This course, is designed to be a descriptive and analytical overview of water organs, availability, location and flow. It will be examined in the light of problems, possibilities and policy and consider historical perspectives.

Relation of purpose of data to data requirements. Relation of data to costs.
Accuracy requirements of measurements and error propagation:
Related to a problem the required accuracy of measurements and the consequences for accuracy in the final result are discussed. Different types of errors are handled. Propagation of errors; for dependent and independent measurements, from mathematical relations and regression is demonstrated. Recapitulated is the theory of regression and correlation.
Interpretation of measurements, data completion: By standard statistical methods screening of measured data is performed; double mass analysis, residual mass, simple rainfall-runoff modelling. Detection of trends; split record tests, Spearman rank tests. Methods to fill data gaps and do filtering on data series for noise reduction.
Methods of hydrological measurements and measuring equipment: To determine quantitatively the most important elements in the hydrological cycle an overview is presented of most common hydrological measurements, measuring equipment and indirect determination methods i.e. for precipitation, evaporation, transpiration, river discharge and groundwater tables. Use, purpose and measurement techniques for tracers in hydrology is discussed.
Advantages and disadvantages and specific condition/application of methods are discussed. Equipment is demonstrated and discussed.
Areal distributed observation: Areal interpolation techniques of point observations: inverse distance, Thiessen, contouring, Kriging. Comparison of interpolation techniques and estimation of errors. Correlation analysis of areal distributed observation of rainfall
Design of measuring networks: Based on correlation characteristics from point measurements (e.g. rainfall stations) and accuracy requirements the design of a network of stations is demonstrated.

The course deals with the principles of hydrology of catchment areas, rivers and deltas. The students will learn:

1). to understand the relations between hydrological processes in catchment areas
2?. to understand and to calculate the propagation of flood waves
3). to understand hydrological processes in deltas
4). to draft frequency analysis of extremes under different climatological conditions.

This course covers fundamentals of subsurface flow and transport, emphasizing the role of groundwater in the hydrologic cycle, the relation of groundwater flow to geologic structure, and the management of contaminated groundwater. The class includes laboratory and computer demonstrations.

Students should research and define terminology included in the exercise (example - drainage basin) prior to lab. Pre-lab lecture should include basic concepts of hydrology (stream networks, basins) and an example of Strahler Stream Order. Students in a GIS-capable class can follow the instructions to create relevant maps and datasets. Students in introductory (non-GIS) classes should use pre-printed figures and tracing paper to complete the exercises.

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Fundamentals of subsurface flow and transport, emphasizing the role of groundwater in the hydrologic cycle, the relation of groundwater flow to geologic structure, and the management of contaminated groundwater. Topics include: Darcy equation, flow nets, mass conservation, the aquifer flow equation, heterogeneity and anisotropy, storage properties, regional circulation, unsaturated flow, recharge, stream-aquifer interaction, well hydraulics, flow through fractured rock, numerical models, groundwater quality, contaminant transport processes, dispersion, decay, and adsorption. Includes laboratory and computer demonstrations.

In this unit, students investigate water from a global perspective. The focus of students learning is on the identification of storehouses where Earth's water is stored, how matter (water) cycles through the geosphere (lithosphere, atmosphere, hydrosphere) and biosphere, and the energy associated with water as it changes between a solid, liquid and gas state. The unit investigations conclude with a short homework assignment on the application of the hydrologic cycle from a regional perspective as you research the quality and availability of fresh water in the state where you live. An important factor is the consideration for the percentage of fresh water that is readily available for human consumption and the impact of human activity on the quality of the water.

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This research paper assignment is designed for my Junior level Hydrology course for majors. The intent of the project to to make sure my students can conduct literature reviews, outline a research project and obtain practice in formatting their work for publication. Getting my students prepared to enter the workforce and/or graduate school with these skill sets is imperative for their future success, since in the sciences we write more than we conduct research.

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This assignment will introduce students to surface hydrologic modeling in GIS and derived products such as stream power and wetness indices.

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This video looks at how water is provided for our use through the hydrologic cycle. It also explains how global climate change disturbs the storage of water in the various global compartments. This video is part of the Sustainability Learning Suites, made possible in part by a grant from the National Science Foundation. See 'Learn more about this resource' for Learning Objectives and Activities.

In this activity, students focus on ecosystem services specifically related to the hydrologic cycle. Using rainfall-runoff data for a small watershed in Ohio, students are introduced to the technical vocabulary associated with watersheds, watershed hydrology, and water balance. Working with hydrologic data will enable the students to test their understanding of watershed hydrology and the water balance equation, which is a measure of how much water is stored within different parts of the watershed.

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HydroViz is an educational "virtual" hydrologic observatory developed for a "real" watershed and is based on integration of field data, remote sensing observations and computer simulations of hydrologic variables and processes. The main purpose of HydroViz is to support hydrology education in engineering and earth science courses.

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This is a four-part exercise. First, students use discharge and precipitation data to create and interpret hydrographs. In part 2, students are provide with 25 years of mean annual discharge for a river and they calculate and plot recurrence interval to estimate discharge for given recurrence intervals and estimate the recurrence interval for given discharges. Students then create a cross-sectional profile and conduct a series of calculations. In the final part, students create and interpret a longitudinal profile.

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This module discusses the hydrologic cycle and its impacts on the planet Earth. Additionally, the module addresses connections between the hydrologic cycle, climate and the impacts humans have had on the cycle.

At the University of Vermont, instructors used land use change, driven by development of the University of Vermont campus and recent student occupancy of surrounding neighborhoods in Burlington, Vermont, as an opportunity for service learning and for teaching fundamental hydrologic and geologic skills. Students from a Geomorphology class, Geohydrology class and student senior research projects all worked on the preoject. In each of these studies, students worked closely with City and University staff and presented results at local forums, professional national meeting, and on the World Wide Web. These service-learning projects have received positive feedback from the students, city officals, and community members.

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Unit 2 engages students in topics related to the water cycle, both from natural and urban system perspectives. Students are assigned approximately 30 minutes of reading (short article) and are required to watch a 15-minute video before class to gain a basic understanding of the natural and urban water cycles, their components, and the impact of urbanization on runoff. Through short lectures, discussion questions, solution to example problems, and a group activity, students gain comprehension of the water cycle components, their spatial and temporal variability, water budget calculation, and the impacts of urbanization on surface water.

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Students will be introduced to the concept of a natural cycle. They are first asked to identify the different components of the hydrologic cycle. Students will be able to recognize the delicate balance between the individual elements of a large and complex system. Students will also be able to identify the interactions among parts of a natural system.

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Using a jigsaw approach, students investigate biogeochemical transformations of water as it moves through the hydrologic cycle. In the first phase, student groups are given a schematic representation of the hydrologic cycle with representative concentrations of a single variable (nitrate, silica, pH and conductivity) provided for oceans, precipitation, streams, and shallow and deep groundwater. After each group has achieved a satisfactory explanation of its own variable, students are recombined to explain and compare the processes that control each variable, and to look for common themes (e.g., weathering reactions in subsurface increase conductivity, silica and pH). The resulting conceptual framework facilitates use of water-quality variables as tracers to interpret runoff processes and stream-flow sources.

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This exercise is designed to evaluate the students' understanding of both the hydrologic cycle and the water budget (mass balance) equation. In my course, the exercise is the students' first exposure to models in the course. While the exercise may seem basic, students gain experience in creating conceptual models and then generating mathematical models from the conceptual model. The exercise provides students with an introduction (or refresher) to some basic Excel formulas. Finally, the exercise can be modified to include more "what if" scenarios that require critical thinking and analysis from the students.

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Students compare traditional paper-based techniques associated with estimating areal precipitation, watershed delineation, and modeling evapotranspiration. This assignment challenges students to consider the various assumptions involved with both analog and digital analyses and highlights the strengths and weaknesses of both approaches.