atmospheric propagation channel; an AC coupled detector, operatively connected to the optical detector, configured to convert the propagated modulated optical signal into an electrical voltage; and an analog-to-digital converter (ADC), operatively connected to the AC coupled detector, configured to digitize the electrical voltage; and an optical depth processing subsystem, operatively connected to the ADC, comprising averaging and signal conditioning circuitry, PSD processing circuitry operatively connected to the averaging and signal conditioning circuitry, and a bandpass filter operatively connected to the PSD processing circuitry. 8. The system of claim 7 further comprising an atmospheric transmission processing subsystem operatively connected to the ADC. 9. The system of claim 8 , wherein the atmospheric transmission processing subsystem comprises: a bandpass filter; time sample processing (TSP) circuitry operatively connected to the bandpass filter; and root mean square processing circuitry operatively connected to the TSP circuitry. 10. The system of claim 7 , wherein the optical detector comprises a telescope with a narrowband optical bandpass filter focused on a detector. 11. The system of claim 7 , wherein the optical source is a laser. 12. The system of claim 7 , wherein the optical detector comprises an avalanche photodiode.