Detection and monitoring of changes in metallic structures using multimode acoustic signals

What is claimed is: 1. A method for detection and monitoring changes in an elongated metallic structure having a wall and an exterior surface, comprising: placing at least one acoustic transmitting transducer in vibrational communication with the exterior surface of said metallic structure; placing at least one receiving transducer in vibrational communication with the exterior surface of said metallic structure and spaced apart a chosen length from said at least one transmitting transducer; generating acoustic frequency chirp signals having a selected signal strength, spectral content, and duration; directing the chirp signals to said at east one transmitting transducer; producing a baseline signal by: receiving the vibrational signals generated in the wall of said metallic structure in response to the chirp signal by the receiving transducer; averaging a chosen number of received vibrational signals; and removing any DC component from the averaged received signals; producing a monitoring signal by: receiving the vibrational signals generated in the wall of said metallic structure in response to the chirp signal by the receiving transducer; averaging a chosen number of received vibrational signals; and removing any DC component from the averaged received signals; normalizing the monitoring signal to the baseline signal, whereby a maximum value of each of the baseline signal and the monitoring signal is equal to a selected value; performing short-time Fourier Transforms of the baseline and monitoring signals using chosen time and frequency window sizes, and time steps; taking the difference between the normalized monitoring signal and the normalized baseline signal, forming thereby a two-dimensional contour map; identifying at least one frequency-time mode pair in the contour map, where one feature of the at least one frequency-time mode pair has a maximum positive value and the corresponding feature of the at least one frequency-time mode pair has a maximum negative value; and calculating the amplitude difference between maximum positive value and the maximum negative value. 2. The method of claim 1 , further comprising the step of performing temperature compensation of the monitoring signal using the baseline signal as a comparison signal after said step of normalizing the monitoring signal to the baseline signal, thereby producing a temperature-compensated monitoring signal. 3. The method of claim 2 , wherein said step of performing temperature compensation comprises: dividing the monitoring signal into a chosen number of equal-duration time bins as a function of time; calculating the cross-correlation function for the monitoring signal and the baseline signal for each time bin; determining a time shift for each time bin by locating a peak of the cross correlation function for each time bin; and assigning a value of the monitoring signal to each bin corresponding to a value of the monitoring signal at the shifted time for that bin, whereby a temperature-compensated monitoring signal is generated. 4. The method of claim 1 , further comprising the step of filtering the received vibrational signals after said step of receiving the vibrational signals generated in the wall of said metallic structure in response to the chirp signal for both of said steps of producing a baseline signal and for producing a monitoring signal. 5. The method of claim 1 , wherein the chirp signals have a spectral content of between about 1 kHz and about 1 MHz. 6. The method of claim 1 , wherein said elongated metallic structure comprises at least one structure chosen from a length of metallic pipe, a metallic pipe assembly, a flange, an elbow, a tee, a reducer, a weld, a vessel, a storage tank, and a storage container. 7. The method of claim 1 , wherein the monitoring signal is produced subsequent to when the baseline signal is produced. 8. The method of claim 1 , further including the step of comparing the change in the monitoring signal for two adjacent pipe segments, whereby the localization of changes to said metallic structure within one of the segments is determined. 9. A method for detection and monitoring changes in an elongated metallic structure having a wall and an exterior surface, comprising: placing at least one acoustic transmitting transducer in vibrational communication with the exterior surface of said metallic structure; placing at least one receiving transducer in vibrational communication with the exterior surface of said metallic structure and spaced apart a chosen length from said at least one transmitting transducer; generating acoustic frequency chirp signals having a selected signal strength, spectral content, and duration; directing the chirp signals to said at least one transmitting transducer; producing a baseline signal by: receiving the vibrational signals generated in the wall of said metallic structure in response to the chirp signal by the receiving transducer; averaging a chosen number of received vibrational signals; and removing any DC component from the averaged received signals; producing a monitoring signal by: receiving the vibrational signals generated in the wall of said metallic structure in response to the chirp signal by the receiving transducer; averaging a chosen number of received vibrational signals; and removing any DC component from the averaged received signals; normalizing the monitoring signal to the baseline signal, whereby a maximum value of each of the baseline signal and the monitoring signal is equal to a selected value; taking the difference between the monitoring signal and the baseline signal; forming a difference signal; performing short-time Fourier transform of the difference signal using chosen time and frequency window sizes, and time steps, forming thereby a two-dimensional array in time and frequency; calculating the standard deviation of the short-time Fourier transform array along the time-axis for each frequency; and summing the standard deviations as a function of frequency. 10. The method of claim 9 , further comprising the step of performing temperature compensation of the monitoring signal using the baseline signal as a comparison signal after said step of normalizing the monitoring signal to the baseline signal, thereby producing a temperature-compensated monitoring signal. 11. The method of claim 10 , wherein said step of performing temperature compensation comprises: dividing the monitoring signal into a chosen number of equal-duration time bins as a function of time; calculating the cross-correlation function for the monitoring signal and the baseline signal for each time bin; determining a time shift for each time bin by locating a peak of the cross correlation function for each time bin; and assigning a value of the monitoring signal to each bin corresponding to a value of the monitoring signal at the shifted time for that bin, whereby a temperature-compensated monitoring signal is generated. 12. The method of claim 9 , further comprising the steps of filtering the received vibrational signals after said step of receiving the vibrational signals generated in the wall of said metallic structure in response to the chirp signal for both of said steps of producing a baseline signal and for producing a monitoring signal. 13. The method of claim 9 , wherein the chirp signals have a spectral content of between about 1 kHz and about 1 MHz. 14. The method of claim 9 , wherein said elongated metallic structure comprises at least one structure chosen from a length of metallic pipe, a metallic pipe assembly, a flange, an elbow, a