>INFO MAXINFO=1000 - Information block from data file... sno222m.dat mtmerge: date: Wed Sep 27 10:12:01 2000 files merged and reject rules and rho_a amplitude corrections used: file 1:sno222_all.dat 80:14000 1.00 1.00 file 2:200222.dat 0:80 1.00 1.00 Comment and Info blocks from each file file 1:sno222_all.dat # mtmerge: # date: Mon Nov 22 12:15:02 1999 # # files merged and reject rules and rho_a amplitude corrections used: # file 1:sno222_2r.dat 1:3000 1.00 1. # file 2:sno222_3r.dat 3000:20000 1.00 1. # # Comment and Info blocks from each file # # file 1:sno222_2r.dat # # tsrestack: version: v5.0 precision: SINGLE # # date: Mon Nov 22 11:36:27 1999 # # # # Coherence minima: # # 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 # # 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 # # Coherence maximum:.9999000 # # Maxtype: JKN # # Ntype: 1 # # Weight: Y # # # # Cascade files used: # # sno222/222a1204a1.cas # # sno222/222a1208a1.cas # # sno222/222a1212a1.cas # # sno222/222a1216a1.cas # # sno222/222a1218a1.cas # # sno222/222a1220a1.cas # # sno222/222a1224a1.cas # # sno222/222a1226a1.cas # # sno222/222a1230a1.cas # # sno222/222a1234a1.cas # # sno222/222a1240b1.cas # # sno222/222a1238a1.cas # # sno222/222b1200a1.cas # # sno222/222b1202a1.cas # # sno222/222b1206a1.cas # # sno222/222b1210a1.cas # # sno222/222b1214a1.cas # # sno222/222b1218b1.cas # # sno222/222b1241a1.cas # # sno222/222b1245a1.cas # # # # tscascade: version: v5.0 precision: SINGLE # # date: Mon Nov 22 11:36:04 1999 # # # # input ts window: sno222b1 # # remote ts window: sno245a1 # # # # process.cfg file:--- # # # # # process.cfg: version: v5.0 # # # # # # This file contains parameters that may be # # # altered for running tscascade and tsrestack # # # Parameters listed below are the default # # # values in the tscascade executable. # # # # # # A hash (#) in the first column comments the line # # # out. That variable is requested on execution # # # # # VER :v5.0 cfg file version # # NUMSTK:20 number of estimates per substack # # 32 32 32 32 16 16 16 16 8 8 8 8 8 8 8 8 4 4 # # VARTOL:0.0100 tolerance for minimum variance # # # Other parameters are allowed (remove # to use) # # OWRITE: T overwrite files without asking # # PROTYP: MT processing type: MT, GDS or HSG # # REMOTE: H type of remote: H or E (not requested if absent) # # #DECLIN: 0 sets declination # # #ROTANG: 0 sets rotation co-ord system # # MAG_OR: F correct magnetometer orientation using baselines # # P_NORM: T normalize spectra by horizontal magnetic field power # # STACK : T .TRUE. substacking # # JJANAL: T .TRUE. Jones-Joedicke processing # # MAXTYP: JKN max type: JKN, COH or VAR # # NTYPE : 1 param to minimize # # WEIGHT: T apply weighting # # COHMIN: 20*0.500 coherence minimum # # COHMAX: 0.999 coherence maximum # # UNITS : SI impedance units: SI or FIELD # # # # # # # # ************************************************************************* # # * # # * sno313as # # * # # ************************************************************************* # # # # Number of degrees of freedom: # # # # Period ndeg # # # # These values are not corrected for any low- or high-pass filtering (if an # # # # Power Spectra == # # Period Hx Hy Ex Ey H # # # # Ordinary coherences == # # Period g12 g13 g14 g23 g24 g34 g16 g17 g26 g27 g51 g52 # # # # Multiple coherences == # # Period g312 g412 g512 g612 g712 # # # # # # Partial coherences == # # Period g31.2 g32.1 g41.2 g42.1 g51.2 g52.1 # # # # # # # # POLARISATION PARAMETERS # # # # PSI = ANGLE OF MAJOR AXIS TO THE NORTH # # RATIO = MINOR/MAJOR AXIS (POLARISED PART ONLY) # # R = POLARISED/TOTAL PART # # # # FOR MAGNETIC FIELD FOR TELLURIC # # # # PERIOD PSI G12 R RATIO IC1 PSI G34 R RATI # # # # # # phase polarisation parameters # # # # psix = angle of maximum axis to the north # # psim = angle of minimum axis to the north # # ratio = major/minor axis # # r = phase difference # # # # for magnetic field for telluric # # # # period psix psim r ratio ic1 psix psim r rati # # # # # # coherence rotation parameters # # # # cohx = angle of maximum coh to the north # # cohm = angle of minimum coh to the north # # ratio = major/minor coh # # r = coh difference # # # # for magnetic field for telluric # # # # period cohx cohm r ratio ic1 cohx cohm r rati # # GDS transfer function == # # # # MT transfer function Ex (Hx,Hy) == # # # # MT transfer function Ey (Hx,Hy) == # # # # # # # # ************************************************************************* # # * # # * sno313as # # * # # ************************************************************************* # # # # Number of degrees of freedom: # # # # Period ndeg # # # # These values are not corrected for any low- or high-pass filtering (if an # # # # Power Spectra == # # Period Hx Hy Ex Ey H # # # # Ordinary coherences == # # Period g12 g13 g14 g23 g24 g34 g16 g17 g26 g27 g51 g52 # # # # Multiple coherences == # # Period g312 g412 g512 g612 g712 # # # # # # Partial coherences == # # Period g31.2 g32.1 g41.2 g42.1 g51.2 g52.1 # # # # # # # # POLARISATION PARAMETERS # # # # PSI = ANGLE OF MAJOR AXIS TO THE NORTH # # RATIO = MINOR/MAJOR AXIS (POLARISED PART ONLY) # # R = POLARISED/TOTAL PART # # # # FOR MAGNETIC FIELD FOR TELLURIC # # # # PERIOD PSI G12 R RATIO IC1 PSI G34 R RATI # # # # # # phase polarisation parameters # # # # psix = angle of maximum axis to the north # # psim = angle of minimum axis to the north # # ratio = major/minor axis # # r = phase difference # # # # for magnetic field for telluric # # # # period psix psim r ratio ic1 psix psim r rati # # # # # # coherence rotation parameters # # # # cohx = angle of maximum coh to the north # # cohm = angle of minimum coh to the north # # ratio = major/minor coh # # r = coh difference # # # # for magnetic field for telluric # # # # period cohx cohm r ratio ic1 cohx cohm r rati # # GDS transfer function == # # # # MT transfer function Ex (Hx,Hy) == # # # # MT transfer function Ey (Hx,Hy) == # # # # # # # # ************************************************************************* # # * # # * sno313as # # * # # ************************************************************************* # # # # Number of degrees of freedom: # # # # Period ndeg # # # # These values are not corrected for any low- or high-pass filtering (if an # # # # Power Spectra == # # Period Hx Hy Ex Ey H # # # # Ordinary coherences == # # Period g12 g13 g14 g23 g24 g34 g16 g17 g26 g27 g51 g52 # # # # Multiple coherences == # # Period g312 g412 g512 g612 g712 # # # # # # Partial coherences == # # Period g31.2 g32.1 g41.2 g42.1 g51.2 g52.1 # # # # # # # # POLARISATION PARAMETERS # # # # PSI = ANGLE OF MAJOR AXIS TO THE NORTH # # RATIO = MINOR/MAJOR AXIS (POLARISED PART ONLY) # # R = POLARISED/TOTAL PART # # # # FOR MAGNETIC FIELD FOR TELLURIC # # # # PERIOD PSI G12 R RATIO IC1 PSI G34 R RATI # # # # # # phase polarisation parameters # # # # psix = angle of maximum axis to the north # # psim = angle of minimum axis to the north # # ratio = major/minor axis # # r = phase difference # # # # for magnetic field for telluric # # # # period psix psim r ratio ic1 psix psim r rati # # # # # # coherence rotation parameters # # # # cohx = angle of maximum coh to the north # # cohm = angle of minimum coh to the north # # ratio = major/minor coh # # r = coh difference # # # # for magnetic field for telluric # # # # period cohx cohm r ratio ic1 cohx cohm r rati # # GDS transfer function == # # # # MT transfer function Ex (Hx,Hy) == # # # # MT transfer function Ey (Hx,Hy) == # # # # # # time series file from mp2ts # # date: Wed Nov 17 10:07:45 1999 # # # # input file: sno222/sno222b1.1mp # # # # Machine endian: Big # # UNIX set : T # # # # site description: Stikine River # # # # Latitude :058:10:13 N # # Longitude :129:51:21 W # # # # LiMS number : 52 # # Magnetometer number : 52 # # # # Ex line length (m): 100.00 # # Ey line length (m): 95.00 # # # # Azimuths relative to: MAGNETIC NORTH # # Ex azimuth; 0 # # Ey azimuth; 90 # # Hx azimuth; 0 # # Hy azimuth; 90 # # # # FIRST 22 POINTS DROPPED FROM .1mp FILE TO # # ACCOUNT FOR FILTER SETTLING # # # #F Filter block begin # #F # #F Filters applied to LiMS/LRMT data are: # #F 1: Analogue anti-alias six-pole Bessel low-pass # #F filters on each channel with -3 dB point at nominally 5 Hz. # #F -calibrated values given below # #F # #F 2: Digital anti-alias multi-stage Chebyshev FIR filters # #F with final stage at 2xsampling rate # #F # #F 1: Analogue single-pole Butterworth high-pass filters on the # #F telluric channels only with -3 dB point at nominally 30,000 s # #F -calibrated values given below # #F # #F Chan Calib Low-pass High-pass (s) # #F 1 1.00 0.20 0.00 # #F 2 1.00 0.20 0.00 # #F 3 1.00 0.20 0.00 # #F 4 1.00 0.20 30000.00 # #F 5 1.00 0.20 30000.00 # #F # #F In the tsrestack code, these filter responses are # #F removed using bessel7.f and high17.f # #F # #F Filter block end # # # # Azimuthal information of cascade decimates # # azimuth : 0 # # this azimuth is relative to TRUE NORTH if either the # # 1) data were recorded in TRUE NORTH, or # # 2) data were recorded in MAGNETIC NORTH and the # # correct declination has been applied # # # # Ex rotation: -25.7 # # Ey rotation: -25.7 # # Hx rotation: -25.7 # # Rx rotation: -27.0 # # # # declination: 0 # # coord_sys : MAGNETIC NORTH # # Ex azimuth : 0 # # Ey azimuth : 90 # # Hx azimuth : 0 # # Rx co_ord : MAGNETIC NORTH # # Rx azimuth : 0 # # # # # STATION :sno222 # STATION_RR:sno245 # AZIMUTH = 0.0 # LATITUDE = 58.1703 # LONGITUDE = -129.8560 # ELEVATION = 0.0 #------------------------------ # file 2:sno222_3r.dat # # tsrestack: version: v5.0 precision: SINGLE # # date: Mon Nov 22 11:39:45 1999 # # # # Coherence minima: # # 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 # # 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 0.50 # # Coherence maximum:.9999000 # # Maxtype: JKN # # Ntype: 1 # # Weight: Y # # # # Cascade files used: # # sno222/222as2001r.cas # # sno222/222as2021r.cas # # sno222/222as204as.cas # # sno222/222as2061r.cas # # sno222/222as208as.cas # # sno222/222as2101r.cas # # sno222/222as212as.cas # # sno222/222as2141r.cas # # sno222/222as2161r.cas # # sno222/222as218as.cas # # sno222/222as220as.cas # # sno222/222as224as.cas # # sno222/222as2261r.cas # # sno222/222as228as.cas # # sno222/222as2301r.cas # # sno222/222as232as.cas # # sno222/222as2341r.cas # # sno222/222as236as.cas # # sno222/222as240as.cas # # sno222/222as241as.cas # # sno222/222as245as.cas # # sno222/222as2381r.cas # # # # tscascade: version: v5.0 precision: SINGLE # # date: Mon Nov 22 11:39:42 1999 # # # # input ts window: sno222as # # remote ts window: sno2381r # # # # process.cfg file:--- # # # # # process.cfg: version: v5.0 # # # # # # This file contains parameters that may be # # # altered for running tscascade and tsrestack # # # Parameters listed below are the default # # # values in the tscascade executable. # # # # # # A hash (#) in the first column comments the line # # # out. That variable is requested on execution # # # # # VER :v5.0 cfg file version # # NUMSTK:20 number of estimates per substack # # 32 32 32 32 16 16 16 16 8 8 8 8 8 8 8 8 4 4 # # VARTOL:0.0100 tolerance for minimum variance # # # Other parameters are allowed (remove # to use) # # OWRITE: T overwrite files without asking # # PROTYP: MT processing type: MT, GDS or HSG # # REMOTE: H type of remote: H or E (not requested if absent) # # #DECLIN: 0 sets declination # # #ROTANG: 0 sets rotation co-ord system # # MAG_OR: F correct magnetometer orientation using baselines # # P_NORM: T normalize spectra by horizontal magnetic field power # # STACK : T .TRUE. substacking # # JJANAL: T .TRUE. Jones-Joedicke processing # # MAXTYP: JKN max type: JKN, COH or VAR # # NTYPE : 1 param to minimize # # WEIGHT: T apply weighting # # COHMIN: 20*0.500 coherence minimum # # COHMAX: 0.999 coherence maximum # # UNITS : SI impedance units: SI or FIELD # # # # # # # # ************************************************************************* # # * # # * sno313as # # * # # ************************************************************************* # # # # Number of degrees of freedom: # # # # Period ndeg # # # # These values are not corrected for any low- or high-pass filtering (if an # # # # Power Spectra == # # Period Hx Hy Ex Ey H # # # # Ordinary coherences == # # Period g12 g13 g14 g23 g24 g34 g16 g17 g26 g27 g51 g52 # # # # Multiple coherences == # # Period g312 g412 g512 g612 g712 # # # # # # Partial coherences == # # Period g31.2 g32.1 g41.2 g42.1 g51.2 g52.1 # # # # # # # # POLARISATION PARAMETERS # # # # PSI = ANGLE OF MAJOR AXIS TO THE NORTH # # RATIO = MINOR/MAJOR AXIS (POLARISED PART ONLY) # # R = POLARISED/TOTAL PART # # # # FOR MAGNETIC FIELD FOR TELLURIC # # # # PERIOD PSI G12 R RATIO IC1 PSI G34 R RATI # # # # # # phase polarisation parameters # # # # psix = angle of maximum axis to the north # # psim = angle of minimum axis to the north # # ratio = major/minor axis # # r = phase difference # # # # for magnetic field for telluric # # # # period psix psim r ratio ic1 psix psim r rati # # # # # # coherence rotation parameters # # # # cohx = angle of maximum coh to the north # # cohm = angle of minimum coh to the north # # ratio = major/minor coh # # r = coh difference # # # # for magnetic field for telluric # # # # period cohx cohm r ratio ic1 cohx cohm r rati # # GDS transfer function == # # # # MT transfer function Ex (Hx,Hy) == # # # # MT transfer function Ey (Hx,Hy) == # # # # # # # # ************************************************************************* # # * # # * sno313as # # * # # ************************************************************************* # # # # Number of degrees of freedom: # # # # Period ndeg # # # # These values are not corrected for any low- or high-pass filtering (if an # # # # Power Spectra == # # Period Hx Hy Ex Ey H # # # # Ordinary coherences == # # Period g12 g13 g14 g23 g24 g34 g16 g17 g26 g27 g51 g52 # # # # Multiple coherences == # # Period g312 g412 g512 g612 g712 # # # # # # Partial coherences == # # Period g31.2 g32.1 g41.2 g42.1 g51.2 g52.1 # # # # # # # # POLARISATION PARAMETERS # # # # PSI = ANGLE OF MAJOR AXIS TO THE NORTH # # RATIO = MINOR/MAJOR AXIS (POLARISED PART ONLY) # # R = POLARISED/TOTAL PART # # # # FOR MAGNETIC FIELD FOR TELLURIC # # # # PERIOD PSI G12 R RATIO IC1 PSI G34 R RATI # # # # # # phase polarisation parameters # # # # psix = angle of maximum axis to the north # # psim = angle of minimum axis to the north # # ratio = major/minor axis # # r = phase difference # # # # for magnetic field for telluric # # # # period psix psim r ratio ic1 psix psim r rati # # # # # # coherence rotation parameters # # # # cohx = angle of maximum coh to the north # # cohm = angle of minimum coh to the north # # ratio = major/minor coh # # r = coh difference # # # # for magnetic field for telluric # # # # period cohx cohm r ratio ic1 cohx cohm r rati # # GDS transfer function == # # # # MT transfer function Ex (Hx,Hy) == # # # # MT transfer function Ey (Hx,Hy) == # # # # # # # # ************************************************************************* # # * # # * sno313as # # * # # ************************************************************************* # # # # Number of degrees of freedom: # # # # Period ndeg # # # # These values are not corrected for any low- or high-pass filtering (if an # # # # Power Spectra == # # Period Hx Hy Ex Ey H # # # # Ordinary coherences == # # Period g12 g13 g14 g23 g24 g34 g16 g17 g26 g27 g51 g52 # # # # Multiple coherences == # # Period g312 g412 g512 g612 g712 # # # # # # Partial coherences == # # Period g31.2 g32.1 g41.2 g42.1 g51.2 g52.1 # # # # # # # # POLARISATION PARAMETERS # # # # PSI = ANGLE OF MAJOR AXIS TO THE NORTH # # RATIO = MINOR/MAJOR AXIS (POLARISED PART ONLY) # # R = POLARISED/TOTAL PART # # # # FOR MAGNETIC FIELD FOR TELLURIC # # # # PERIOD PSI G12 R RATIO IC1 PSI G34 R RATI # # # # # # phase polarisation parameters # # # # psix = angle of maximum axis to the north # # psim = angle of minimum axis to the north # # ratio = major/minor axis # # r = phase difference # # # # for magnetic field for telluric # # # # period psix psim r ratio ic1 psix psim r rati # # # # # # coherence rotation parameters # # # # cohx = angle of maximum coh to the north # # cohm = angle of minimum coh to the north # # ratio = major/minor coh # # r = coh difference # # # # for magnetic field for telluric # # # # period cohx cohm r ratio ic1 cohx cohm r rati # # GDS transfer function == # # # # MT transfer function Ex (Hx,Hy) == # # # # MT transfer function Ey (Hx,Hy) == # # # # # # time series file from tssplice # # date: Wed Nov 17 11:10:03 1999 # # # # Files spliced together: # # sno2221r 1999-09-23 03:30:45-1999-09-28 01:10:20 # # sno2222r 1999-09-30 03:00:45-1999-10-03 22:24:00 # # # # Following comment block from first file... # # # # time series file from ts_resamp # # date: Wed Nov 17 11:08:35 1999 # # # # input file =sno222/sno222a1.ts # # # # time series file from mp2ts # # date: Wed Nov 17 10:07:32 1999 # # # # input file: sno222/sno222a1.1mp # # # # Machine endian: Big # # UNIX set : T # # # # site description: Stikine River # # # # Latitude :058:10:13 N # # Longitude :129:51:21 W # # # # LiMS number : 52 # # Magnetometer number : 52 # # # # Ex line length (m): 100.00 # # Ey line length (m): 95.00 # # # # Azimuths relative to: MAGNETIC NORTH # # Ex azimuth; 0 # # Ey azimuth; 90 # # Hx azimuth; 0 # # Hy azimuth; 90 # # # # FIRST 22 POINTS DROPPED FROM .1mp FILE TO # # ACCOUNT FOR FILTER SETTLING # # # #F Filter block begin # #F # #F Filters applied to LiMS/LRMT data are: # #F 1: Analogue anti-alias six-pole Bessel low-pass # #F filters on each channel with -3 dB point at nominally 5 Hz. # #F -calibrated values given below # #F # #F 2: Digital anti-alias multi-stage Chebyshev FIR filters # #F with final stage at 2xsampling rate # #F # #F 1: Analogue single-pole Butterworth high-pass filters on the # #F telluric channels only with -3 dB point at nominally 30,000 s # #F -calibrated values given below # #F # #F Chan Calib Low-pass High-pass (s) # #F 1 1.00 0.20 0.00 # #F 2 1.00 0.20 0.00 # #F 3 1.00 0.20 0.00 # #F 4 1.00 0.20 30000.00 # #F 5 1.00 0.20 30000.00 # #F # #F In the tsrestack code, these filter responses are # #F removed using bessel7.f and high17.f # #F # #F Filter block end # # # # Azimuthal information of cascade decimates # # azimuth : 0 # # this azimuth is relative to TRUE NORTH if either the # # 1) data were recorded in TRUE NORTH, or # # 2) data were recorded in MAGNETIC NORTH and the # # correct declination has been applied # # # # Ex rotation: -25.7 # # Ey rotation: -25.7 # # Hx rotation: -25.7 # # Rx rotation: -26.9 # # # # declination: 0 # # coord_sys : MAGNETIC NORTH # # Ex azimuth : 0 # # Ey azimuth : 90 # # Hx azimuth : 0 # # Rx co_ord : MAGNETIC NORTH # # Rx azimuth : 0 # # # # # STATION :sno222 # STATION_RR:sno238 # AZIMUTH = 0.0 # LATITUDE = 58.1703 # LONGITUDE = -129.8560 # ELEVATION = 0.0 #------------------------------ # # Information block taken from file 1 # STATION :sno222 STATION_RR:sno245 AZIMUTH = 0.0 LATITUDE = 58.1703 LONGITUDE = -129.8560 ELEVATION = 0.0 ------------------------------ file 2:200222.dat #WRITTEN BY GEOTOOLS: 200_222 09/26/00 RAW RECS AZIMUTH = 0.0 LATITUDE = 58.1703 LONGITUDE = -129.8573 ELEVATION = 0.0 ------------------------------ Information block taken from file 1 STATION :sno222 STATION_RR:sno245 AZIMUTH = 0.0 LATITUDE = 58.1703 LONGITUDE = -129.8560 ELEVATION = 0.0 -