pylot/autoPyLoT_local.in

%This is a parameter input file for autoPyLoT.
%All main and special settings regarding data handling
%and picking are to be set here!
%Parameters are optimized for local data sets!
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

#main settings#
/DATA/Insheim                       #rootpath#     %project path
EVENT_DATA/LOCAL		    #datapath#     %data path
2013.02_Insheim                     #database#     %name of data base
e0019.048.13                        #eventID#      %event ID for single event processing
PILOT				    #datastructure#  %choose data structure
2                                   #iplot#        %flag for plotting: 0 none, 1, partly, >1 everything
AUTOPHASES_AIC_HOS4_ARH             #phasefile#    %name of autoPILOT output phase file 
AUTOLOC_AIC_HOS4_ARH                #locfile#      %name of autoPILOT output location file 
AUTOFOCMEC_AIC_HOS4_ARH.in          #focmecin#     %name of focmec input file containing polarities
HYPOSAT                             #locrt#        %location routine used ("HYPOINVERSE" or "HYPOSAT")
6                                   #pmin#         %minimum required P picks for location
4                                   #p0min#        %minimum required P picks for location if at least
                                                   %3 excellent P picks are found
2                                   #smin#         %minimum required S picks for location
/home/ludger/bin/run_HYPOSAT4autoPILOT.csh #cshellp# %path and name of c-shell script to run location routine
7.6 8.5                             #blon#         %longitude bounding for location map
49 49.4                             #blat#         %lattitude bounding for location map
#parameters for moment magnitude estimation#
5000                                #vp#           %average P-wave velocity
2800                                #vs#           %average S-wave velocity
2200                                #rho#          %rock density [kg/m^3]
300                                 #Qp#           %quality factor for P waves
100                                 #Qs#           %quality factor for S waves
#common settings picker#
15                                  #pstart#       %start time [s] for calculating CF for P-picking
40                                  #pstop#        %end time [s] for calculating CF for P-picking
-1.0                                #sstart#       %start time [s] after or before(-) P-onset for calculating CF for S-picking
7                                   #sstop#        %end time [s] after P-onset for calculating CF for S-picking
2 20                                #bpz1#         %lower/upper corner freq. of first band pass filter Z-comp. [Hz]
2 30                                #bpz2#         %lower/upper corner freq. of second band pass filter Z-comp. [Hz]
2 15                                #bph1#         %lower/upper corner freq. of first band pass filter H-comp. [Hz]
2 20                                #bph2#         %lower/upper corner freq. of second band pass filter z-comp. [Hz]
#special settings for calculating CF#
%!!Be careful when editing the following!!
#Z-component#
HOS                                 #algoP#        %choose algorithm for P-onset determination (HOS, ARZ, or AR3)
7                                   #tlta#         %for HOS-/AR-AIC-picker, length of LTA window [s] 
4                                   #hosorder#     %for HOS-picker, order of Higher Order Statistics
2                                   #Parorder#     %for AR-picker, order of AR process of Z-component
1.2                                 #tdet1z#       %for AR-picker, length of AR determination window [s] for Z-component, 1st pick
0.4                                 #tpred1z#      %for AR-picker, length of AR prediction window [s] for Z-component, 1st pick
0.6                                 #tdet2z#       %for AR-picker, length of AR determination window [s] for Z-component, 2nd pick
0.2                                 #tpred2z#      %for AR-picker, length of AR prediction window [s] for Z-component, 2nd pick
0.001                               #addnoise#     %add noise to seismogram for stable AR prediction
3 0.1 0.5 0.1                       #tsnrz#        %for HOS/AR, window lengths for SNR-and slope estimation [tnoise,tsafetey,tsignal,tslope] [s]
3                                   #pickwinP#     %for initial AIC pick, length of P-pick window [s]
8                                   #Precalcwin#   %for HOS/AR, window length [s] for recalculation of CF (relative to 1st pick)
0                                   #peps4aic#     %for HOS/AR, artificial uplift of samples of AIC-function (P)
0.2                                 #aictsmooth#   %for HOS/AR, take average of samples for smoothing of AIC-function [s]
0.1                                 #tsmoothP#     %for HOS/AR, take average of samples for smoothing CF [s]
0.001                               #ausP#         %for HOS/AR, artificial uplift of samples (aus) of CF (P)
1.3                                 #nfacP#        %for HOS/AR, noise factor for noise level determination (P)
#H-components#
ARH                                 #algoS#        %choose algorithm for S-onset determination (ARH or AR3)
0.8                                 #tdet1h#       %for HOS/AR, length of AR-determination window [s], H-components, 1st pick
0.4                                 #tpred1h#      %for HOS/AR, length of AR-prediction window [s], H-components, 1st pick
0.6                                 #tdet2h#       %for HOS/AR, length of AR-determinaton window [s], H-components, 2nd pick
0.3                                 #tpred2h#      %for HOS/AR, length of AR-prediction window [s], H-components, 2nd pick
4                                   #Sarorder#     %for AR-picker, order of AR process of H-components
6                                   #Srecalcwin#   %for AR-picker, window length [s] for recalculation of CF (2nd pick) (H)
3                                   #pickwinS#     %for initial AIC pick, length of S-pick window [s]
2 0.2 1.5 0.5                       #tsnrh#        %for ARH/AR3, window lengths for SNR-and slope estimation [tnoise,tsafetey,tsignal,tslope] [s]
0.05                                #aictsmoothS#  %for AIC-picker, take average of samples for smoothing of AIC-function [s]
0.02                                #tsmoothS#     %for AR-picker, take average of samples for smoothing CF [s] (S)
0.2                                 #pepsS#        %for AR-picker, artificial uplift of samples of CF (S) 
0.4                                 #ausS#         %for HOS/AR, artificial uplift of samples (aus) of CF (S)
1.5                                 #nfacS#        %for AR-picker, noise factor for noise level determination (S)
%first-motion picker%
1                                   #minfmweight#  %minimum required p weight for first-motion determination
2                                   #minFMSNR#     %miniumum required SNR for first-motion determination
0.2                                 #fmpickwin#    %pick window around P onset for calculating zero crossings
%quality assessment%
#inital AIC onset#
0.01 0.02 0.04 0.08                 #timeerrorsP#   %discrete time errors [s] corresponding to picking weights [0 1 2 3] for P
0.04 0.08 0.16 0.32                 #timeerrorsS#   %discrete time errors [s] corresponding to picking weights [0 1 2 3] for S
80                                  #minAICPslope#  %below this slope [counts/s] the initial P pick is rejected
1.2                                 #minAICPSNR#    %below this SNR the initial P pick is rejected
50                                  #minAICSslope#  %below this slope [counts/s] the initial S pick is rejected
1.5                                 #minAICSSNR#    %below this SNR the initial S pick is rejected
#check duration of signal using envelope function#
1.5                                 #prepickwin#   %pre-signal window length [s] for noise level estimation 
0.7                                 #minsiglength# %minimum required length of signal [s]
0.2                                 #sgap#         %safety gap between noise and signal window [s]
2                                   #noisefactor#  %noiselevel*noisefactor=threshold
60                                  #minpercent#   %per cent of samples required higher than threshold
#check for spuriously picked S-onsets#
3.0                                 #zfac#         %P-amplitude must exceed zfac times RMS-S amplitude 
#jackknife-processing for P-picks#
3                                   #thresholdweight#%minimum required weight of picks
3                                   #dttolerance#  %maximum allowed deviation of P picks from median [s]
4                                   #minstats#     %minimum number of stations with reliable P picks
#wadati check#
0.8                                 #wdttolerance# %maximum allowed deviation from Wadati-diagram
Example of autoPyLoT.in for local data set. 2015-06-22 16:28:21 +02:00			`%This is a parameter input file for autoPyLoT.`
			`%All main and special settings regarding data handling`
			`%and picking are to be set here!`
Modified parameters. 2015-06-24 09:31:01 +02:00			`%Parameters are optimized for local data sets!`
Example of autoPyLoT.in for local data set. 2015-06-22 16:28:21 +02:00			`%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%`

			`#main settings#`
			`/DATA/Insheim #rootpath# %project path`
			`EVENT_DATA/LOCAL #datapath# %data path`
			`2013.02_Insheim #database# %name of data base`
			`e0019.048.13 #eventID# %event ID for single event processing`
			`PILOT #datastructure# %choose data structure`
			`2 #iplot# %flag for plotting: 0 none, 1, partly, >1 everything`
			`AUTOPHASES_AIC_HOS4_ARH #phasefile# %name of autoPILOT output phase file`
			`AUTOLOC_AIC_HOS4_ARH #locfile# %name of autoPILOT output location file`
			`AUTOFOCMEC_AIC_HOS4_ARH.in #focmecin# %name of focmec input file containing polarities`
			`HYPOSAT #locrt# %location routine used ("HYPOINVERSE" or "HYPOSAT")`
			`6 #pmin# %minimum required P picks for location`
			`4 #p0min# %minimum required P picks for location if at least`
			`%3 excellent P picks are found`
			`2 #smin# %minimum required S picks for location`
			`/home/ludger/bin/run_HYPOSAT4autoPILOT.csh #cshellp# %path and name of c-shell script to run location routine`
			`7.6 8.5 #blon# %longitude bounding for location map`
			`49 49.4 #blat# %lattitude bounding for location map`
			`#parameters for moment magnitude estimation#`
			`5000 #vp# %average P-wave velocity`
			`2800 #vs# %average S-wave velocity`
			`2200 #rho# %rock density [kg/m^3]`
			`300 #Qp# %quality factor for P waves`
			`100 #Qs# %quality factor for S waves`
			`#common settings picker#`
			`15 #pstart# %start time [s] for calculating CF for P-picking`
			`40 #pstop# %end time [s] for calculating CF for P-picking`
			`-1.0 #sstart# %start time [s] after or before(-) P-onset for calculating CF for S-picking`
			`7 #sstop# %end time [s] after P-onset for calculating CF for S-picking`
			`2 20 #bpz1# %lower/upper corner freq. of first band pass filter Z-comp. [Hz]`
			`2 30 #bpz2# %lower/upper corner freq. of second band pass filter Z-comp. [Hz]`
			`2 15 #bph1# %lower/upper corner freq. of first band pass filter H-comp. [Hz]`
			`2 20 #bph2# %lower/upper corner freq. of second band pass filter z-comp. [Hz]`
			`#special settings for calculating CF#`
			`%!!Be careful when editing the following!!`
			`#Z-component#`
			`HOS #algoP# %choose algorithm for P-onset determination (HOS, ARZ, or AR3)`
			`7 #tlta# %for HOS-/AR-AIC-picker, length of LTA window [s]`
			`4 #hosorder# %for HOS-picker, order of Higher Order Statistics`
			`2 #Parorder# %for AR-picker, order of AR process of Z-component`
			`1.2 #tdet1z# %for AR-picker, length of AR determination window [s] for Z-component, 1st pick`
			`0.4 #tpred1z# %for AR-picker, length of AR prediction window [s] for Z-component, 1st pick`
			`0.6 #tdet2z# %for AR-picker, length of AR determination window [s] for Z-component, 2nd pick`
			`0.2 #tpred2z# %for AR-picker, length of AR prediction window [s] for Z-component, 2nd pick`
			`0.001 #addnoise# %add noise to seismogram for stable AR prediction`
			`3 0.1 0.5 0.1 #tsnrz# %for HOS/AR, window lengths for SNR-and slope estimation [tnoise,tsafetey,tsignal,tslope] [s]`
			`3 #pickwinP# %for initial AIC pick, length of P-pick window [s]`
			`8 #Precalcwin# %for HOS/AR, window length [s] for recalculation of CF (relative to 1st pick)`
			`0 #peps4aic# %for HOS/AR, artificial uplift of samples of AIC-function (P)`
			`0.2 #aictsmooth# %for HOS/AR, take average of samples for smoothing of AIC-function [s]`
			`0.1 #tsmoothP# %for HOS/AR, take average of samples for smoothing CF [s]`
			`0.001 #ausP# %for HOS/AR, artificial uplift of samples (aus) of CF (P)`
			`1.3 #nfacP# %for HOS/AR, noise factor for noise level determination (P)`
			`#H-components#`
			`ARH #algoS# %choose algorithm for S-onset determination (ARH or AR3)`
			`0.8 #tdet1h# %for HOS/AR, length of AR-determination window [s], H-components, 1st pick`
			`0.4 #tpred1h# %for HOS/AR, length of AR-prediction window [s], H-components, 1st pick`
			`0.6 #tdet2h# %for HOS/AR, length of AR-determinaton window [s], H-components, 2nd pick`
			`0.3 #tpred2h# %for HOS/AR, length of AR-prediction window [s], H-components, 2nd pick`
			`4 #Sarorder# %for AR-picker, order of AR process of H-components`
			`6 #Srecalcwin# %for AR-picker, window length [s] for recalculation of CF (2nd pick) (H)`
			`3 #pickwinS# %for initial AIC pick, length of S-pick window [s]`
			`2 0.2 1.5 0.5 #tsnrh# %for ARH/AR3, window lengths for SNR-and slope estimation [tnoise,tsafetey,tsignal,tslope] [s]`
			`0.05 #aictsmoothS# %for AIC-picker, take average of samples for smoothing of AIC-function [s]`
			`0.02 #tsmoothS# %for AR-picker, take average of samples for smoothing CF [s] (S)`
			`0.2 #pepsS# %for AR-picker, artificial uplift of samples of CF (S)`
			`0.4 #ausS# %for HOS/AR, artificial uplift of samples (aus) of CF (S)`
			`1.5 #nfacS# %for AR-picker, noise factor for noise level determination (S)`
			`%first-motion picker%`
			`1 #minfmweight# %minimum required p weight for first-motion determination`
			`2 #minFMSNR# %miniumum required SNR for first-motion determination`
			`0.2 #fmpickwin# %pick window around P onset for calculating zero crossings`
			`%quality assessment%`
			`#inital AIC onset#`
			`0.01 0.02 0.04 0.08 #timeerrorsP# %discrete time errors [s] corresponding to picking weights [0 1 2 3] for P`
			`0.04 0.08 0.16 0.32 #timeerrorsS# %discrete time errors [s] corresponding to picking weights [0 1 2 3] for S`
			`80 #minAICPslope# %below this slope [counts/s] the initial P pick is rejected`
			`1.2 #minAICPSNR# %below this SNR the initial P pick is rejected`
			`50 #minAICSslope# %below this slope [counts/s] the initial S pick is rejected`
			`1.5 #minAICSSNR# %below this SNR the initial S pick is rejected`
			`#check duration of signal using envelope function#`
			`1.5 #prepickwin# %pre-signal window length [s] for noise level estimation`
			`0.7 #minsiglength# %minimum required length of signal [s]`
			`0.2 #sgap# %safety gap between noise and signal window [s]`
			`2 #noisefactor# %noiselevel*noisefactor=threshold`
			`60 #minpercent# %per cent of samples required higher than threshold`
			`#check for spuriously picked S-onsets#`
			`3.0 #zfac# %P-amplitude must exceed zfac times RMS-S amplitude`
			`#jackknife-processing for P-picks#`
			`3 #thresholdweight#%minimum required weight of picks`
			`3 #dttolerance# %maximum allowed deviation of P picks from median [s]`
			`4 #minstats# %minimum number of stations with reliable P picks`
			`#wadati check#`
			`0.8 #wdttolerance# %maximum allowed deviation from Wadati-diagram`