4. Средняя пространственная частотная характеристика рефлектограммы с двухимпульсным зондирующим сигналом с частотным разнесением

The average spatial backscattered intensity spectrum of the OTDR with dual-pulse diverse frequency probe signal

Let us derive the expression for the average power spectral characteristic of the bandpass OTDR trace 34 or 35 with the carrier frequency and random amplitude and phase modulation. Once again we calculate the ACF of the random process which in this case is the square of electric fields sum 30 and 31 i.e. . Like before we will use the Gaussian moment theorem [11] for the complex scattering coefficients , and also consider the lack of correlation over the ensemble between the fields, scattered by the different parts of the dual-pulse and . The AKF is found to be a sum of 16 terms, where due to the just mentioned facts only 6 of them result in nonzero contribution, as a result we have got:

3636\* MERGEFORMAT ().

The ACF 36 also depends only on the coordinate difference and so the process is wide-sense stationary. Applying Wiener–Khinchin theorem the Fourier transform of 36 results in the PSD of the random process _:

3737\* MERGEFORMAT ().

The linearly filtered processes and are statistically equal and the final PSD will take the form:

3838\* MERGEFORMAT (),

where the convolution was found in the second part of the paper for the probe pulses of different amplitude shapes, the spatial frequency is defined as .

Thus the PSD of the random intensity fluctuation process , when the dual-pulse probe signal with different carrier frequencies of the first and the second parts of the pair consists of several components: the first term in 38 represents the constant part in the received intensity, the second term correspond to the PSDs of the intensity fluctuation processes, is associated with the fields backscattered by the first and the second parts of the dual-pulse, this PSD is concentrated near zero frequency and defined previously 20, the third and the fourth terms correspond to the PSDs of interference intensity fluctuations, associated with the interference of the fields backscattered by the first and the second parts of the dual-pulse, they have the similar form as the PSD near zero frequency, but due to harmonic component in the ACF 36 they are concentrated near positive and negative frequency: .

As before the transition to the time domain could be made by multiplication of the corresponding spatial frequencies by group velocity of light , so the PSD of the random process is concentrated near zero frequency and near frequencies , where .

It is now proved that using of dual-pulse with different carrier frequencies of the first and the second parts leads to appearance of three equally shaped PSDs where two PSDs are frequency shifted. The PSD that experience a positive frequency shift can be interpreted as power spectrum of the banpass quasi-harmonic signal, as mentioned before. One can also say that 38 shows the average spatial power spectrum of the OTDR intensity trace with dual-pulse diverse frequency probe signal.

The particular form of the spectral characteristic 20 and 38 is defined by the shape of the probe pulse , for the pulses of rectangular or Gaussian shape the spectral characteristics could be derived using 22 и 26.