2019 QUARTER 01

A B C D E F G H I K L M N O P R S T U V W

Identify potential sources of data (free or commercial) needed for a particular application or enterprise
Judge the relative merits of obtaining free data, purchasing data, outsourcing data creation, or producing and managing data in-house for a particular application or enterprise
Estimate the cost to collect needed data from primary sources (e.g., remote sensing, GPS)

Describe how data mining can be used for geospatial intelligence
Explain how the analytical reasoning techniques, visual representations, and interaction techniques that make up the domain of visual analytics have a strong spatial component
Demonstrate how cluster analysis can be used as a data mining tool
Interpret patterns in space and time using Dorling and Openshaw’s geographical analysis machine (GAM) demonstration of disease incidence diffusion
Differentiate between data mining approaches used for spatial and non-spatial applications
Explain how spatial statistics techniques are used in spatial data mining
Compare and contrast the primary types of data mining: summarization/characterization, clustering/categorization, feature extraction, and rule/relationships extraction

Analyze the relative performance of data retrieval strategies
Implement algorithms that retrieve geospatial data from a range of data structures
Describe the particular advantages of Morton addressing relative to geographic data representation
Discuss the advantages and disadvantages of different data structures (e.g., arrays, linked lists, binary trees, hash tables, indexes) for retrieving geospatial data
Compare and contrast direct and indirect access search and retrieval methods

Describe formal and informal arrangements that promote geospatial data sharing (e.g., FGDC, ESDI, memoranda of agreements, informal access arrangements, targeted funding support)
Describe a situation in which politics interferes with data sharing and exchange

Describe how using standards can affect implementation of a GIS
Explain how validation and verification processes can be used to maintain database integrity
Summarize how data access processes can be a factor in development of an enterprise GIS implementation
Describe effective methods to get stakeholders to create, adopt, or develop and maintain metadata for shared datasets

Describe a stochastic error model for a natural phenomenon
Differentiate between the following concepts: vagueness and ambiguity, well defined and poorly defined objects, and fields or discord and non-specificity
Explain how the familiar concepts of geographic objects and fields affect the conceptualization of uncertainty

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

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

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

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