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Infrasound Technology Workshop Bermuda, 2008

Infrasound Technology Workshop Bermuda, 2008. Enhancements to the CTBTO operational automatic infrasound processing system David Brown, Nicolas Brachet , and Ronan Le Bras International Data Centre Software Applications Section Preparatory Commission for the Comprehensive

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Infrasound Technology Workshop Bermuda, 2008

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  1. Infrasound Technology WorkshopBermuda, 2008 Enhancements to the CTBTO operational automatic infrasound processing system David Brown, Nicolas Brachet, and Ronan Le Bras International Data Centre Software Applications Section Preparatory Commission for the Comprehensive Nuclear-Test-Ban Treaty Organization Provisional Technical Secretariat Vienna International Centre P.O. Box 1200, A-1400 Vienna, Austria E-mail: David.Brown@ctbto.org E-mail: Nicolas.Brachet@ctbto.org

  2. Overview Two enhancements to the IDC automatic infrasound processing system are being tested: • Station Noise characterization • purpose • requirements • method • testing • real data • still to be done • Infrasound amplitude determination • purpose • procedure • testing • still to be done Infrasound Technology Workshop, Bermuda

  3. Station Noise Characterization Purpose • Provide a method for users of IDC external products to determine station ‘noise’ levels. • will be useful in determining network detection capability • Provide an additional utility for internal PTS station performance monitoring. Requirements • Noise data for each station would need to reveal: • seasonal or monthly variations • day and night time variations • External/Internal Users need to access the binary data and plot files. Method • Employ Power Spectral Density methods • along the lines of the analysis of Bowman et al. • will run automatically on incoming data and update seasonal or monthly averages. Infrasound Technology Workshop, Bermuda

  4. Station Noise Characterization Choose 4 hourly periods for each station: • 03:30-04:30, 09:30-10:30, 15:30-16:30, 21:30-22:30 local time Choose a FFT window function: • References: • Harris 1978: On the use of Windows for Harmonic Analysis with the Discrete Fourier Transform Proc. IEEE Vol 66, No. 1, 1978. • Heinzel 2002: https://www.lisa.uni-hannover.de/?page=publikationen&sub=publikationen&type=publi&publitype=3&lang=en • Require moderate frequency resolution • Require good amplitude resolution Infrasound Technology Workshop, Bermuda

  5. Station Noise Characterization Windowing: • a significant part of the PSD measurement process no window equivalent to High Frequencies Infrasound Technology Workshop, Bermuda

  6. Station Noise Characterization Windowing: • non-periodic nature of the windowing process leads to spectral leakage • frequency content and spectral leakage controlled by the transform of the window function: ‘Dirac Comb’ ‘Dirac Comb’ spectral leakage Infrasound Technology Workshop, Bermuda

  7. Station Noise Characterization Windowing: • Ensure the side lobes of the Window Transform are below the noise floor of the sensor system (microbarometer + filter): • MB2005: approx. 10-7 Pa2/Hz → Nutall4a window (Heinzel et al, 2002) • Chaparral : approx. 10-9 Pa2/Hz → Nutall4c window (Heinzel et al, 2002) Infrasound Technology Workshop, Bermuda

  8. Station Noise Characterization ‘Welch’ PSD method • Divide hourly data into overlapping 3 minute windows • without averaging, the variance of the PSD for a individual frequency picket is of the order of the PSD at that frequency. • 20 Hz sample-rate →3600 samples or 1800 frequency pickets: • 0.0000000 Hz→ DC • 0.0015625 Hz → 640 sec period • 0.0031250 Hz → 320 sec period • … • 9.9984375 Hz one hour Infrasound Technology Workshop, Bermuda

  9. Station Noise Characterization • Number of overlapping windows is determined by the window ROV (Relative Overlap Value, see Heinzel et al, 2002), indicated in the following Table: Infrasound Technology Workshop, Bermuda

  10. Station Noise Characterization • Remove linear trend from each 3 minute data segment • otherwise DC component may generate spectral leakage • Multiply data segment with window function • remember to divide by the processing gain, ie, multiply by • Apply FFT • Determine PSD at frequency picket i according to the rule: • average the PSD for all sub windows and take the log of the average • could consider taking the average of the log’s, but Bowman et al’s work suggests not log-normal distribution. N = samples; D = sample frequency; b = ENBW • Accommodates the accumulation ability • of the main lobe for white noise Infrasound Technology Workshop, Bermuda

  11. Station Noise Characterization Testing • use artificial digitizer noise • Digitizing process generates (white) noise power spectral density: • (see Lyons, 1997; Heinzel, 2002) • is the Pa corresponding to one least-significant bit • is the sampling frequency, Hz. • Example: with Infrasound Technology Workshop, Bermuda

  12. Station Noise Characterization Testing • use 4 different windows: • Rectangular (no window) • Hanning • Nutall4a (Heinzel 2002) • HFT248D (Heinzel 2002) -8.079 -8.079 Infrasound Technology Workshop, Bermuda

  13. Station Noise Characterization Testing • have initiated a series of ‘blind-tests’ with Lars Ceranna at BGR to assess the validity of the method. • using randomly chosen IMS array data • IS07, IS27, IS32, IS55 • 2007-2008, 1st day of the month 4 times per day. • will ‘manipulate’ the PSD methods until we get the same answers. • compare with known published results: Bowman et al. Infrasound Technology Workshop, Bermuda

  14. Station Noise Characterization Real Data • PSD noise data is being determined automatically for every IMS infrasound station. • Two outputs are generated: • Output 1: log-average PSD data for the given hours • binary data file + plot (.ps) • should be free of contamination from spectral leakage • have complete hourly and monthly-averaged PSD information for each station for September 2008 , October 2008 and the current part of November 2008. • for each 8-element station the data growth rate is : • 4 x (80000 + 130000 ) bytes = 840Kb • (.jpg binary) Infrasound Technology Workshop, Bermuda

  15. Station Noise Characterization Real Data • PSD noise data is being determined automatically for every IMS infrasound station. • Two outputs are generated: • Output 1: log-average PSD data for the given hours • binary data file + plot (.ps) • should be free of contamination from spectral leakage • have complete hourly and monthly-averaged PSD information for each station for September 2008 , October 2008 and the current part of November 2008. • for each 8-element station the data growth rate is: • 4 x (80000 + 130000 ) bytes = 520Kb / day (approx. 5 Gb per year for 60-stations) • (generate graphic on the fly) Infrasound Technology Workshop, Bermuda

  16. Station Noise Characterization Real Data • PSD noise data is being determined automatically for every IMS infrasound station. • Two outputs are generated: • Output 2: monthly-average PSD data + variance smoothed using an 11-point 6-order Savitzky-Golay Filter for the specified times. • Savitzky-Golay filter • polynomial regression that preserves features of the distribution such as relative maxima, minima and width • have complete hourly and monthly-averaged PSD information for each station for September 2008 , October 2008 and the current part of November 2008. Infrasound Technology Workshop, Bermuda

  17. Station Noise Characterization Still to be done • incorporate as part of mainstream IDC processing • make data accessible to external users via a web-service interface • incorporate into Station Performance Monitoring tool for internal PTS use Infrasound Technology Workshop, Bermuda

  18. Infrasound Amplitude Determination Purpose • Provide a method for determining infrasound amplitudes in Pascals • useful information to write in the Bulletin • may be useful in Network processing Infrasound Technology Workshop, Bermuda

  19. Infrasound Amplitude Determination Procedure • Apply Window Function in the time domain • Use FTSRS ‘Flat Top’window • process sufficient data such that the window function will not drop by more than 50% from its peak value over the duration of the signal segment. • otherwise signal will get mangled by the window division processes window function signal 0.5 extra data 0.0 signal start time signal end time Infrasound Technology Workshop, Bermuda

  20. Infrasound Amplitude Determination Procedure • Apply FIR filter • two filter bands chosen: • 0.5 to 3.0 Hz • minfreq and maxfreq determined by pmcc detection algorithm • Remove window function from signal segment by dividing • Three amplitude measures applied to a time-aligned beam : • beam aligned according to azimuth + slowness in CSS detection table • Peak-to-Peak: used in several attenuation laws • LANL • DASE • RMS (user specifiable window length) • Amplitude of the Analytic Trace (see Olson, 2000) • For each detection: • 6 amplitude measures are being determined • the Peak-to-Peak 0.5-3.0 Hz amplitude is being written to the CSS arrival table, all others are being written to the amplitude table. Infrasound Technology Workshop, Bermuda

  21. Infrasound Amplitude Determination Testing • A sinc function is used to test beamformer, filtering procedure and amplitude measurement • Peak-to-Peak (P-P) amplitude = 2.434 ; Analytic amplitude = 2.0 • Overlapping traces: • beamformer is working correctly • filter process is not generating a phase-shift • window division is not mangling the data Nutall 4a window 0.001 - 9.999 Hz • non-overlapping traces: • filter process is not generating a phase-shift • window division is not mangling the data 0.15 - 0.60 Hz Infrasound Technology Workshop, Bermuda

  22. Infrasound Amplitude Determination Testing • Results: • for all windows the P-P measure provides the correct amplitude in the ‘unfiltered’ case • the HFT248D window provides the best analytic amplitude in the unfiltered case. • all windows provided reduced amplitudes for a 2-octave band-pass filter centred on the dominant frequency. high frequency resolution general purpose high amplitude resolution Infrasound Technology Workshop, Bermuda

  23. Infrasound Amplitude Determination Still to be done • evaluate results • compare with analyst measured amplitudes • investigate utility of different amplitude measures • Analytic amplitude as a microbarom classifier ? • the RMS amplitude as a signal significance measure ? • incorporate as part of mainstream IDC processing Infrasound Technology Workshop, Bermuda

  24. Conclusions Summary • Two enhancements to the automatic infrasound processing system are currently under development: • station noise characterization • amplitude determination • Should be operational in around 3-4 months. Infrasound Technology Workshop, Bermuda

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