Group items tagged

"Need more convincing that Minecraft can be a powerful tool for learning? Check out this fun video from PBS Idea Channel's Mike Rugnetta, who specifically (and very quickly) lists a number of ways the video game can and has been used to learn everything from physics to history."

"In a digital world of links, likes, tweets and pins, there are very few mechanisms for connecting our ever expanding digital world with the physical one around us. QR codes are one of the simplest and most well established ways to make this connection, and for students it can create a number of unique and fun learning opportunities, meshing the digital and physical classroom. In the below presentation, cutting edge educator Denise Webster shares the tools she uses, as well as some real world examples for making the most of QR codes in the classroom."

Introduction to Physical Computing Tinkering with Light, Sound, and Motion A guide for explorations and sharing possibilities for Young Makers mentors

"Manipulatives are objects that allow learners to interact with mathematical concepts. The learner changes the manipulative in some way, and the manipulative provides informative feedback. Research suggests that using maniuplatives (physical or virtual) has a positive effect on student achievement.  Check out how ST Math educators incorporate physical manipulatives with education technology to provide different ways to explore math concepts and facilitate deeper learning:"

These project-based lessons focus on basic principles of physics, structural, and mechanical engineering. Physical models are built from a similar set of materials that can be easily sourced online (links are provided in-lesson). All of the project plans in this collection are designed to be used in an after school enrichment setting, though you may use and modify these ideas for other not-for-profit purposes provided you cite The Workshop for Young Engineers. This is a growing and improving collection of lesson plans. Please comment to share your ideas to improve lessons and photos of your designs.

"Because this book's main focus is on the day-to-day classroom applications of brain-based research, I will not attempt to provide you with a thorough description of the physical brain and all its functions. However, it is beneficial for teachers to have at least a general awareness of how the brain physically functions. This knowledge can help teachers understand their students' needs or reactions and may provide a physiological basis for certain instructional decisions. So, let's take a quick walk through the brain."

"You see it everywhere in K-12. Kindergarteners design toys for their friends to practice empathy, while learning to use a saw and glue-gun along the way. Second graders deepen their understanding of character traits while designing and sewing puppets to represent a character in a folk-tale. In high school physics, students make wind turbines in order to internalize an understanding of how magnetism can create electricity. The "it" I'm referring to is "Making," and simply put, Making is any activity where people create something, often with their hands. I often define Making by looking at what people bring to the Maker Faire, which does include more technical aspects like 3D printing, physical computing and programming. But Making also includes woodworking, growing food, making art and crafts."

"Short Circuit is an after-school experience with a fresh approach to electronics and physical computing for young people. The Short Circuit Curriculum Guide includes seven informal learning activity modules that encourage students to express their creativity and develop DIY digital media skills by exploring innovative uses for physical and digital materials, like circuits, conductive inks, LEDs and the latest programming languages. Short Circuit Curriculum Guide modules include lesson plans and individualized assessment tools based on programs piloted at Quest to Learn, as well as by the Digital Youth Network and YouMedia programs in Chicago."

is recently supposed an important issue in our daily affairs. Physical education should be started from childhood education period. Body movement and gaming is the child's familliar works. He feels a huge amusement by gaming and running freedomly. He engages in gaming when he gets a few free moments.

"Imagine spending every day in a physical space designed for people much bigger than you. To wash your hands or get a drink of water, you'd have to drag a chair over to the sink or ask a friend for a boost. Your feet would dangle in mid-air when you sat down and you'd have to crane your neck and stand on tiptoe to read the bulletin board. After the novelty wore off, it's likely that you'd end up feeling uncomfortable, insignificant, and out of place. Unfortunately, this is how many children feel every day in their classrooms. Whether it's because the chairs are too big or too small, the aisles too narrow, the tables too low, or the displays too high, the message is clear: "This room was not made for you." The sad fact is that most classroom spaces are far from ideal. Perhaps they were originally designed and built with little or no consultation with the teachers who would be working in them. Or maybe they were designed for another purpose, or with tight budgetary restrictions. And while teachers probably won't be able to transform an inadequate classroom space into an ideal one, they can make dramatic improvements. So, where to begin? The most obvious place is by thinking about the students. Before moving a single piece of furniture or clearing a wall for a display, learn as much as you can about the particular needs of the children you'll be teaching by talking with families and former teachers. Below are some general guidelines to help you create a physical environment that makes children feel comfortable and significant and that best serves their needs."

Learn Physics using java applets. Sections Mechanics, Light & Wave, Electromagnetism and Electronics. Also has Chinese version

"Caring about and maintaining our mental health is as important as our physical health. We only have one brain and one body, so it's our job to keep it running in the best way we can by paying attention to and working to improve our mental and physical health. We seem to know more about our bodies than we do our minds. This website is designed to share information about mental health and provide you with resources that can help you understand your mental health and assist those you care about. Use the tools, resources, events and engagement tools to improve mental health literacy in your community and help change the conversation."

"We're becoming a sedentary bunch. Even with increased flexible working practices, too many of us spend too long sitting at a desk working. Few of us seem to have physical work these days and while repetitious or hard physical work can create problems of its own, our lack of regular activity can lead to long-term health issues. So, while this infographic, from OfficeVibe, veers towards the alarmist - a few exercises at your desk may just possibly save your life, but is more likely to simply make you feel better and more energised - but it will help you make the most of your time sat at a desk and mean that you'll feel less hunched up and atrophied. Much of the same effect could be had by having a stand-up desk, but not everyone can afford or get one of these. "

"Yesterday I mentioned a useful tip for using physical keyboards with iPads in my guide to unlocking the full potential of the iPad Pro. The tip actually works with all iOS 9 iPads connected to external keyboards over Bluetooth, Lightning, or the Smart Connector: hold Command (⌘) to see a list of supported keyboard shortcuts for the Home screen or app you're in. This works in most of Apple's built-in apps and plenty of popular third-party apps as well, but it can be monotonous prompting that sheet in each app to get a sense of what keyboard shortcuts work. Instead, I've compiled a cheat sheet of which keyboard shortcuts work in all the system apps and several popular third-party apps. Whether you're using Apple's Smart Keyboard for the iPad Pro, Magic Keyboard, Logitech's excellent K811, or any other physical keyboard, these will make you more efficient when working on your iPad."

"This is a collection of project-based engineering lessons for kids. Project-based learning allows students to control the direction and pace of their learning. Activities that promote investigation, critical thinking, and hands-on subject matter are also central to project-based learning. These project-based lessons focus on basic principles of physics, structural, and mechanical engineering. Physical models are built from a similar set of materials that can be easily sourced online (links are provided in-lesson). All of the project plans in this collection are designed to be used in an after school enrichment setting, though you may use and modify these ideas for other not-for-profit purposes provided you cite The Workshop for Young Engineers. This is a growing and improving collection of lesson plans. Please comment to share your ideas to improve lessons and photos of your designs."

"It's often easy to get stuck into a narrow view of what a particular field of study entails, but as Dominic Walliman reveals in his impressive science infographics, there's much more than meets the eye when thinking of particular STEM subjects. Walliman demonstrates the diversity and complexity of biology, chemistry, computer science, physics, and mathematics in visual maps that explore the breadth of each field. Walliman, who also created animated videos exploring his science infographics, manages to pack all the shades of each complex field on one page. For instance, the Map of Mathematics travels from the origins and foundations of the field to the differences between pure mathematics and applied mathematics. Likewise, chemistry is divided between rules and different sub-topics like biochemistry and inorganic chemistry, with fun illustrations to clearly show what falls underneath each area. Whether you are a scientist who feels like people never quite get what you do or a student who can't put their finger on how they might use their math or science degree, Walliman's infographics will come in handy. Consider them roadmaps to possible careers or cheat sheets to figuring out how quantum physics is related to the theory of relativity. Best of all, by studying the visual maps, it becomes easy to see how all these scientific fields overlap and fit together like a puzzle."

"Evaluating a student's understanding of a topic is like taking a measurement. However, it requires measuring something that is difficult to see. It's not like I can stick a ruler into a student's brain to determine the size of their physics stuff. Now, most teachers use indirect means, usually a multiple-choice test or an exam in which students work through a problem. These are poor measures of student understanding. Someone could simply guess, or flub the answer through a silly mistake. So how can I accurately assess a student's understanding of physics? Until someone invents a way of reading a student's mind, I must do something else. I use a combination of written tests and video assessments."

"The groundwork for machine learning was laid down in the middle of last century. But increasingly powerful computers - harnessed to algorithms refined over the past decade - are driving an explosion of applications in everything from medical physics to materials, as Marric Stephens discovers When your bank calls to ask about a suspiciously large purchase made on your credit card at a strange time, it's unlikely that a kindly member of staff has personally been combing through your account. Instead, it's more likely that a machine has learned what sort of behaviours to associate with criminal activity - and that it's spotted something unexpected on your statement. Silently and efficiently, the bank's computer has been using algorithms to watch over your account for signs of theft. Monitoring credit cards in this way is an example of "machine learning" - the process by which a computer system, trained on a given set of examples, develops the ability to perform a task flexibly and autonomously. As a subset of the more general field of artificial intelligence (AI), machine-learning techniques can be applied wherever there are large and complex data sets that can be mined for associations between inputs and outputs. In the case of your bank, the algorithm will have analysed a vast pool of both legitimate and illegitimate transactions to produce an output ("suspected fraud") from a given input ("high-value order placed at 3 a.m."). But machine learning isn't just used in finance. It's being applied in many other fields too, from healthcare and transport to the criminal-justice system. Indeed, Ge Wang - a biomedical engineer from the Rensselaer Polytechnic Institute in the US who is one of those pioneering its use in medical imaging - believes that when it comes to machine learning, we're on the cusp of a revolution."

"Circuit Playground meets Scratch-Physical Computing for Kindergartners"