Wireline Sonic Waveform Data

 

ODP logging contractor: LDEO-BRG
Hole: 1170D
Leg: 189
Location: South Tasman Rise (Tasman Sea)
Latitude: 47° 9.04'S
Longitude: 146° 2.991'E
Logging date: April, 2000
Bottom felt: 2715.8 mbrf
Total penetration: 779.8 mbsf
Total core recovered: 287.69 m (81.1 %)

TOOL USED: DSI (Dipole Sonic Imager)

Recording mode: Monopole P&S (on FMS tool string-Pass 1 and GHMT tool string-both passes), Upper and Lower Dipole (GHMT tool string-both passes) and Upper Dipole (on FMS tool string-Pass 1).

Remarks about the recording: none.

 

MONOPOLE P&S MODE: measures compressional and hard-rock shear slowness. The monopole transmitter is excited by a high-frequency pulse, which reproduces conditions similar to previous sonic tools.

UPPER DIPOLE MODE: measures shear wave slowness using firings of the upper dipole transmitter.

LOWER DIPOLE MODE: measures shear wave slowness using firings of the lower dipole transmitter.

 

As most Schlumberger logs, acoustic data are recorded in DLIS format. Each of the eight waveforms consists of 512 samples, each recorded every 10 (monopole P&S) and 40 microsec (dipole modes), at depth intervals of 15.24 cm (6 inches). The original data in DLIS format is first loaded on a Sun system using GeoFrame software. The packed waveform data files are then converted into ASCII and finally binary format.

Each row of the binary file is composed of the entire waveform set recorded at each depth, preceded by the depth. In the case of 8 waveforms with 512 samples per waveform, this corresponds to 1 + 4x512 = 4097 columns. In this hole, the specifications of the files are:

 

Number of columns: 4097

Number of rows: 1477 (GHMT tool string pass 1)

Number of rows: 526 (GHMT tool string pass 2)

Number of rows: 925 (FMS tool string pass 1)

 

All values are stored as ' IEEE floating point numbers' (= 4 bytes).

Any numerical software or programing language (matlab, python,...) can import the files for further analysis of the waveforms.

The following files were converted:

 

DSI from GHMT/DSI/NGT  (Pass 1, Bottom Hole Assembly at ~ 3245 mbrf)

1170D-mono_ghmt_p1.bin: 3245-3470 mbrf

1170D-ldip_ghmt_p1.bin: 3245-3470 mbrf

1170D-udip-ghmt_p1.bin: 3245-3470 mbrf

 

DSI from GHMT/DSI/NGT (Pass 2, Bottom Hole Assembly at ~ 3245 mbrf)

1170D-ldip_ghmt_p2.bin: 3245-3325 mbrf

1170D-udip_ghmt_p2.bin: 3245-3325 mbrf

 

DSI from FMS/GPIT/DSI/NGT (Pass 1, Bottom Hole Assembly at ~ 3245 mbrf)

1170D-mono_fms_p1.bin: 3349-3490 mbrf

1170D-udip-fms_p1.bin: 3349-3490 mbrf

 

The sonic waveform files are not depth-shifted to a reference run or to the seafloor. For depth shift to the sea floor, please refer to the DEPTH SHIFT section in the standard log documentation file.

 

NOTE: For users interested in converting the data to a format more suitable for their own purpose, a simple routine to read the binary files would include a couple of basic steps (here in old fashioned fortran 77, but would be similar in matlab or other languages):

The first step is to extract the files dimensions and specification from the header, which is the first record in each file:

  open (1, file = *.bin,access = 'direct', recl = 50) <-- NB:50 is enough to real all fields

  read (1, rec = 1)nz, ns, nrec, ntool, mode, dz, scale, dt

  close (1)

The various fields in the header are:
      - number of depths
      - number of samples per waveform and per receiver
      - number of receivers
      - tool number (0 = DSI; 1 = SonicVISION; 2 = SonicScope; 3 = Sonic Scanner; 4 = XBAT; 5 = MCS; 6 = SDT; 7 = LSS; 8 = SST; 9 = BHC; 10 = QL40; 11 = 2PSA)
      - mode (1 = Lower Dipole, 2 = Upper Dipole, 3 = Stoneley, 4 = Monopole)
      - vertical sampling interval *
      - scaling factor for depth (1.0 = meters; 0.3048 = feet) *
      - waveform sampling rate in microseconds *

All those values are stored as 4 bytes integers, except for the ones marked by an asterisk, stored as 4 bytes IEEE floating point numbers.

Then, if the number of depths, samples per waveform/receiver, and receivers are nz, ns, and nrec, respectively, a command to open the file would be:

  open (1, file = *.bin, access = 'direct', recl = 4*(1 + nrec*ns))

Finally, a generic loop to read the data and store them in an array of dimension nrec × ns × nz would be:

  do k = 1, nz

    read (1, rec = 1+k) depth(k), ((data(i,j,k), j = 1,ns), i = 1,nrec)

  enddo

 

For further information about the logs please contact:

 

Cristina Broglia
Phone: 845-365-8343
Fax: 845-365-3182
E-mail: Cristina Broglia