>INFO
MAXINFO=1000
 
-
Information block from data file...
sno279m.dat                                                                     
 mtmerge:
 date: Wed Sep 27 14:07:07 2000

 files merged and reject rules and rho_a amplitude corrections used:
 file  1:sno279_all.dat                             4:14000      1.00      1.00
 file  2:dat279.dat                                     0:3      1.00      1.00

 Comment and Info blocks from each file

 file  1:sno279_all.dat
 # mtmerge:
 # date: Fri Nov 19 15:12:34 1999
 #
 # files merged and reject rules and rho_a amplitude corrections used:
 # file  1:sno279_2r.dat                               1:3000      1.00      1.
 # file  2:sno279_3r.dat                           3000:20000      1.00      1.
 #
 # Comment and Info blocks from each file
 #
 # file  1:sno279_2r.dat
 # # tsrestack: version: v5.0    precision: SINGLE
 # # date: Fri Nov 19 13:34:42 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:
 # # sno279/279a1241b1.cas
 # # sno279/279a1247b1.cas
 # # sno279/279a1251a1.cas
 # # sno279/279a1253b1.cas
 # # sno279/279a1255a1.cas
 # # sno279/279a1259a1.cas
 # # sno279/279a1283a1.cas
 # # sno279/279a1269a1.cas
 # # sno279/279a1265a1.cas
 # # sno279/279a1263a1.cas
 # # sno279/279a1287a1.cas
 # # sno279/279a1281a1.cas
 # # sno279/279a1277a1.cas
 # # sno279/279a1275a1.cas
 # # sno279/279a1275a2.cas
 # # sno279/279a1273a1.cas
 # # sno279/279a1267a1.cas
 # #
 # # tscascade: version: v5.0    precision: SINGLE
 # # date: Fri Nov 19 13:34:11 1999
 # #
 # # input  ts window: sno279a1
 # # remote ts window: sno267a1
 # #
 # # 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: Fri Nov 19 13:23:01 1999
 # #
 # # input file: sno279/sno279a1.1mp
 # #
 # # Machine endian: Big
 # # UNIX set      : T
 # #
 # # site description: swift river
 # #
 # # Latitude   :060:01:30 N
 # # Longitude  :131:05:30 W
 # #
 # # LiMS         number :   63
 # # Magnetometer number :   63
 # #
 # # Ex line length (m):     100.00
 # # Ey line length (m):     100.00
 # #
 # # 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:   -27.0
 # # Ey rotation:   -27.0
 # # Hx rotation:   -27.0
 # # Rx rotation:   -25.6
 # #
 # # declination:   0
 # # coord_sys  : MAGNETIC NORTH
 # # Ex azimuth :   0
 # # Ey azimuth :  90
 # # Hx azimuth :   0
 # # Rx co_ord  : MAGNETIC NORTH
 # # Rx azimuth :   0
 # #
 # #
 #  STATION   :sno279
 #  STATION_RR:sno267
 #  AZIMUTH   =         0.0
 #  LATITUDE  =     60.0250
 #  LONGITUDE =   -131.0920
 #  ELEVATION =         0.0
 #------------------------------
 # file  2:sno279_3r.dat
 # # tsrestack: version: v5.0    precision: SINGLE
 # # date: Fri Nov 19 13:38:19 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:
 # # sno279/279as241as.cas
 # # sno279/279as247as.cas
 # # sno279/279as249as.cas
 # # sno279/279as2511r.cas
 # # sno279/279as253as.cas
 # # sno279/279as2551r.cas
 # # sno279/279as257as.cas
 # # sno279/279as2591r.cas
 # # sno279/279as4141r.cas
 # # sno279/279as283as.cas
 # # sno279/279as269as.cas
 # # sno279/279as265as.cas
 # # sno279/279as2631r.cas
 # # sno279/279as261as.cas
 # # sno279/279as4011r.cas
 # # sno279/279as4041r.cas
 # # sno279/279as4211r.cas
 # # sno279/279as287as.cas
 # # sno279/279as2811r.cas
 # # sno279/279as2771r.cas
 # # sno279/279as275as.cas
 # # sno279/279as2731r.cas
 # # sno279/279as2671r.cas
 # #
 # # tscascade: version: v5.0    precision: SINGLE
 # # date: Fri Nov 19 13:38:12 1999
 # #
 # # input  ts window: sno279as
 # # remote ts window: sno2671r
 # #
 # # 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: Fri Nov 19 13:23:57 1999
 # #
 # # Files spliced together:
 # # sno2791r  1999-10-13 00:00:45-1999-10-19 23:59:35
 # # sno279a2  1999-10-20 00:04:00-1999-10-24 19:58:20
 # #
 # # Following comment block from first file...
 # #
 # # time series file from ts_resamp
 # # date: Fri Nov 19 12:36:12 1999
 # #
 # # input file =sno279/sno279a1.ts
 # #
 # # time series file from mp2ts
 # # date: Fri Nov 19 12:19:13 1999
 # #
 # # input file: sno279/sno279a1.1mp
 # #
 # # Machine endian: Big
 # # UNIX set      : T
 # #
 # # site description: swift river
 # #
 # # Latitude   :060:01:30 N
 # # Longitude  :131:05:30 W
 # #
 # # LiMS         number :   63
 # # Magnetometer number :   63
 # #
 # # Ex line length (m):     100.00
 # # Ey line length (m):     100.00
 # #
 # # 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:   -27.0
 # # Ey rotation:   -27.0
 # # Hx rotation:   -27.0
 # # Rx rotation:   -25.6
 # #
 # # declination:   0
 # # coord_sys  : MAGNETIC NORTH
 # # Ex azimuth :   0
 # # Ey azimuth :  90
 # # Hx azimuth :   0
 # # Rx co_ord  : MAGNETIC NORTH
 # # Rx azimuth :   0
 # #
 # #
 #  STATION   :sno279
 #  STATION_RR:sno267
 #  AZIMUTH   =         0.0
 #  LATITUDE  =     60.0250
 #  LONGITUDE =   -131.0920
 #  ELEVATION =         0.0
 #------------------------------
 #
 # Information block taken from file 1
 #
  STATION   :sno279
  STATION_RR:sno267
  AZIMUTH   =         0.0
  LATITUDE  =     60.0250
  LONGITUDE =   -131.0920
  ELEVATION =         0.0
------------------------------
 file  2:dat279.dat
 #WRITTEN BY GEOTOOLS: data2_279    09/27/00    RAW RECS    
  AZIMUTH   =         0.0
  LATITUDE  =     60.0249
  LONGITUDE =   -131.0937
  ELEVATION =         0.0
------------------------------

 Information block taken from file 1

STATION   :sno279
STATION_RR:sno267
AZIMUTH   =         0.0
LATITUDE  =     60.0250
LONGITUDE =   -131.0920
ELEVATION =         0.0
 
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