This case study-based class assignment (see Appendix A) is designed as a culminating course activity through which students demonstrate not only their understanding of school finance basics but also show how to apply their knowledge to solving a problem i

This course examines the science of natural catastrophes such as earthquakes and hurricanes and explores the relationships between the science of and policy toward such hazards. It presents the causes and effects of these phenomena, discusses their predictability, and examines how this knowledge influences policy making. This course includes intensive practice in the writing and presentation of scientific research and summaries for policy makers.

This course is designed to introduce the student to the study of Calculus through concrete applications. Upon successful completion of this course, students will be able to: Define and identify functions; Define and identify the domain, range, and graph of a function; Define and identify one-to-one, onto, and linear functions; Analyze and graph transformations of functions, such as shifts and dilations, and compositions of functions; Characterize, compute, and graph inverse functions; Graph and describe exponential and logarithmic functions; Define and calculate limits and one-sided limits; Identify vertical asymptotes; Define continuity and determine whether a function is continuous; State and apply the Intermediate Value Theorem; State the Squeeze Theorem and use it to calculate limits; Calculate limits at infinity and identify horizontal asymptotes; Calculate limits of rational and radical functions; State the epsilon-delta definition of a limit and use it in simple situations to show a limit exists; Draw a diagram to explain the tangent-line problem; State several different versions of the limit definition of the derivative, and use multiple notations for the derivative; Understand the derivative as a rate of change, and give some examples of its application, such as velocity; Calculate simple derivatives using the limit definition; Use the power, product, quotient, and chain rules to calculate derivatives; Use implicit differentiation to find derivatives; Find derivatives of inverse functions; Find derivatives of trigonometric, exponential, logarithmic, and inverse trigonometric functions; Solve problems involving rectilinear motion using derivatives; Solve problems involving related rates; Define local and absolute extrema; Use critical points to find local extrema; Use the first and second derivative tests to find intervals of increase and decrease and to find information about concavity and inflection points; Sketch functions using information from the first and second derivative tests; Use the first and second derivative tests to solve optimization (maximum/minimum value) problems; State and apply Rolle's Theorem and the Mean Value Theorem; Explain the meaning of linear approximations and differentials with a sketch; Use linear approximation to solve problems in applications; State and apply L'Hopital's Rule for indeterminate forms; Explain Newton's method using an illustration; Execute several steps of Newton's method and use it to approximate solutions to a root-finding problem; Define antiderivatives and the indefinite integral; State the properties of the indefinite integral; Relate the definite integral to the initial value problem and the area problem; Set up and calculate a Riemann sum; Estimate the area under a curve numerically using the Midpoint Rule; State the Fundamental Theorem of Calculus and use it to calculate definite integrals; State and apply basic properties of the definite integral; Use substitution to compute definite integrals. (Mathematics 101; See also: Biology 103, Chemistry 003, Computer Science 103, Economics 103, Mechanical Engineering 001)

This course presents software engineering concepts and principles in parallel with the software development life cycle. Topics addressed include the Software Development Life Cycle (SDLC), software modeling using Unified Modeling Language (UML), major phases of SDLC (Software Requirements and Analysis, Software Design, and Software Testing), and project management. Upon successful completion of this course, the student will be able to: demonstrate mastery of software engineering knowledge and skills, and professional issues necessary to practice software engineering; discuss principles of software engineering; describe software development life cycle models; learn principles of software modeling through UML as a modeling language; identify major activities and key deliverables in a software development life cycle during software requirements and analysis, software design, and software testing; apply the object-oriented methodology in software engineering to create UML artifacts for software analysis and requirements, software design, and software testing; apply project management concepts in a software engineering environment to manage project, people, and product; participate as an individual and as part of a team to deliver quality software systems. This free course may be completed online at any time. (Computer Science 302)

For middle school and up, a short course that explains acoustics (the physics of sound waves) as it relates to music and musical instruments. Suggestions for presenting some of the concepts to younger students are included.

"I'd like to suggest the educational technology resource: SpinnerWheel.com

Spinner Wheel is a free online tool that allows for a flexible and engaging approach to learning. It has many use-cases for any subject.

All entries on wheels are fully editable and one of the main things that makes it so useful is the ability to create multiple wheels for use at one time.

An example use of Spinner Wheel for mathematics: https://spinnerwheel.com/mental-mathematics-quiz
and for creative writing: https://spinnerwheel.com/short-burst-writing-ideas-generator

From creating multiple random number generators to equitably selecting students from a group, the possibilities for using this resource in a learning environment are practically endless."

This template is to be used by participants attending the TENFEE (Teacher Educators Network for Environmental Education) professional learning summit. Sign into WISELearn to create your own copy of this resource and update the template and this abstract.

This course considers reggae, or Jamaican popular music more generally--in its various forms (ska, rocksteady, roots, dancehall)--as constituted by international movements and exchanges and as a product that circulates globally in complex ways. By reading across the reggae literature, as well as considering reggae texts themselves (songs, films, videos, and images), students will scrutinize the different interpretations of reggae's significance and the implications of different interpretations of the story of Jamaica and its music. Beginning with a consideration of how Jamaica's popular music industry emerged out of transnational exchanges, the course will proceed to focus on reggae's circulation outside of Jamaica via diasporic networks and commercial mediascapes. Among other sites, we will consider reggae's resonance and impact elsewhere in the Anglo Caribbean (e.g., Trinidad, Barbados), the United Kingdom (including British reggae styles but also such progeny as jungle, grime, and dubstep), the United States (both as reggae per se and in hip-hop), Panama and Puerto Rico and other Latin American locales (e.g., Brazil), Japan and Australia, as well as West, South, and East Africa (CĺŞte d'Ivoire, Tanzania, Uganda).

In this problem-based learning activity, students experiment with a battery and light bulbs to build your own flashlights. The purpose of the activity is to develop understanding of fundamental electrical circuit concepts, including voltage, current, and closed circuits, and to help eliminate common misconceptions. This module provides instructor information for the activity.

Introducing and modeling use of inquiry-based learning strategies and the Wisconsin Standards for Environmental Literacy and Sustainability, this plan takes place over the course of three 110-minute class meetings.

This site provides online simulations, learning modules, and interactive tools for learning about nanotechnology -- the design and production of structures, devices, and systems one atom or one molecule at a time. Analyze the electronic properties of different nano materials and the optical properties of nanoparticles. Explore molecular conduction, nanofluids, and nanowires. Create simulations of nanoelectronic and nanoelectromechanical systems. Registration required.

This course, as the name suggest, is intended to help authors who want to publish mathematical content on web. The emphasis here is to enable learners to quickly adapt to the extensive mathML markup language and begin writing codes even without a specialized editor, available commercially. The course is presented in the form of a tutorial, which essentially saves on unnecessary details. This tutorial is not intended currently (may be supplemented later with the help coming from others) to be a comprehensive treatment on mathML. The presentation here is restricted to areas which form the basic part of the electronic publication of mathematical content.