Unit 3: Static GPS/GNSS Methods part of High Precision Positioning with Static and Kinematic GPS
Ben Crosby, Idaho State University
The application of Global Navigation Satellite Systems (GNSS) in the earth sciences has become commonplace. GNSS data can produce high-accuracy, high-resolution measurements in common reference frames. Static GNSS ...

Unit 3: Understanding landslide factors part of Surface Process Hazards
Becca Walker, Mt. San Antonio College
How do slope characteristics and magnitude of forces dictate whether or not a slope will fail? Can environmental and built characteristics change the magnitude of these forces? In this unit, students qualitatively ...

Unit 2: Reading the landscape part of Surface Process Hazards
Sarah Hall, College of the Atlantic; Becca Walker, Mt. San Antonio College
How do geologic, hydrologic, biologic, and built-landscape features manifest themselves on maps? In this unit, students will use topographic maps, hillshade maps, and aerial imagery to learn to recognize a variety ...

Unit 3: Monitoring groundwater storage with GPS vertical position part of Measuring Water Resources
Bruce Douglas, Indiana University-Bloomington; Eric Small, University of Colorado at Boulder
This unit shows how GPS records of surface elevation can be used to monitor groundwater changes. Students calculate secular trends in the GPS time series and then use the original and detrended records to identify ...

Unit 3.2 - Landforms and Remote Sensing part of Critical Zone Science
Tim White, Pennsylvania State University-Main Campus
In this unit, geomorphic environments and the processes that can move and shape them are explored to learn about the links between landforms, soils, and the Critical Zone. The fundamentals of geomorphology are ...

Unit 5: Summative assessment project part of Analyzing High Resolution Topography with TLS and SfM
Bruce Douglas (Indiana University) Chris Crosby (EarthScope Consortium) Kate Shervais (UNAVCO)
Unit 5 is the summative assessment for the module. This final exercise takes eight to ten hours. The exercise evaluates students' developed skills in survey design, execution of a geodetic survey, and simple ...

Weathering and Sedimentary Processes in Google Streetview part of GET Spatial Learning:Teaching Activities
Nicole LaDue, Northern Illinois University
This exercise uses Google Streetview, in combination with 360 degree immersive photographs, to show students real-world examples of the sedimentary rocks, sedimentary structures, and weathering processes that they ...

Unit 4: The phenomenology of earthquakes from InSAR data part of Imaging Active Tectonics
Bruce Douglas, Indiana University-Bloomington; Gareth Funning, University of California-Riverside
How are different types of earthquakes represented in InSAR data? How can we obtain detailed information on the earthquake source from InSAR data? How well can we resolve those details? In this unit, students ...

Unit 3: How to see an earthquake from space (InSAR) part of Imaging Active Tectonics
Bruce Douglas, Indiana University-Bloomington; Gareth Funning, University of California-Riverside
How can we tell what style of faulting was responsible for a particular earthquake? Especially in cases where there is limited instrumentation in a region, or where geologists have difficulty accessing the affected ...

Google Earth Investigation of Pleistocene Flood Deposits Across the Pacific Northwest part of Teaching Activities
Elizabeth Cassel, University of Idaho
In this activity, students use Google Earth Pro to examine and measure sedimentary and geomorphic structures related to the late Pleistocene draining of glacial Lake Missoula and Lake Bonneville.