2017 QUARTER 02

A B C D E F G H I K L M N O P R S T U V W
PD-03 - Development environments for geospatial applications
  • Develop a geospatial application using the most appropriate environment
  • Compare and contrast the relative merits of available environments for geospatial applications, including desktop software scripting (e.g., VBA), graphical modeling tools, geospatial components in standard environments, and “from-scratch” development in standard environments
DM-20 - Discrete entities
  • Discuss the human predilection to conceptualize geographic phenomena in terms of discrete entities
  • Compare and contrast differing epistemological and metaphysical viewpoints on the “reality” of geographic entities
  • Identify the types of features that need to be modeled in a particular GIS application or procedure
  • Identify phenomena that are difficult or impossible to conceptualize in terms of entities
  • Describe the difficulties in modeling entities with ill-defined edges
  • Describe the difficulties inherent in extending the “tabletop” metaphor of objects to the geographic environment
  • Evaluate the effectiveness of GIS data models for representing the identity, existence, and lifespan of entities
  • Justify or refute the conception of fields (e.g., temperature, density) as spatially-intensive attributes of (sometimes amorphous and anonymous) entities
  • Model “gray area” phenomena, such as categorical coverages (a.k.a. discrete fields), in terms of objects
  • Evaluate the influence of scale on the conceptualization of entities
  • Describe the perceptual processes (e.g., edge detection) that aid cognitive objectification
  • Describe particular entities in terms of space, time, and properties
FC-14 - Distance, Length, and Direction
  • Describe several different measures of distance between two points (e.g., Euclidean, Manhattan, network distance, spherical)
  • Explain how different measures of distance can be used to calculate the spatial weights matrix
  • Explain why estimating the fractal dimension of a sinuous line has important implications for the measurement of its length
  • Explain how fractal dimension can be used in practical applications of GIS
  • Explain the differences in the calculated distance between the same two places when data used are in different projections
  • Outline the implications of differences in distance calculations on real world applications of GIS, such as routing and determining boundary lengths and service areas
  • Estimate the fractal dimension of a sinuous line
  • Describe operations that can be performed on qualitative representations of direction
  • Explain any differences in the measured direction between two places when the data are presented in a GIS in different projections
  • Compute the mean of directional data
  • Compare and contrast how direction is determined and stated in raster and vector data
  • Define “direction” and its measurement in different angular measures
KE-13 - Economics and the role of information
  • Discuss the general role of information in economics
  • Describe the role of economics in the use of geospatial information
  • Describe the role of economics in public and private production of geospatial information
GS-09 - Enforcing control
  • Explain the concept of “fair use” with regard to geospatial information
  • Describe defenses against various claims of copyright infringement
  • Discuss ways in which copyright infringements may be remedied
  • Identify types of copyright infringement
GS-13 - Epistemological critiques
  • Discuss critiques of GIS as “deterministic” technology in relation to debates about the Quantitative Revolution in the discipline of geography
  • Describe the extent to which contemporary GIS&T supports diverse ways of understanding the world
  • Discuss the implications of interoperability on ontology
  • Explain the argument that GIS privileges certain views of the world over others
  • Identify alternatives to the “algorithmic way of thinking” that characterizes GIS
FC-02 - Epistemology
  • Explain the notions of model and representation in science
  • Identify the epistemological assumptions underlying the work of colleagues
  • Bridge the differences in epistemological viewpoints to enable work with diverse colleagues
  • Define common theories on what constitutes knowledge, including positivism, reflectance-correspondence, pragmatism, social constructivism, and memetics
  • Justify the epistemological frameworks with which you agree
  • Recognize the influences of epistemology on GIS practices
  • Compare and contrast the ability of various theories to explain different situations
FC-25 - Error
  • Compare and contrast how systematic errors and random errors affect measurement of distance
  • Describe the causes of at least five different types of errors (e.g., positional, attribute, temporal, logical inconsistency, and incompleteness)
DM-32 - Error-based uncertainty
  • Define uncertainty-related terms, such as error, accuracy, uncertainty, precision, stochastic, probabilistic, deterministic, and random
  • Recognize expressions of uncertainty in language
  • Evaluate the causes of uncertainty in geospatial data
  • Describe a stochastic error model for a natural phenomenon
  • Explain how the familiar concepts of geographic objects and fields affect the conceptualization of uncertainty
  • Recognize the degree to which the importance of uncertainty depends on scale and application
  • Differentiate uncertainty in geospatial situations from vagueness
GS-14 - Ethical critiques
  • Defend or refute the argument that GIS&T professionals are culpable for applications that result in civilian casualties in warfare
  • Discuss the ethical implications of the use of GIS&T as a surveillance technology
  • Defend or refute the argument that the “digital divide” that characterizes access to GIS&T perpetuates inequities among developed and developing nations, among socio-economic groups, and between individuals, community organizations, and public agencies and private firms

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