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"When Sonja Khan started college, she'd never thought of studying computer science. But when she heard from friends that the intro class was good, she decided to give it a try - and then ended up majoring in it. Four years later, she has just graduated with a computer science degree, is pursuing a master's degree and is headed to a summer internship at Facebook. "I didn't even know anything about the field before; I had never considered it," she said. "I signed up for it pretty much on a whim and really enjoyed it." Ms. Khan's story reads like a dream for universities and technology companies - where only about 15 percent of computer science graduates and technical workers are women. The industry has been under pressure to recruit more. The difficult question, though, is how to encourage more women on paths like Ms. Khan's"

"When educator Lynn Koresh hears from kids that they want a career doing something with computers, she asks, "To do what with computers?" Adults often encourage kids to pursue science, technology, engineering and math (STEM) skills, and computing classes are usually a first stop. But Koresh knows it's the real-world applications of computational thinking and coding language skills that bring such knowledge to life. She reasoned that most middle school students are already playing video games and might respond well to a unit on how to design, create, test and promote video games. Along the way, she's also teaching them about digital citizenship and entrepreneurship. "I wanted to give kids exposure to what it means to have a career using computers," said Koresh, technology coordinator at Edgewood Campus School in Madison, Wisconsin."

"Computational thinking has received considerable attention over the past several years, but there are many perspectives on what computational thinking entails. We are interested in the ways that design-based learning activities - in particular, programming interactive media - support the development of computational thinking in young people. This site and its collection of instruments are designed for K-12 educators and researchers interested in supporting and assessing the development of computational thinking through programming. "

"Did you know that this week (December 8-14) is Computer Science Education Week? There are resources available via the previous link to help encourage kids to learn to code, to bring computer science education to your school or district, and more. While the concept is mainly aimed at encouraging schools to teach more computer science and more kids to (want to) learn computer science, it can address a much, much wider audience. 'Computer Science' can sound like a big scary unknown thing if you're someone who has never done any type of programming before, but it doesn't have to be."

"t's been two and a half years since Code.org hired our first salaried employee. We've been humbled to watch the landscape change in K-12 computer science (CS) over that time. This teacher-powered movement has reached hundreds of thousands of classrooms and millions of students. We've never been more confident in our ability to realize our vision - that every student in every school should have the opportunity to learn computer science. Although only 25% of U.S. schools teach computer science and computer programming, the field is growing at a rapid pace. Enrollment in computer science is exploding. Over 10% of all U.S. students in grades K-8 registered accounts to begin coding in just the last 2 years. CS is the fastest-growing AP course of this decade. For the first time, the diversity of participating students is improving, with enrollment growth by women and students of color outpacing enrollment growth by White and Asian males."

"In this article, we use evidence to describe seven key lessons from a four-year district-wide computer science implementation project between Howard University and the District of Columbia Public Schools. These lessons are: (a) Get to know the school counselors (and other key personnel); (b) Expect personnel changes and strategic reorganization within school districts; (c) Be innovative to build and maintain community; (d) Be flexible when developing instruments and curricula; (e) Maintain a firm commitment to equity; (f) Develop tiered content and prepare to make philosophical adjustments; and (g) Identify markers of sustainability. We also include original curricula materials including the Computer Science Course Evaluation and the Computational Thinking Survey. The seven lessons and curricula materials provided in this study can be used to inform the development of future computer science researcher-practitioner partnerships."

"This lesson/series of lessons is designed to give pupils an introductory understanding of key computational thinking skills and help them to discover that in fact, computers don't solve problems, but are used by us to aid the problem solving process. This will be shown by using the BBC Micro:Bit device, both emulated via online tools and with a real Micro:Bit if available - and adding a touch of magic."

Coding is the enemy of computational thinking," Stephen Wolfram announced during his keynote at the Building Learning Communities® Education Conference. What was remarkable about this comment were the agreeable nods from the crowd. It seemed there was a collective understanding to this notion, and perhaps one that needed further reflection. This year, the conference had several sessions focusing on computational thinking (which, I might add, is incredibly encouraging to see), and in each one I attended, a special note was added: "Coding and computational thinking are not synonymous."

The Bebras cards are designed to enable pupils to develop their computational thinking skills, whilst at the same time providing an introduction to more advanced computing concepts. Computational Thinking Each card is aligned to one of the following computational thinking concepts, which are indicated in the top right-hand corner of each card.  Patterns  Algorithms  Logic  Abstraction Task Difficulty The difficulty of the task on each card is indicated by the icon in the bottom right-hand corner.  = Easy  = Medium  = Hard Answers and Other Materials Answers to tasks, ideas for teaching and national curriculum links can be found at: www.bebras.uk Tip: pupils will need an exercise book or a piece of paper in order to record their answers to each activity

"With Computer Science in Education (CSED) Week and Hour of Code right around the corner, we have a simple request: Don't teach coding. Instead, we suggest that you introduce computational thinking and creative problem solving into your classroom. This way, you can get at the big ideas behind computer science rather than focus on a single activity or lesson involving "code.""

The Bebras cards are designed to enable pupils to develop their computational thinking skills, whilst at the same time providing an introduction to more advanced computing concepts. Computational Thinking Each card is aligned to one of the following computational thinking concepts, which are indicated in the top right-hand corner of each card.  Patterns  Algorithms  Logic  Abstraction Task Difficulty The difficulty of the task on each card is indicated by the icon in the bottom right-hand corner.  = Easy  = Medium  = Hard Answers and Other Materials Answers to tasks, ideas for teaching and national curriculum links can be found at: www.bebras.uk Tip: pupils will need an exercise book or a piece of paper in order to record their answers to each activity

"I participate as a parent in our middle school Tech Club - the TechDetectives. The 8th graders in the club came up with this great end of year project idea - they wanted to take apart one of the lab computers and re-mount all the parts on the wall so that future students could easily see all the parts of this working computer. It was something they saw done on YouTube. I've been calling it the "CoW" (Computer On the Wall). I loved this idea - and quickly volunteered to help out after school - knowing we didn't have enough time in tech club before the end of their graduating year to finish it. As I described in a few posts previously, this project also turned into a great opportunity for some #3DPrinting solutions."

"Increasing the gender diversity of the computer science faculty should be a priority for all schools as it would provide female students--as well as students of color--with role-models and mentors. In a study conducted in a suburban area near Oklahoma University, researchers examined the correlation between an after-school engineering mentoring program led by female college students and the perceptions of sixth and seventh grade girls (Holmes, Redmond, Thomas, & High, 2012). The researchers found that high quality mentoring relationships with a female role model led to an increase in the girls' confidence in their mathematics ability (Holmes et al., 2012). Similarly, seeing a confident and successful female computer science teacher could have a positive impact on girls and boys in computer science classes."

"Across the United States and around the world, educators are being called on to help their students prepare for futures in an increasingly computational world. Integrating computational thinking into activities, lessons, and curricula not only supports building new skills, but also enhances learning and engagement in every discipline. However, there are still many more educators who do not feel comfortable with computational thinking concepts than those who do."

"Our "Key Concepts of Computational Thinking" framework supports teachers in identifying where their students can leverage computational thinking to enhance their learning. Within these eight key concepts, teachers in every subject have found intersections with what their students are expected to know and know how to do."

"There is a lot of talk of "Computational Thinking" as a new imperative of education, so I wanted to address a few questions that keep coming up about it. What is it? Is it important? How does it relate to today's school subjects? Is Computer-Based Maths (CBM) a Computational Thinking curriculum? Firstly, I've got to say, I really like the term. To my mind, the overriding purpose of education is "to enrich life" (yours, your society's, not just in "riches" but in meaning) and different ways in which you can think about how you look at ideas, challenges and opportunities seems crucial to achieving that. Therefore using a term of the form "xxx Thinking" that cuts across boundaries but can support traditional school subjects (eg. History, English, Maths) and emphasises an approach to thinking is important to improving education."

"Benefits of Coding At the heart of computational thinking - and mathematics - is abstraction. When children write code, they come to… understand in a tangible way the abstractions that lie at the heart of  mathematics, dynamically model mathematics concepts and relationships, gain confidence in their own ability and agency as mathematics learners. Computer coding is creating a buzz in education. Prime Minister Justin Trudeau recently said, "We need to do a lot better job of getting young people to understand what coding is and how it's important, how to program, how to problem solve, how to create the most elegant algorithm possible."1 BC recently announced that computer coding will be added to all grades of the K-12 curriculum, and Nova Scotia has made a similar announcement. The trend of adding some form of computer coding to curriculum is an international phenomenon; in 2014, England mandated a coding curriculum for all K-12 students."

"How do you ensure students who excel at math remain engaged? Heidi Williams intended to solve that challenge by starting an after-school coding club while she was a gifted-and-talented teacher at Bayside Middle School near Milwaukee. Instead of using pen and paper, her students created an interactive children's book on Scratch, the MIT Media Lab coding suite that lets users create games, stories and simulations. And the more of this kind of coding activity they did, the better their math test scores got. Now a computer science curriculum specialist at Marquette University in Milwaukee, Williams researches this correlation. One possibility is that the computational thinking skills developed while coding help students break down complicated problems-on and off computers, she says."

"Released in 2013, the NGSS was created to align science education with how scientists actually work and think. It encourages students to learn science content and concepts deeply by using critical thinking and primary investigation skills. Adopted by 18 states (with as many as 40 interested and in the process), the standards define science education through core concepts (such as wave properties), practices (like analyzing and interpreting data ) and crosscutting concepts (like cause-and-effect). Some of the NGSS guidelines directly overlap with the practices listed in the K-12 Computer Science framework and the new CSTA Computer Science standards. Here's a doodle that illustrates how the two subjects overlap. "

"Stories are an entertaining way to introduce or reinforce computer science concepts and help students to understand abstract concepts in a more concrete way. Do you read picture books, chapter books, or short stories to your students in computer science classes? I do. The easiest way to get started is with books that are specifically written to teach CS concepts."