Point Shapefile of the Interpreted Flooding Surface Isopach Based on Seismic-Reflection Profiles Collected in Apalachicola Bay in 2006 from U.S. Geological Survey Cruise 06001 (FLOODISO_GEOG.SHP, Geographic, WGS84)

Frequently anticipated questions:

• What does this data set describe?
  1. How might this data set be cited?
  2. What geographic area does the data set cover?
  3. What does it look like?
  4. Does the data set describe conditions during a particular time period?
  5. What is the general form of this data set?
  6. How does the data set represent geographic features?
  7. How does the data set describe geographic features?
• Who produced the data set?
  1. Who are the originators of the data set?
  2. Who also contributed to the data set?
  3. To whom should users address questions about the data?
• Why was the data set created?
• How was the data set created?
  1. From what previous works were the data drawn?
  2. How were the data generated, processed, and modified?
  3. What similar or related data should the user be aware of?
• How reliable are the data; what problems remain in the data set?
  1. How well have the observations been checked?
  2. How accurate are the geographic locations?
  3. How accurate are the heights or depths?
  4. Where are the gaps in the data? What is missing?
  5. How consistent are the relationships among the data, including topology?
• How can someone get a copy of the data set?
  1. Are there legal restrictions on access or use of the data?
  2. Who distributes the data?
  3. What's the catalog number I need to order this data set?
  4. What legal disclaimers am I supposed to read?
  5. How can I download or order the data?
• Who wrote the metadata?

What does this data set describe?

1. How might this data set be cited?
   Twichell, David C., and Cross, VeeAnn A., 2012, Point Shapefile of the Interpreted Flooding Surface Isopach Based on Seismic-Reflection Profiles Collected in Apalachicola Bay in 2006 from U.S. Geological Survey Cruise 06001 (FLOODISO_GEOG.SHP, Geographic, WGS84): Open-File Report 2012-1003, U.S. Geological Survey, Coastal and Marine Geology Program, Woods Hole Coastal and Marine Science Center, Woods Hole, MA.

   Online Links:

   • https://doi.org/10.3133/ofr20121003
   • http://pubs.usgs.gov/of/2012/1003/data/shapefiles/floodiso_geog.zip
   • http://pubs.usgs.gov/of/2012/1003/html/catalog.html

   This is part of the following larger work.
   Cross, V.A., Twichell, D.C., Foster, D.S., and O'Brien, T.F., 2012, Apalachicola Bay Interpreted Seismic Horizons and Updated IRIS Chirp Seismic-Reflection Data: Open-File Report 2012-1003, U.S. Geological Survey, Reston, VA.

   Online Links:

   • http://pubs.usgs.gov/of/2012/1003/

2. What geographic area does the data set cover?

   West_Bounding_Coordinate: -85.094055
   East_Bounding_Coordinate: -84.877486
   North_Bounding_Coordinate: 29.717944
   South_Bounding_Coordinate: 29.602959
   

3. What does it look like?
4. Does the data set describe conditions during a particular time period?

   Beginning_Date: 31-May-2006

   Ending_Date: 27-Jun-2006

   Currentness_Reference:

   ground condition

5. What is the general form of this data set?

   Geospatial_Data_Presentation_Form: vector digital data
   

6. How does the data set represent geographic features?
   1. How are geographic features stored in the data set?
      This is a Vector data set. It contains the following vector data types (SDTS terminology):
      • Entity point (123409)
   2. What coordinate system is used to represent geographic features?
      Horizontal positions are specified in geographic coordinates, that is, latitude and longitude. Latitudes are given to the nearest 0.000001. Longitudes are given to the nearest 0.000001. Latitude and longitude values are specified in Decimal degrees. The horizontal datum used is D_WGS_1984.
      The ellipsoid used is WGS_1984.
      The semi-major axis of the ellipsoid used is 6378137.000000.
      The flattening of the ellipsoid used is 1/298.257224.
      

      Vertical_Coordinate_System_Definition:

      Depth_System_Definition:

      Depth_Datum_Name: Local surface
      Depth_Resolution: 0.1
      Depth_Distance_Units: meters
      Depth_Encoding_Method: Attribute values
      

7. How does the data set describe geographic features?

   floodiso_geog

   ESRI point shapefile (Source: ESRI)

   FID

   Internal feature number. (Source: ESRI) Sequential unique whole numbers that are automatically generated.

   Shape

   Feature geometry. (Source: ESRI) Coordinates defining the features.

   easting

   Easting coordinate of the point in meters, UTM Zone 16, WGS84. (Source: U.S. Geological Survey)

   Range of values
   Minimum:	684510.87
   Maximum:	705389.91
   Units:	meters

   northing

   Northing coordinate of the point in meters, UTM Zone 16, WGS84. (Source: U.S. Geological Survey)

   Range of values
   Minimum:	3276398.26
   Maximum:	3289310.6
   Units:	meters

   ms

   The depth below the sea floor of the ravinement (flooding) surface in milliseconds two-way travel time. Negative values should be ignored as these values imply the ravinement (flooding) surface is above the sea floor and is erroneous. This occurs when a portion of the sea floor wasn't interpreted to the end of the line. (Source: Software calculated.)

   Range of values
   Minimum:	-3.39
   Maximum:	9.64
   Units:	milliseconds

   line

   Line name used in Landmark SeisWorks as the unique identifier for each seismic line. (Source: Data processor.) Character set.

   filter_ms

   Where the ravinement points are within 75 meters of a man-made feature, or are negative (invalid) values, this attribute is set to the NODATA value of -9999. Otherwise, the ms attribute is present here. This enables points to be excluded based on a selection criteria. (Source: Data processor.)

   Range of values
   Minimum:	0.09
   Maximum:	9.64
   Units:	milliseconds

   mtrs_1800

   The depth below the sea floor to the ravinement surface converted from milliseconds to meters based on a speed of sound of 1800 meters per second. (Source: Data processor.)

   Range of values
   Minimum:	0.081
   Maximum:	8.676
   Units:	meters

   Entity_and_Attribute_Overview:

   These values represent thickness values - the distance from the sea floor to the ravinement (flooding) surface.

   Entity_and_Attribute_Detail_Citation: U.S. Geological Survey
   

Who produced the data set?

1. Who are the originators of the data set? (may include formal authors, digital compilers, and editors)
   • David C. Twichell
   • VeeAnn A. Cross
2. Who also contributed to the data set?
3. To whom should users address questions about the data?

Why was the data set created?

How was the data set created?

1. From what previous works were the data drawn?

   none (source 1 of 1)

   U.S. Geological Survey, unpublished material, Data acquisition.

   Type_of_Source_Media: digital files
   Source_Contribution:

   The seismic data used for the interpretation comes from two different seismic systems. The bulk of the data are from the EdgeTech FSSB 424 system pole mounted on the R/V Rafael. These data were logged in SEG-Y format using SBLogger. This system had a 1/4 second fire rate. The remainder of the data, in the shallower areas, were acquired with the USGS IRIS system. IRIS is a remotely operated vehicle that has an EdgeTech FSSB 424 chirp sub-bottom profiling system mounted to it. The seismic data were recorded by JSTAR, a software package developed by EdgeTech. This system had a much faster fire rate, almost 15 times per second. The EdgeTech FSSB 424 is a chirp sub-bottom profiler that operates within a 4-24kHz frequency range. The IRIS vehicle is navigated using Real-Time Kinematic (RTK) GPS. The antenna is mounted directly on the platform to minimize navigational error. The R/V Rafael was also navigated with an RTK GPS system with the navigation antenna approximately 1.5 meters forward of the seismic transducer. This offset was not accounted for.

2. How were the data generated, processed, and modified?

   Date: 2006 (process 1 of 13)

   Two different seismic systems acquired data in Apalachicola Bay in 2006. One system was the EdgeTech FSSB 424 (4-24kHz) aboard the R/V Rafael. These data were acquired as SEG-Y files using SBLogger. The second seismic system was also an EdgeTech FSSB 424 chirp system mounted on the USGS autonomous vehicle IRIS. These data were acquired with JSTAR in JSF format and converted to SEG-Y format using a C-program written by Tom O'Brien (USGS, Woods Hole). These SEG-Y files were then converted from IEEE format to IBM floating point using SIOSEIS, and the shots were renumbered starting at one. With initial preparation work on the seismic data complete, these data and navigation needed to be loaded into Landmark SeisWorks software for interpretation. In order to load the seismic data and navigation into Landmark SeisWorks software the navigation needed to be extracted from the header of the seismic data. An AWK script was used to extract the navigation from the seismic data headers and export in UTM, Zone 16 eastings and northings, rounded to the nearest meter. Person who carried out this activity:
   

   U.S. Geological Survey

   Woods Hole Coastal and Marine Science Center

   Woods Hole, MA
   

   508-548-8700 (voice)

   508-457-2310 (FAX)

   Date: 2006 (process 2 of 13)

   Once the navigation is extracted from the seismic data, this navigation has to be loaded into the interpretation software - Landmark SeisWorks version R2003. The navigation is loaded using Data - Management - Seismic Data Manager. A new survey is created for each acquisition system (06001 for the Rafael data, asv06 for the IRIS data). Then, Data - Import - Seismic Data Loader and point to the navigation text file. When loading the navigation, use a decimation of 0, use first shot point if duplicates are found, and overwrite data in target project if necessary. A decimation of zero was used because the IRIS navigation had already been decimated to take every 5th record from the complete navigation extracted from the headers of the IRIS seismics. The Rafael data did not need decimation. The Rafael data had a 1/4 second fire rate while the IRIS data fired at approximately 15 shots per second. Once the navigation is loaded and verified, then the actual seismic data can be loaded. To do this, use PostStack Data Loader. There was a small issue in working with seismic data in SeisWorks where it's better to have all the seismic profiles at the same sample rate. It's a display issue in the interpretation phase where opening a profile in a window with a different sample rate than the previously loaded profile doesn't always refresh the window properly. The result is an incorrect interpretation - the interpreted line falls in the wrong spot vertically. The seismic data were resampled to the same sample rate to eliminate this problem. The Rafael acquired data at two different sample rates: 40 microseconds and 80 microseconds. The Rafael seismics were all resampled to 40 microseconds in the PostStack data loader. Additionally, the lines had an automatic 8-bit scaling applied to each profile when loaded. The IRIS seismic lines were acquired with two sample rates - 23 microseconds and 46 microseconds. All of the lines were resampled to a 40 microsecond sampling interval in PostStack data loader and had an automatic 8-bit scaling applied to each profile when loaded. With the seismic data now loaded, the project has to be modified so these changes are reflected in the surveys and the data can be interpreted. Person who carried out this activity:
   

   VeeAnn A. Cross

   U.S. Geological Survey

   Marine Geologist

   Woods Hole Coastal and Marine Science Center

   Woods Hole, MA
   

   (508) 548-8700 x2251 (voice)

   (508) 457-2310 (FAX)

   vatnipp@usgs.gov

   Date: 2007 (process 3 of 13)

   The ravinement horizon was created in SeisWorks, and this surface was digitized from each seismic reflection profile where present. Initially the interpreted surface was referred to as a ravinement surface, so most of the processing steps will use that terminology instead of the more appropriate flooding surface. On seismic-reflection profiles this surface has a high-amplitude signature where it separates Pleistocene deposits from Holocene estuarine fill and has a moderate amplitude signature where it crosses the paleo-valleys and separates the underlying seismic unit characterized by parallel, continuous, closely-spaced reflectors with moderate acoustic amplitude from the overlying unit characterized by weak-amplitude reflectors. Person who carried out this activity:
   

   David C. Twichell

   U.S. Geological Survey

   Oceanographer

   Woods Hole Coastal and Marine Science Center

   Woods Hole, MA
   

   (508) 548-8700 x2266 (voice)

   (508) 457-2310 (FAX)

   dtwichell@usgs.gov

   Date: 2008 (process 4 of 13)

   Once the interpretation was complete, the ravinement horizon was subtracted from the sea floor horizon to create a ravinement isopach unit. This isopach unit was then exported as a text file with the following information in separate columns for each point: line name, easting, northing, and thickness of the unit in milliseconds (two-way travel time). This process step and all subsequent process steps were overseen by the same person - VeeAnn A. Cross. Person who carried out this activity:
   

   VeeAnn A. Cross

   U.S. Geological Survey

   Marine Geologist

   Woods Hole Coastal and Marine Science Center

   Woods Hole, MA
   

   (508) 548-8700 x2251 (voice)

   (508) 457-2310 (FAX)

   vatnipp@usgs.gov

   Date: 2008 (process 5 of 13)

   A header line is added to the exported text file, and converted from a tab-delimited file to a comma-delimited file.

   Date: 2008 (process 6 of 13)

   ArcMap 9.2 was used to load this text file as an event theme using Tools - Add XY data. The projection is defined on input as UTM, Zone 16, WGS84.

   Date: 2008 (process 7 of 13)

   This event theme is converted to a shapefile by right mouse click - Data - Export Data and generating the output shapefile raviso.shp.

   Date: 2008 (process 8 of 13)

   Any points falling outside Apalachicola Bay were deleted. The following attributes were added to the shapefile: filter_ms, and mtrs_1800. The Selection tool (select by location) was used to select any points falling within 75 meters of a man-made feature. Features were selected that intersected ApalachicolaBaseMap polygon shapefile with a buffer applied to the polygon of 75 meters. The ApalachicolaBaseMap polygon is available from USGS Open-File Report 2006-1381. With these records selected, a value of -9999 was assigned to the filter_ms attribute using field calculator. The selection was switched to the other records and the field calculator was used to copy the ms attribute values to the filter_ms attribute. Field calculator was used to populate the attribute mtrs_1800 by converting the isopach thickness in milliseconds to thickness in meters using 1800 meters per second where filter_ms does not equal -9999. In cases where filters_ms=-9999, mtrs_1800 is set to the value -9999 (a common NODATA value).

   Date: 2010 (process 9 of 13)

   The original shapefile in UTM, Zone 16, WGS84 was projected to Geographic, WGS84 using ArcMap 9.2 - ArcToolbox - Data Management Tools - Projections and Transformations - Feature - Project. No datum transformation was necessary. The shapefile was renamed to the more appropriate floodiso_geog.shp.

   Date: 29-Jun-2016 (process 10 of 13)

   Edits to the metadata were made to fix any errors that MP v 2.9.32 flagged. This is necessary to enable the metadata to be successfully harvested for various data catalogs. In some cases, this meant adding text "Information unavailable" or "Information unavailable from original metadata" for those required fields that were left blank. Other minor edits were probably performed (title, publisher, publication place, etc.). The source information was incomplete and had to be modified to meet the standard. The distribution format name was modified in an attempt to be more consistent with other metadata files of the same data format. The metadata date (but not the metadata creator) was edited to reflect the date of these changes. The metadata available from a harvester may supersede metadata bundled within a download file. Compare the metadata dates to determine which metadata file is most recent. Person who carried out this activity:
   

   U.S. Geological Survey

   Attn: VeeAnn A. Cross

   Marine Geologist

   384 Woods Hole Rd.

   Woods Hole, MA
   

   508-548-8700 x2251 (voice)

   508-457-2310 (FAX)

   vatnipp@usgs.gov

   Date: 20-Jul-2018 (process 11 of 13)

   USGS Thesaurus keywords added to the keyword section. Person who carried out this activity:
   

   U.S. Geological Survey

   Attn: VeeAnn A. Cross

   Marine Geologist

   384 Woods Hole Road

   Woods Hole, MA
   

   508-548-8700 x2251 (voice)

   508-457-2310 (FAX)

   vatnipp@usgs.gov

   Date: 18-Nov-2019 (process 12 of 13)

   Crossref DOI link was added as the first link in the metadata. Person who carried out this activity:
   

   U.S. Geological Survey

   Attn: VeeAnn A. Cross

   Marine Geologist

   384 Woods Hole Road

   Woods Hole, MA
   

   508-548-8700 x2251 (voice)

   508-457-2310 (FAX)

   vatnipp@usgs.gov

   Date: 08-Sep-2020 (process 13 of 13)

   Added keywords section with USGS persistent identifier as theme keyword. Person who carried out this activity:
   

   U.S. Geological Survey

   Attn: VeeAnn A. Cross

   Marine Geologist

   384 Woods Hole Road

   Woods Hole, MA
   

   508-548-8700 x2251 (voice)

   508-457-2310 (FAX)

   vatnipp@usgs.gov

3. What similar or related data should the user be aware of?
   Twichell, D.C., Andrews, B.D., Edmiston, H.L., and Stevenson, W.R., 2007, Geophysical mapping of oyster habitats in a shallow estuary; Apalachicola Bay, Florida: Open-File Report 2006-1381, U.S. Geological Survey, Reston, VA.

   Online Links:

   • http://pubs.usgs.gov/of/2006/1381/

   Twichell, D.C., Pendleton, E.A., Poore, R.Z., Osterman, L.E., and Kelso, K.W., 2009, Vibracore, radiocarbon, microfossil, and grain-size data from Apalachicola Bay, Florida: Open-File Report 2009-1031, U.S. Geological Survey, Reston, VA.

   Online Links:

   • http://pubs.usgs.gov/of/2009/1031/

   Bergeron, E., Worley, C.R., and O'Brien, T.F., 2007, Progress in the development of shallow-water mapping systems: using an autonomous surface vehicle for shallow-water geophysical studies: Sea Technology v. 48, no. 6, p. 10-15, Compass Publications, Inc., Arlington, VA.

How reliable are the data; what problems remain in the data set?

1. How well have the observations been checked?
   
2. How accurate are the geographic locations?
   The R/V Rafael acquired data recording navigation using a Real Time Kinematic (RTK) GPS at a one second interval. The GPS antenna was mounted over the bathymetric sonar. The seismic pole mount system was on the starboard side and approximately 1.5 meters aft of the bathymetry system. No offset was added to the navigation for the seismic data. For seismic data collected with the IRIS system, an RTK GPS system was also used. The GPS antenna for IRIS was mounted directly over the seismic transducer. This system can provide positions to within 0.1 meters. However, due to some errors with the acquisition software, this accuracy is reduced. The accuracy is approximately 2 m given the constraints of the acquisition system.
3. How accurate are the heights or depths?
   For the Rafael seismic system, the transducers were located approximately 1 meter below the water surface. This offset was not adjusted for. For the IRIS system, the transducers are barely below the water surface, less than half a meter. This depth is not adjusted for.
4. Where are the gaps in the data? What is missing?
   All useable seismic-reflection profiles collected in 2006 within Apalachicola Bay were used in the interpretation.
5. How consistent are the relationships among the observations, including topology?
   All data were handled in the same manner.

How can someone get a copy of the data set?

1. Who distributes the data set? (Distributor 1 of 1)
   
   VeeAnn A. Cross

   U.S. Geological Survey

   Marine Geologist

   Woods Hole Coastal and Marine Science Center

   Woods Hole, MA
   

   (508) 548-8700 x2251 (voice)

   (508) 457-2310 (FAX)

   vatnipp@usgs.gov
2. What's the catalog number I need to order this data set? Downloadable Data
3. What legal disclaimers am I supposed to read?
   Neither the U.S. government, the Department of the Interior, nor the USGS, nor any of their employees, contractors, or subcontractors, make any warranty, express or implied, nor assume any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, nor represent that its use would not infringe on privately owned rights. The act of distribution shall not constitute any such warranty, and no responsibility is assumed by the USGS in the use of these data or related materials. Any use of trade, product, or firm names is for descriptive purposes only and does not imply endorsement by the U.S. Government.
4. How can I download or order the data?
   • Availability in digital form:

     Data format:	This WinZip file contains the point shapefile as well as the associated metadata files. in format Shapefile (version ArcGIS 9.2) Size: 4.4
     Network links:	http://pubs.usgs.gov/of/2012/1003/data/shapefiles/floodiso_geog.zip http://pubs.usgs.gov/of/2012/1003/html/catalog.html

   • Cost to order the data: None

5. What hardware or software do I need in order to use the data set?
   This WinZip file contains data available in ESRI point shapefile format. The user must have software capable of uncompressing the WinZip file and reading/displaying the shapefile.

Who wrote the metadata?

Dates:

Last modified: 18-Mar-2024

Metadata author:

VeeAnn A. Cross

U.S. Geological Survey

Marine Geologist

Woods Hole Coastal and Marine Science Center

Woods Hole, MA

(508) 548-8700 x2251 (voice)

(508) 457-2310 (FAX)

whsc_data_contact@usgs.gov

Contact_Instructions:

The metadata contact email address is a generic address in the event the person is no longer with USGS. (updated on 20240318)

Metadata standard:

FGDC Content Standards for Digital Geospatial Metadata (FGDC-STD-001-1998)