Acoustic measurement infrastructure method and system for process monitoring, diagnostics, and prognostics

1 . A method of operating sensors on or within a system, the method comprising: continuously capturing analog signal data from at least one sensor and digitizing the signal data; applying a Short Time Fast Fourier Transform (STFFT) to the digitized data within a selected time interval having a duration (T) to obtain a time-frequency spectrum; selecting at least one harmonic frequency to monitor from the time-frequency spectrum; recording an amplitude, frequency, and phase for the selected frequency from the time-frequency spectrum; applying the STFFT to the digitized data within a shifted time interval having a duration (T) and shifted by a percentage (X %) of T; recording an amplitude, frequency, and phase of the at least one harmonic frequency selected to be monitored from the time-frequency spectrum for the shifted time interval; and determining whether the analog signal data have changed and whether a condition is causing the analog signal data to change responsive to monitoring the amplitude, frequency, and phase data from the shifted time interval and the amplitude, frequency, and phase data for the previous time intervals. 2 . The method of claim 1 , wherein the system comprises a nuclear reactor core, and further comprising placing a plurality of sensors generating the analog signal data at different locations on or within the structure of the nuclear reactor core. 3 . The method of claim 1 , further comprising: recursively applying the STFFT by using an output from a previous STFFT and performing another STFFT and obtain additional amplitude, phase and frequency data; and determining whether the recursive analog signal data have changed and whether a condition is causing the recursive analog signal data to change responsive to monitoring the amplitude, frequency, and phase data from the shifted time interval and the amplitude, frequency, and phase data for the previous time intervals. 4 . The method of claim 1 , further comprising multiplexing outputs from the plurality of sensors for processing by a single receiver. 5 . The method of claim 1 , further comprising Fast Fourier transform (FFT) applied to the digitized signal data to obtain a baseline frequency spectrum. 6 . The method of claim 5 , further comprising determining a harmonic to monitor within the baseline frequency spectrum. 7 . The method of claim 6 , wherein the harmonic selected to be monitored is a fundamental harmonic. 8 . The method of claim 1 , wherein the at least one harmonic frequency selected to monitor is the frequency with the largest amplitude. 9 . An acoustic measurement infrastructure (AMI) system, comprising: at least one sensor; and a data acquisition system including a processor operably coupled to the at least one sensor, the processor configured to: acquire analog signal data from at least one sensor; digitize the analog signal data; convert the digitized analog signal data to obtain frequency information for the digitized signal data; select at least one harmonic frequency to monitor from the frequency information; record an amplitude, frequency, and phase for the selected frequency from the frequency information; apply an STFFT to the raw digitized data within a shifted time interval having a duration (T) and shifted by a percentage (X %) of T; record an amplitude, frequency, and phase of at least one harmonic frequency selected to be monitored from the time-frequency spectrum for the shifted time interval; and determine whether the analog signal data have changed and whether a condition is causing the analog signal data to change responsive to monitoring the amplitude, frequency, and phase data from the shifted time interval and the amplitude, frequency, and phase data for the previous time intervals. 10 . The AMI system of claim 9 , wherein the processor is further configured to create and store an event log to maintain a list of system events that have occurred for a system data acquisition session. 11 . The AMI system of claim 9 , wherein the at least one sensor includes at least one of an acoustic based sensor, an electromagnetic based sensor, or an intrinsic sensor configured to generate a signal derived from pressure pulses of a component. 12 . The AMI system of claim 9 , wherein the processor is further configured to recursively apply the STFFT to the previous STFFT amplitude, phase, or frequency outputs within a shifted time interval having a duration (T) and shifted by a percentage (X %) of T. 13 . The AMI system of claim 9 , further comprising an electronic display operably coupled with the processor, wherein the processor is further configured to display results of the STFFT to the digitized data on the electronic display. 14 . The AMI system of claim 9 , further comprising a memory device operably coupled with the processor, wherein the STFFT results are stored in a file in the memory device. 15 . The AMI system of claim 9 , wherein the processor is further configured to: apply an STFFT to the digitized data to generate a baseline spectrum; and compare a subsequent STFFT of the digitized data to the baseline spectrum to determine a deviation therefrom. 16 . The AMI system of claim 15 , wherein the processor is further configured to control an operational feature of a nuclear reactor responsive to determining the deviation. 17 . The AMI system of claim 15 , further comprising a memory device operably coupled with the processor, wherein the STFFT results are stored in a file in the memory device. 18 . The AMI system of claim 9 , wherein the at least one sensor is configured to detect signals generated internally within a nuclear reactor selected from the group consisting of transmission of fluids and moving/vibrating mechanical structures. 19 . The AMI system of claim 18 , wherein the condition is at least one of a temperature, a neutron flux, a gamma flux, an axial extension of a structure, a fuel-dimension change, or fission gases within the nuclear reactor. 20 . The AMI system of claim 18 , wherein the at least one sensor is coupled to an external structure of the nuclear reactor selected from the group consisting of a pressure vessel, vessel piping, a flange, and a hydraulic shuttle irradiation system.