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"Please, No More Professional Development! By Peter DeWitt on April 17, 2015 8:10 AM Today's guest blog is written by Kristine Fox (Ed.D), Senior Field Specialist/Research Associate at Quaglia Institute for Student Aspirations (QISA). She is a former teacher and administrator who has passion for teacher learning and student voice. Kris works directly with teachers and leaders across the country to help all learners reach their fullest potential. Peter DeWitt recently outlined why "faculty meetings are a waste of time." Furthering on his idea, most professional development opportunities don't offer optimal learning experiences and the rare teacher is sitting in her classroom thinking "I can't wait until my district's next PD day." When I inform a fellow educator that I am a PD provider, I can read her thoughts - boring, painful, waste of time, useless, irrelevant - one would think my job is equal to going to the dentist (sorry to my dentist friends). According to the Quaglia Institute and Teacher Voice and Aspirations International Center's National Teacher Voice Report only 54% percent of teachers agree "Meaningful staff development exists in my school." I can't imagine any other profession being satisfied with that number when it comes to employee learning and growth. What sense does it make for the science teacher to spend a day learning about upcoming English assessments? Or, for the veteran teacher to learn for the hundredth time how to use conceptual conflict as a hook. Why does education insist everyone attend the same type of training regardless of specialization, experience, or need? As a nod to the upcoming political campaigns and the inevitable introduction of plans with lots of points, here is my 5 Point Plan for revamping professional development. 5 Point Plan Point I - Change the Term: Semantics Matter We cannot reclaim the term Professional Development for teachers. It has a long, baggage-laden history of conformity that does not

"Regardless of whether you think every infant needs an iPad, I think we can all agree that technology has changed education for the better. Today's learners now enjoy easier, more efficient access to information; opportunities for extended and mobile learning; the ability to give and receive immediate feedback; and greater motivation to learn and engage. We now have programs and platforms that can transform learners into globally active citizens, opening up countless avenues for communication and impact. Thousands of educational apps have been designed to enhance interest and participation. Course management systems and learning analytics have streamlined the education process and allowed for quality online delivery. But if we had to pick the top ten, most influential ways technology has transformed education, what would the list look like? The following things have been identified by educational researchers and teachers alike as the most powerful uses of technology for learning. Take a look. 1. Critical Thinking In Meaningful Learning With Technology, David H. Jonassen and his co-authors argue that students do not learn from teachers or from technologies. Rather, students learn from thinking-thinking about what they are doing or what they did, thinking about what they believe, thinking about what others have done and believe, thinking about the thinking processes they use-just thinking and reasoning. Thinking mediates learning. Learning results from thinking. So what kinds of thinking are fostered when learning with technologies? Analogical If you distill cognitive psychology into a single principle, it would be to use analogies to convey and understand new ideas. That is, understanding a new idea is best accomplished by comparing and contrasting it to an idea that is already understood. In an analogy, the properties or attributes of one idea (the analogue) are mapped or transferred to another (the source or target). Single analogies are also known as sy

"Take a look at the definition of student-centered learning, and let me know what you think: Student-centered learning (SCL), or learner-centeredness, is a learning model that places the student (learner) in the center of the learning process. In student-centered learning, students are active participants in their learning; they learn at their own pace and use their own strategies; they are more intrinsically than extrinsically motivated; learning is more individualized than standardized. Student-centered learning develops learning-how-to-learn skills such as problem solving, critical thinking, and reflective thinking. Student-centered learning accounts for and adapts to different learning styles of students (National Center for Research on Teacher Learning, 1999)."

"I love the idea of making, inventing and tinkering. Just watch kids who are immersed in the activities and you can see the engagement. But is the learning authentic and relevant? I presented three sessions at the Free Maker Movement event at One Work Place on Wednesday, September 30, 2015 with some amazing educators who presented hands-on activities. The event will took place at our Oakland Center for Active Learning . I decided I needed to spend some time researching where the Maker Movement was happening and find examples of authentic learning. This gave me the opportunity to talk to several of my friends and share how they have transformed learning spaces to Makerspaces. Everyone I talked to made a point that it is about creativity not consumption. Yet when I went to different Maker events, I saw activities that an adult set up, purchased a kit or provided directions for activities. They were all fun, but I was having trouble seeing the connections to real learning or any ownership from kids."

"Tinkering activities provide a powerful way to inspire students' interest, engagement, and understanding in science. The Tinkering Fundamentals course will help educators and enthusiasts develop a practice of tinkering and making. This course will focus on key design elements of high-quality, science-rich tinkering activities, effective facilitation strategies and environmental organization. Watch Intro Video About the Course The Tinkering Fundamentals course will offer educators and enthusiasts an opportunity to develop a practice of tinkering and making.  We see tinkering as a serious endeavor -- one that is generalizable across content and especially good at interweaving disciplines in a way that leads to complex projects and individualized learning opportunities.   Tinkering has recently been introduced into the educational field as a potential driver of creativity, excitement, and innovation in science learning. It is seen by many as an effective means to engage in exploring STEM concepts, practices and phenomena. Tinkering typically blends the high and low tech tools of science along with a strong aesthetic dimension that supports children's (and adults) self expression.  For over a decade, the Exploratorium has been developing science-rich tinkering activities. Working with learning scientists, we have identified a set of design principles and indicators of learning that can help you to integrate tinkering activities into your elementary and middle school science programs. This course will focus on key design elements of high quality science-rich tinkering activities, facilitation strategies, and environmental organization. Selected  tinkering activities will be centered around circuits for this course.  We will review the ways in which tinkering supports science learning through providing opportunities to deepen engagement, intentionality, innovation, collaboration, and understanding. This course will excite you, inspire you, and get you tinkering in

"In today's world, many parents (myself included) are sending kids to after school classes, summer camps, … in the hope that kids will learn something that are missing from school. But one thing we forget while sending kids to these extra curriculum activities is there are a lot we can do right at home. Today we put together these cool STEM (science, technology, engineer, math) activities for kids that you can do in your kitchen. Kitchen science activities have always been our favorite. Now we start expand from Science to STEM. We try to pick the ideas that only use materials you already have or can be easily get from a grocery store nearby, and activities that can be done safely at home, so the whole family can explore and have fun together, no matter the age of kids. It is more important for kids to have the interest to learn than to have the knowledge itself, and the more the learning being an integral part of life, the more they will be interested in learning. And of course, they would love to do activities with their parents. So here we go"

"The adoption of active learning techniques means discarding the traditional notion of what a "classroom" is and developing a new type of contemporary learning space: one that is more flexible, agile adaptive and equipped with technology to both personalize and expand conditions for learning. The comprehensive research, real-world examples, insights and exercises contained within the pages of Get Active: Reimagining Learning Spaces for Student Success provide that crucial first step for any educator or administrator looking to support today's learners with active learning concepts that will best prepare them for tomorrow's world."

"If you find yourself frustrated trying to keep up with the school packets, video chats, and virtual office hours, take a deep breath and a step back. Official school activities are important, but there are plenty of everyday activities that count as learning too. These kinds of activities have their limits (kids aren't going to learn calculus from cooking dinner), but overall, you can feel good about kids furthering their learning through these at-home activities."

I am a huge proponent of using hands-on, interactive learning activities to explore ill-defined problems as a way of teaching for all age groups. Given the spontaneity and uncertainty of these types of active learning environments, I believe educators should observe, reflect on, and analyze how learners interact with the materials, the content, the educator, and the other learners. This practice is in line with the teacher as ethnographer. In my role as a teacher as ethnographer, I made some initial observations during my first two weeks of teaching maker education for elementary age students. With half the kids under 7, I learned a bunch about young makers. Young makers are more capable than what people typically believe. Young makers need to be given more time, resources, strategies to learn how to solve more ambiguous and ill-defined problems (i.e., ones that don't have THE correct answer). Too many don't know how to approach such problems. If a project doesn't "work" during the first trial, they way too often say "I can't do this." They have a low tolerance for frustration; for not getting the answer quickly. Young makers often celebrate loudly and with extreme joy when making something work. Young makers like to work together but lack skills or desire to peer tutor one another. Young makers usually like to stand while working. Young makers are more capable than what people (adults) typically believe. During our maker education summer camp, the young makers made LED projects, circuit crafts, and simple robotics. Looking at the instructions for similar activities, the recommended ages were usually 8 and above. Yet, my group of 14 kids contained half under that age. The kids of all ages struggled a bit - as is common with making type activities but all were successful to some degree with all of the activities.

"I got my copy of Get Active: Reimagining Learning Spaces for Student Success at ISTE 2015 this summer in Philadelphia.  I love reading about and studying learning space design theory.  I truly feel that innovative learning environments can transform how our students learn.  This book is an excellent introduction to active learning spaces and strategies we can use in designing and redesigning learning spaces, from hacking our furniture to working with architects on new construction."

"ome widely held ideas about the way children learn can lead educators and parents to adopt faulty teaching principles Jan 1, 2015 Credit: Kiyoshi Takahase segundo MYTH HUMANS USE ONLY 10 PERCENT OF THEIR BRAIN FACT The 10 percent myth (sometimes elevated to 20) is mere urban legend, one perpetrated by the plot of the 2011 movie Limitless, which pivoted around a wonder drug that endowed the protagonist with prodigious memory and analytical powers. In the classroom, teachers may entreat students to try harder, but doing so will not light up "unused" neural circuits; academic achievement does not improve by simply turning up a neural volume switch. MYTH "LEFT BRAIN" and "RIGHT BRAIN" PEOPLE DIFFER FACT The contention that we have a rational left brain and an intuitive, artistic right side is fable: humans use both hemispheres of the brain for all cognitive functions. The left brain/right brain notion originated from the realization that many (though not all) people process language more in the left hemisphere and spatial abilities and emotional expression more in the right. Psychologists have used the idea to explain distinctions between different personality types. In education, programs emerged that advocated less reliance on rational "left brain" activities. Brain-imaging studies show no evidence of the right hemisphere as a locus of creativity. And the brain recruits both left and right sides for both reading and math. MYTH YOU MUST SPEAK ONE LANGUAGE BEFORE LEARNING ANOTHER FACT Children who learn English at the same time as they learn French do not confuse one language with the other and so develop more slowly. This idea of interfering languages suggests that different areas of the brain compete for resources. In reality, young children who learn two languages, even at the same time, gain better generalized knowledge of language structure as a whole. MYTH BRAINS OF MALES AND FEMALES DIFFER IN WAYS THAT DICTATE LEARNING ABILITIES FACT Diffe

"As a learning strategy, inquiry-based learning is all about learners constructing their own understanding and knowledge through asking questions. Unlike traditional learning methods that focus primarily on drills, memorization and rote learning, inquiry-based learning is essentially student-centered. It starts with posing questions and directly involves students in challenging hands-on activities that drive students to ask more questions and explore different learning paths. In today's post, we have assembled a collection of some useful web tools and apps that support the ethos of inquiry-based learning.  Using these tools will enable students to engage in a wide range of learning tasks that are all driven by a sense of inquiry and questioning."

"Synchronous and asynchronous learning technologies are the two most common online learning types. The Synchronous and Asynchronous e-Learning Infographic explores these common types of e-learning and how they can be implemented at organizations. Considering the Benefits of Synchronous and Asynchronous e-Learning, effective e-learning courses should include both asynchronous and synchronous learning activities. "

"If you're like me, you can't believe that June is already here. And despite the craziness of assessments, reporting, awards day ceremonies, field trips, and impending good byes to students, my thoughts are already turning to my favourite season of the year. Summer! Bikinis and beaches, airplanes and backpacks, golf clubs and green grass, patios and cool drinks, and professional learning. That's right-professional learning. It's not only students who can experience summer learning loss! The glorious months of July and August are a rare opportunity for relaxation and adventure, but summer holidays also gives educators a chance to engage in self-directed professional learning. With ten months of busy schedules and mandatory professional learning days, pursuing our own educational interests is an indulgence many of us we feel we can't afford. This summer I challenge you to choose a topic you are passionate or curious about and pair some professional learning with your favourite summertime activity. Put a few of these summer learning hacks into action and avoid the summer slide!"

"I have been asked to return to teach summer enrichment classes on maker education for elementary-aged learners at a local school during the summer of 2016. One of the new classes I am designing is called Coding and Bots. The description is: Learn how to code first by playing games and then by coding some bots including Sphero, OZOBOT, and Dash and Dot. All ages are welcome but the child should have basic symbol recognition/reading skills. Two things to note about this class are, first, I learned last summer not to underestimate the learning potential of very young kids. These classes are mixed ages ranging from 4 to 10 year old kids. For most of the maker education activities, the very young ones could perform them, sometimes better than the older kids. Second, I am a strong proponent of hands on activities. Although I like the use of iPads and computers, I want elementary aged students to have to directly interact with materials. As such, I am designing Coding and Bots to include using their bodies and manipulating objects. This translates into having all activities include the use of objects and materials excluding and in conjunction with the iPad - not just using the iPad and online apps/tools to learn to code. The activities I plan to do follow:"

"Learning to read can be really difficult for some kids but it doesn't have to be.  We have a huge list of reading activities that are so much fun.  If you need to learn something, why not learn through play? These activities are great for kids of all ages starting with the early pre-readers. "

"The new year is in full swing. Teachers across the world are back to work, sharing thoughts, ideas and resources...ready for what 2016 may bring. With this in mind, we thought when better than to share 16 ways to use the Thinking Kit. Using the Thinking Kit Creator (currently free), educational activities can be created on any browser. The user saves the activity, gets a code, then uses that code in the Thinking Kit App (free) to download the activity onto iPads (or get students to). This teams two really strong themes together - learning using iPads AND digital content creation, whether by teachers or the learners themselves. Activities involve one main goal/objective/question and snippets of information or images to help learners complete/answer it. The Thinking Kit App can be used individually, but works brilliantly as a group activity too. It seamlessly allows for multi-touch and engages learners in face to face collaboration as they learn. There is a dedicated Reflection Stage and lots of tools to help them become better problem solvers, critical thinkers and team players. So, without further ado, let's get started…"

Making is as old as learning itself. While the maker movement may only be about a decade old, the human desire to create dates back to the earliest forms of human activity, from making stone tools to drawing on cave walls (Halverson & Sheridan, 2014; Martinez & Stager, 2014). Thinkers such as Pestalozzi, Montessori, and Papert helped paved the way for the maker movement by stressing the importance of hands-on, student-centered, meaningful learning. Instead of viewing learning as the transmission of knowledge from teacher to student, these thinkers embraced the idea that children learn best when encouraged to discover, play, and experiment. More recently, maker education is being used as a way to connect do-it-yourself informal learning to classrooms. Driven by new technologies such as 3D printing, robotics, and kid-friendly coding, making is emerging as an effective way to introduce students to STEM, particularly women and minorities. By incorporating elements of making into the classroom, educators can bridge the gap between what students are passionate about and what they're learning in school.

"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."

"Computer coding is essentially a language that computer uses. When we think about helping kids learn computer coding, we automatically think we need a computer first. But in fact, there are many ways to learn computer coding without a computer, as many thinking and coding approach can be learned in many different activities off-screen. Today we share some off-screen activities that teach kids computer coding."