@proceedings {317, title = {Guiding principles for use of digital technology in geologic data collection and distribution}, volume = {46}, year = {2014}, month = {2014/01/01/}, pages = {75 - 75}, publisher = {Geological Society of America (GSA) : Boulder, CO, United States}, abstract = {The past decade has seen a dramatic shift in the public perception of a map as a static paper document to a dynamic digital interface for addressing a specific geographic question. The adoption of digital technology for geologic data collection, compilation, and distribution has many advantages but requires a similar shift in attitudes towards the nature of data and resulting maps themselves to ensure that they remain accessible, viable, and relevant in this new paradigm. We propose a set of guiding principles for the use of digital technology in geologic data and map production: 1.) Utilize dedicated digital data professionals (DDPs): It is unreasonable to expect that geologists maintain expertise in their field and be thoroughly versed in complex and rapidly changing best practices for digital data. Following the recommendations of the National Research Council (2009), DDPs should be embedded in any research endeavor from its inception with geologists being savvy enough in digital technology to maintain productive engagement with DDPs. 2.) Use appropriate technology: Fully digital workflows and field equipment are not appropriate for all projects. Free or open-source software (FOSS) and easily available low-cost hardware (i.e., smartphones) have also met or surpassed the utility of many proprietary technology solutions thus reducing the price and increasing accessibility of data. 3.) Practice good data management: Digital data takes considerable resources and sustained effort to remain viable even shortly after its production. Best practices in data accessibility (data standards, open formats, etc.) and maintenance (refreshing, migration, etc.) in addition to robust metadata creation, through all phases of a project, are unquestionably necessary. 4.) Approach maps and digital data as living dynamic entities: Geologic data is out of date the moment it is published. A primary advantage of digital datasets is their ability to be easily updated, queried, and manipulated in infinite ways. Derivative products for specific applications are in arguably higher demand by end users than the data itself. Geologists must design for flexibility, appropriateness of use, and the persistence of their expert interpretations through development of all possible end products of and updates to the map and dataset.}, keywords = {$\#$StaffPubs, data, data preservation, databases, digital, digital data, digital geologic maps, geologic maps, GIS, migration}, isbn = {00167592}, url = {https://gsa.confex.com/gsa/2014NE/webprogram/Paper236362.html}, author = {Joseph P Kopera and House, P. Kyle and Schmidt, Maxine and Clark, Ryan} } @proceedings {269, title = {An update of geologic mapping in Massachusetts}, volume = {36}, year = {2004}, note = {Accession Number: 2005-048993; Conference Name: Geological Society of America, Northeastern Section, 38th annual meeting; Geological Society of America, Southeastern Section, 53rd annual meeting; Washington, DC, United States; Conference Date: 20040325; Language: English; Coden: GAAPBC; Collation: 1; Collation: 58; Publication Types: Abstract Only; Serial; Conference document; Updated Code: 200518; Monograph Title: Geological Society of America, Northeastern Section, 38th annual meeting; Geological Society of America, Southeastern Section, 53rd annual meeting; Monograph Author(s): Anonymous; Reviewed Item: Analytic}, month = {2004/03/01/}, pages = {58 - 58}, publisher = {Geological Society of America (GSA) : Boulder, CO, United States}, address = {United States}, abstract = {Despite the state{\textquoteright}s relatively high population density and decades of detailed study of the bedrock geology, only about half of the 7.5{\textquoteright} quadrangles in Massachusetts have been published as GQ series geologic maps. As the state{\textquoteright}s population continues to grow, the availability of basic geologic data becomes increasingly crucial for informed land-use and water-management decision making. Much of the published 1:24000 scale geologic mapping predates recent advances in the understanding of regional tectonics, and needs to be updated. The Office of the State Geologist has begun a geologic mapping program in Massachusetts to address these needs. Two mapping projects were conducted through the STATEMAP component of the National Cooperative Geologic Mapping program in 2003. These projects focused on 7.5{\textquoteright} quadrangles along the I-495 corridor, which is experiencing extensive population growth and development. The first project involved conversion of published 1:24,000-scale surficial geology to digital form for 10 quadrangles in southeastern Massachusetts. A semi-automated process was developed for this project that easily converts published paper geologic maps into vectorized, georeferenced datalayers. The second project involved 1:24000-scale geologic mapping of the Marlborough quadrangle in east-central Massachusetts. Products include traditional maps of bedrock and surficial geology as well as two new prototype products: a fracture characterization map and a surficial materials map. These projects mark the first time in Massachusetts{\textquoteright} history that quadrangle-scale geologic data will be available in digital form to consultants and stakeholders, thus greatly expediting and improving the use and analysis of all geologic data. In addition, the inclusion of fracture characterization and surficial materials maps adds substantially to the value of traditional geologic map products. The new maps provide supplemental data on the hydrologic characteristics of the bedrock and the vertical stacking of surficial deposits that previously was unavailable. STATEMAP projects in 2004 will continue to focus along the I-495 corridor, and will involve revision and new mapping in the Wilmington, Reading, South Groveland, Lawrence, Hudson, and Oxford quadrangles.}, keywords = {$\#$StaffPubs, data, data acquisition, data processing, digital data, Geologic maps 14, mapping, massachusetts, National Cooperative Geologic Mapping Program, programs, publications, regional, review, STATEMAP, United States}, isbn = {00167592}, author = {Joseph P Kopera and Stephen B Mabee and Scott A Salamoff and Hildreth, Carol} } @online {50, title = {MA DCR - Office of Water Resources Rainfall Program}, publisher = {Massachusetts Department of Conservation and Recreation}, keywords = {data, massachusetts, rainfall, water, water resources, water supply}, url = {http://www.mass.gov/dcr/waterSupply/rainfall/index.htm} } @online {129, title = {The Massachusetts DEP Hydrogeologic Information Matrix}, publisher = {MassDEP}, abstract = {An index of all USGS geologic maps and hydrogeologic publications for Massachusetts, cross-referenced and indexed by town and 7.5{\textquoteright} quadrangle. This is an extremely valuable resource for finding geologic data for a given site. }, keywords = {$\#$BedrockMaps, $\#$Hydro, $\#$MapDatabase, $\#$MapsDataPublications, $\#$QuadIndex, $\#$SurficialMaps, aquifer, catalog, data, database, GEOLOGIC MAP, ground source heat pumps, groundwater, hydrogeology, index, maps, quadrangles, water resources}, url = {http://www.mass.gov/eea/docs/dep/water/compliance/hydromat.pdf} } @online {127, title = {National Geologic Map Database}, publisher = {USGS}, abstract = {Search here first for any and all geologic map data for the Commonwealth before searching the links below.}, keywords = {$\#$MapDatabase, $\#$MapsDataPublications, catalog, data, database, GEOLOGIC MAP, index, maps}, url = {http://ngmdb.usgs.gov/} } @online {136, title = {Reading Maps with a Critical Eye: Becoming an Informed Map Reader}, publisher = {Maine Geological Survey}, abstract = {New to using geologic maps? This is a great guide to learning how to read and get the most out of geologic maps}, keywords = {$\#$MapsDataPublications, $\#$UsingGeologicMaps, catalog, data, database, GEOLOGIC MAP, how to, index, maps, using geologic maps}, url = {http://www.maine.gov/doc/nrimc/mgs/mapuse/informed/informed.htm} } @online {128, title = {USGS Publications Warehouse}, publisher = {USGS}, abstract = {Search here second for any and all geologic data for the Commonwealth before searching the links below.}, keywords = {$\#$MapDatabase, $\#$MapsDataPublications, catalog, data, database, GEOLOGIC MAP, index, maps}, url = {http://infotrek.er.usgs.gov/pubs/} } @online {134, title = {What 7.5{\textquoteright} quadrangle am I in?: A PDF of a paper map}, publisher = {MassGIS}, abstract = {

Download a PDF map showing which towns are in which 7.5{\textquoteright} quadrangles.

}, keywords = {$\#$MapsDataPublications, $\#$QuadIndex, catalog, data, database, GEOLOGIC MAP, index, maps, quadrangles, what town}, url = {http://www.geo.umass.edu/stategeologist/Quads_Towns_WS7_34x44.pdf} } @online {135, title = {What 7.5{\textquoteright} quadrangle am I in?: KMZ of 7.5" quadrangles for use in Google Earth}, publisher = {MGS}, abstract = {

A Google Earth KMZ file showing the locations of 7.5{\textquoteright} quadrangles in Massachusetts

}, keywords = {$\#$MapsDataPublications, $\#$QuadIndex, catalog, data, database, GEOLOGIC MAP, index, maps, quadrangles, what town}, url = {http://www.geo.umass.edu/stategeologist/QuadTownsWatersheds.kmz} }