This activity describes the construction and use of a pneumatic cannon and free falling target used to teach the concepts of projectile motion in introductory physics.

This project is intended as a long-term (3 weeks -- 1 month) lab exercise near the end of a combined Stratigraphy/Sedimentology course. The project utilizes real world data provided by CONSOL Energy of Pittsburgh, PA, and the West Virginia Geological and Economic Survey. This project has been assigned once and is being revised. Instructions have been left somewhat vague in an attempt to force students into discovering some of the more mechanical details of this process themselves.

By the latter third of the course, students have described sedimentary rocks in detail and have constructed vertical sections of rock at several outcrops around campus. The course is moving from Sedimentology/Petrology into Stratigraphy. This project is designed to illustrate the basic principles of lithostratigraphy, which are covered concurrently in the lecture portion of the class.

The project 'unfurls' over several weeks. If students are provided with the entire project at one time they generally get overwhelmed, so the project is presented piecemeal, allowing the students to expand the project as they complete one section.

Step 1: Core description 40 feet of core from the Conemaugh Group of southwestern Pennsylvania is made available to the students. They must describe the core, define lithologic units, identify specific sedimentary structures, and construct a stratigraphic column. (Students struggle with detail versus efficiency of completion, given one full lab period (3 hours) and a week to complete the assignment, many students will get lost in the detail)

The goal is to build familiarity with the type of data available to geologists as they go about constructing maps for resource estimates. Additionally, the lithologies present in this core will be similar to those described in the geologist and drilling logs necessary to complete the next step.

Each step is evaluated independently in this step concern is primarily with identification of basic lithologies (coal, sandstone, shale, limestone).

Step 2: construction of strip logs for 25 core holes in northern West Virginia. Students are provided with a location map, logs for 25 holes, and elevation data. They must construct strip logs suitable for correlation, deciding upon scale and detail of presentation. Students are provided with a CD including the location map and a .pdf for each drill record.

The logs vary between the simplicity of driller data (60' of "blue" shale) and the detail of geologist descriptions, students must balance the detail and simplicity. Additionally, students were faced with "long" logs (i.e. greater than 500') and "short" logs (i.e. less than 100'). This turned out to be extremely difficult, some students got very lost, producing long detailed logs that left them without much time for the last two steps.

Students are again provided with a week to construct the strip logs, including the lab time for the week. Strip logs are evaluated for detail, accuracy, and utility (in many cases too much detail can be as confusing as too little).

Step 3: construction of stratigraphic cross sections. The first time this project was assigned, there was little guidance provided to students beyond "choosing logs that covered the largest stratigraphic interval." This exceeded the grasp of most students so additional guidance will be provided in the next iteration of this project. A generalized stratigraphic column illustrating the basic characteristics of the Monongahela and Conemaugh groups will be provided to assist students with recognition of the basic formations.

Students will be required to construct a stratigraphic cross section through selected wells on the west side of the project area. This cross section will demonstrate the use of marker beds and the lateral continuity of stratigraphic units.

The second cross section will run east-west onto the western flank of the Chestnut Ridge anticline. The datum for this cross section will be surface elevation. This cross section will illustrate the problems of stratigraphic correlation when combined with geological structures. The rock becomes consistently older as one proceeds towards the axis of the anticline. The prominent red beds and the absence of coals, in the eastern portion of the map area indicate the presence of the Chestnut Ridge Anticline.

Evaluation of the cross sections will be based upon the accuracy of the correlations. Students are allowed a week to produce cross sections (including lab). The stratigraphic cross section should accurately delineate the Redstone, Pittsburgh, and Sewickley coals. These occur in sequence and are fairly easy to identify. Successful completion of the east-west cross section will require identification of the approximate stratigraphic position of the Monongahela-Conemaugh contact.

Step 4: construction of isopach maps. Students are then required to identify specific coal and sandstone units within their cross sections, correlate those across the map region and construct isopach maps of those units.

This requires that the students now extend what they have learned from the previous three weeks, extend those correlations to the core holes not included in the basic stratigraphic analysis. The thickness of the coal and sandstone should be identified and isopach maps constructed.

The first iteration of this project produced problems similar to those encountered in step 3. Better guidance and evaluation of the cross sections and allowing students less input on the choice of stratigraphic units to isopach should reduce the confusion.

Step 5: (optional) Interpretation and report writing : the first iteration of this project was running concurrently with a term paper. Instead of two separate projects, an interpretive report will be required. This is still in the planning stage and has not been assigned to students.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

This Course Review and Approval Tool (CRAT) is the “workbook” that faculty use to design and plan their course with best practice in mind that addresses: curricular alignment with objectives, learning activities, practice assignments and quizzes, and higher-stakes assessments. The 10-tabbed spreadsheet is a digital multitool that centralizes and aggregates the entire course development, review, and approval processes. This tool is used to plan the course prior to its build in the Learning Management System (LMS) as part of an eight-module LMS-based support course that steps faculty through the process and gives them a learner-based perspective on how the tools work together and the features available to them for use in their own courses.

In addition to facilitating communication with multiple stakeholders who may share the document, the process MODELS a self- and peer-reviewed authentic assessment strategy that adapts itself well to any curriculum, whether for training, orientation, or credit-bearing coursework. It supports and models features of an intersection of agile design, backward design, and reflective practice in addition to encouraging authentic and formative assessment strategies. Providing all necessary documents in one easily accessed and bookmarkable document facilitates the process of course development by providing both a model and a touchstone for faculty who are often overwhelmed with the complexity of the process of developing or redeveloping courses regardless of delivery modality. While most of our faculty came to the program because of requirements for online or hybrid learning, most have exclaimed happily that they now apply this process to all of their courses and their learners have shown appreciation for the clarity and consistency that the tool promotes and supports.

The document also includes a dynamic link to future updates for anyone who adopts it and wants to follow its evolution. Feel free to adapt!

Cracker Barn. This is the Lesson 1 Exposure Activity, from Unit 2 Power, Structure and Technology, from the DIGS (Developing Individuals, Growing Stewards) AmeriCorps Curriculum from CSU. The curriculum focuses on introducing students in grades 3-5 to Colorado agriculture, industry and environmental issues. The curriculum is matched to State Standards 2021. The curriculum upon request. Visit: https://engagement.colostate.edu/programs-old/developing-individuals-growing-stewards/

Reading and creating comic strips and comic books are engaging ways to promote literacy at any grade level and across content areas. The students in this video are members of a high school comic book club and have access to drawing tablets and Adobe Photoshop, so they can achieve sophisticated results. Even without such software, however, teachers can still integrate digital comics into a wide range of teaching situations.

There are a number of comic books, especially contemporary ones, that are not “school appropriate,” so you might want to guide students’ web research on comic books.

This Open Educational Resource (OER) web-book aims to empower English teachers from across the globe to design their own, authentic, corpus-based lessons by showcasing a range of ideas for creating corpus-informed teaching materials using online resources.

Pre-service trainee teachers from Osnabrück University (Germany) contributed the chapters as part of three English Pedagogy Masters of Education seminars taught by Elen Le Foll.

The introductory chapter “About the project” outlines the rationale and development of the project and discusses how various challenges were overcome. The remaining Lesson Ideas chapters are organised according to the school type for which they were developed.

Part I is dedicated to corpus-informed lesson ideas for primary schools.
Part II showcases corpus-informed lesson ideas for secondary schools.
Part III explores the use of corpora in Content and Language Integrated Learning (CLIL) and bilingual secondary education.
Part IV presents corpus-informed lesson ideas for English for Specific Purposes (ESP) and vocational education.

For teachers and teacher trainees entirely new to corpora, we recommend selecting one or two chapters of interest and following the step-by-step instructions in order to recreate the corpus-informed materials proposed by the chapter authors. As you work your way through these, you will find that the various ideas and methods outlined in all the chapters can easily be transferred to an infinite range of different language foci, topics, and educational contexts.

In addition, most of the chapters include worksheets that can be downloaded as individual PDFs in just one click. Thus, this book also provides a low-threshold introduction to working with corpus-informed materials for teachers with no previous knowledge of corpora. It is hoped that the experience of using these “oven-ready” corpus-informed materials, which require little to no preparation time, will encourage teachers to subsequently invest time in working through a selection of the book’s chapters in order to, in due course, be able to pick their own ingredients and create entirely new and delicious corpus-informed dishes!

Each chapter, or recipe, has a different focus which may be lexical, grammatical, or phraseological, and focuses on a different set of language and/or interdisciplinary skills. The chapters are all similarly structured. The chapter contributors begin by describing their lesson’s learning objectives and outlining the rationale for their choice of topic, corpus, and corpus tool. They then guide the reader through all the necessary steps to create their proposed corpus-informed materials with clear, tutorial-like and illustrated step-by-step instructions. In many instances, the authors also provide instructions for their lesson tasks, as well as (possible) solutions. At the end of each chapter, you will also find additional options and ideas to expand or adapt the proposed lesson to the taste buds of your students.

This survey instrument is designed to understand how creators use (or decide not to use) Creative Commons licenses. The target survey participants are people who create materials for documentation, maintenance, instruction, learning, and/or revitalization of Indigenous, minority, endangered, and/or low-resourced languages. Part 1 of this survey is designed to learn about the digital creation formats and sharing practices in this specific community of practice. Parts 2 through 4 of this survey contain general questions intended to elicit information about research participants’ knowledge and awareness of Creative Commons (CC) licenses; understanding of how to apply CC licenses to their digital creations; interest in and experience with applying CC licenses to their digital creations; motivations for and barriers to applying CC licenses to their digital creations; and understanding of how to adapt or reuse digital creations licensed with CC licenses.

This survey can be easily adapted for use in other communities of practice by editing some of the questions and multiple-choice responses.

If you wish to read this survey and background information about it, please start with the file ReadMe-CCLuseSurvey.pdf.

The file Creative_Commons_License_Use_Survey.qsf is a Qualtrics Survey File that can be used to recreate this survey in your own instance of the Qualtrics software.

The file Creative_Commons_License_Use_Survey.pdf is a PDF of the survey. This version includes Creative Commons graphics that are used in the survey questions. The file ReadMe-CCLuseSurvey.pdf does not include the graphics.

Curriculum Instruction and Assessment for CTE Syllabus

ED 429

Course Description
Build knowledge and skills in curriculum design, instructional strategies, and assessment for successful teaching in a Career and Technical Education and other specialty areas: (a) Agriculture Food and Natural Resource Systems, (b) Arts, Information and Communications, (c) Business Management, (d) Health Sciences (e) Human Resources, (F) Industrial and Engineering Systems, (g) Family and Consumer Sciences, (h) Career Trades.

Learn how instructional designers use data to inform the creation of a Learning Persona. Learning Personas help determine the needs of the training and help ...

This unit discusses the purposes of databases, a relational database, and the querying language SQL. Students will design a simple database using data modeling and normalization. This unit will define basic data operations, provide instruction on how to create common query statements, and discuss SQL implementation.

A Day Without Agriculture. This is the Lesson 1 Exposure Activity, from Unit 1 Introduction to Agriculture, from the DIGS (Developing Individuals, Growing Stewards) AmeriCorps Curriculum from CSU. The curriculum focuses on introducing students in grades 3-5 to Colorado agriculture, industry and environmental issues. The curriculum is matched to State Standards 2021. The curriculum upon request. Visit: https://engagement.colostate.edu/programs-old/developing-individuals-growing-stewards/

The purpose of this investigation is to understand how the amount of water vapor in the air at various temperatures affects the way the human body responds. This is an important basic concept for understanding why one might feel either comfortable or uncomfortable at exactly the same temperature. This challenge draws on understanding the student has acquired by conducting experiments outlined in chapters 3-11 of Meteorology: An Educator's Resource for Inquiry-Based Learning for Grades 5-9. The resource includes background information, teaching tips and questions to guide student discussion. This is chapter 14 of Meteorology: An Educator's Resource for Inquiry-Based Learning for Grades 5-9. The guide includes a discussion of learning science, the use of inquiry in the classroom, instructions for making simple weather instruments, and more than 20 weather investigations ranging from teacher-centered to guided and open inquiry investigations.

In this Instructable I will go through my process of designing and building these little scissor mechanism toys in Fusion 360.

Students begin by following instructions to connect a Sunfounder Ultrasonic Sensor and an Arduino Microcontroller. Once they have them set up, students calibrate the sensor and practice using it. Students are then given an engineering design problem: to build a product that will use the ultrasonic sensors for a purpose that they all specify. Students will have to work together to design and test their product, and ultimately present it to their classmates.

The focus of many open education projects is to provide access to education. But what does access mean? If the materials are not accessible for each and every student, do they fulfill the mandate to deliver fully open education? The open education movement has helped people in different parts of the world access content that they would otherwise not be able to view or interact with. Open education resources reduce costs for students and allow for greater flexibility for instructors. Accessibility can help push the movement even further forward.

The goal of the OER Accessibility Toolkit is to provide the needed resources needed to each content creator, instructor, instructional designer, educational technologist, librarian, administrator, and teaching assistant to create a truly open and accessible educational resource — one that is accessible for all students.

This experimental activity is designed to develop an understanding that air has mass. Students conduct an investigation and observe the change in the position of a bar balancing a balloon inflated with air on one end and a uninflated balloon on the other end. Resources needed include a piece of wood, two rubber balloons, two large paper clips, ruler, nail, hammer and tape. The resource includes background information, teaching tips and questions to guide student discussion. This is chapter 7 of Meteorology: An Educator's Resource for Inquiry-Based Learning for Grades 5-9. The guide includes a discussion of learning science, the use of inquiry in the classroom, instructions for making simple weather instruments, and more than 20 weather investigations ranging from teacher-centered to guided and open inquiry investigations.

This exercise is typically integrated with lecture during the first two days of a chapter on fluvial geomorphology.

Day 1:
The first day of class begins with a discussion of the components of a drainage basin and typical drainage basin patterns, including dendritic, parallel, trellis, rectangular, radial, annular, and multibasinal. After viewing the typical textbook diagrams of these drainage basin patterns, each student is given his/her own topographic map and a geologic map from the same region. The students are given the following instructions:

1.Write a one paragraph description of your study area, and include the following information:

Quad. name
Drainage basin pattern(s) -- in bold
Geological influence

2.Email the paragraph to me as an MS Word document by 9:00AM on [date -- next day]. I will read the paragraph, but I will not modify any wording, so make sure it is accurate and well-written.

The maps are usually distributed in the last 10 minutes of a 50-minute class period, so that the students have some time to get familiar with the maps and ask any questions that arise immediately. Recommended 7.5 minute quad.s for the exercise include:

dendritic: Effingham, IL; Alma, WI-MN
parallel: Ithaca West, NY; Antelope Peak, AZ
trellis: Waldron, AR
rectangular: Hillsboro, KY; Cumberland MD-PA-WV
radial: Mt. Rainer, WA
annular: Maverick Spring, WY
multibasinal: Whitwell, TN; Oolitic, IN

The Website http://rockyweb.cr.usgs.gov/outreach/featureindex.html is also a useful reference for other topographic maps.

Day 2:
On the second day of class, we discuss the initiation of channels and basin morphometry. After lecturing on topics like tractive force, micropiracy, cross-grading, and bifurcation, we discuss typical stream courses (i.e., insequent, consequent, subsequent, obsequent, and resequent). In the last 5 minutes of class, the paragraphs from the previous day are redistributed in such a way that every student has a paragraph written by one of their peers and a new set of maps. The students are given the following instructions:

1.Rewrite/edit what you have been given, if necessary, to emphasize the bolded drainage pattern.
2.Decide whether the stream patterns are representative of consequent, insequent, or subsequent stream courses.
3.Explain your reasoning using the geologic map.

Discuss the influence of the resistance of geologic materials on the stream course.
Discuss the influence of slope on the development of the stream course.

4.Email the paragraph to me as an MS Word document by 9:00AM on [date -- next day].

Once final paragraphs are submitted, they are redistributed to the entire class so that all students have a complete set of paragraphs describing a variety of drainage basin patterns and stream courses from a variety of geologic settings. Maps remain in the classroom for the duration of the term so that students can reference them if they choose to.
Designed for a geomorphology course
Has minimal/no quantitative component

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

The Drawing Board consists of a marking pen that remains stationary and a platform that swings beneath the pen, acting as a pendulum. As the platform swings, the pen marks a sheet of paper that is fastened to the platform, generating beautiful repetitive patterns. These colorful designs contain hidden lessons in physics. This resource includes instructions for making a large-scale Drawing Board as well.

Instructional materials for the course "ENTC 2160: Architectural CAD" include videos demonstrating how to create CAD drawings and use CAD tools. Videos cover the following topics: exterior walls, interior walls, doors, windows, dimensioning, linetypes, electrical, slab, stairs, hatching, fireplaces, and roofing.

EQuIP (Educators Evaluating the Quality of Instructional Products) is an initiative designed to identify high-quality materials aligned to the Common Core State Standards (CCSS) or Next Generation Science Standards (NGSS). This site includes the EQuIP rubric for lessons and units as well as the EQuIP task review rubric and training materials.