Tag: <span>Teaching</span>

03 Mar

Free Teaching Resources Make Mathematics Fun on Interactive Whiteboards

Interactive whiteboards allow students to actually interact with the subject matter that is being presented and you’ll find that there are many great touch screen dynamics available that make them helpful for teaching math. Whiteboards are used with a computer and projector and put the images from a desktop onto the wall where they can be manipulated by touch or by using a pointer. When used along with free teaching resources whiteboards can make a huge difference in a math class.

When using these resources along with an interactive whiteboard, suddenly number is a subject that is more hands-on for students. Instead of being a concept that they can’t see, they are now able to see and touch the concept. Everyday ways of using math can be displayed with the whiteboard so they have both an auditory and a visual example of what is going on and why the information is important. The more senses engaged during learning, the more likely students are to retain the information that is being taught.

There is a large selection of free teaching resources available for math teachers. On the web there are many mathematical specific options that can be implemented into the classroom. Along with these resources, PowerPoint is a huge help as well. With this program you are able to create lessons, graphs to help illustrate lessons. Graphs that are in 3D are perfect for teaching math. With interactive whiteboards you can make simple 3D graphs come to life, changing them when things occur to illustrate what is happening.

You’ll also find that interactive whiteboards are perfect when you want to play games in the classroom. There are many great math games that help to illustrate tough concepts. Pupils are able to better understand the concepts with games and activities that make them use the material that they have learned. Not only can you use games that you find online, but you can easily create games of your own to play or to stretch advanced students they can create their own mathematical games, a great way to get the most out of pupil’s abilities and free teaching resources!



Source by Thomas Radcliff

15 Jun

Random Facts Versus Whole Science Approach to Homeschool Teaching

When it comes to learning science, most of us were taught in the public school system, which is a big proponent of the random fact teaching methodology. In other words, science was a single subject taught in a vacuum separate from other subjects. When it comes to teaching difficult or complex subjects such as science, it makes more sense to take a holistic approach. Here’s why.

The Science Random Fact Junk Drawer

There has been much news lately about the American education crisis in regards to a lack of interest in STEM (science, technology, engineering, math) disciplines. The United States is falling behind other developed countries when it comes to new technologies and discoveries, mainly because it is producing fewer graduates with related degrees.

One of the reasons for this lack of interest in STEM disciplines is due to the way kids are taught. Students often learn a bit of science here and a bit of science there without being provided any logical way to connect the dots. This collection of random facts can be likened to your junk drawer at home – you know there’s a screwdriver in the midst of all those rubber bands and paper clips and batteries and gadgets somewhere, you just can’t find it amongst all the clutter.

The same holds true for kids learning science. For instance, if a child learns a little something about the earth and the moon and how the shadow of our planet can cause a lunar eclipse, that’s an interesting, but random, fact. You might also have taught your child some astronomy concepts and explained how the moon affects the ocean’s tides. Perhaps your child has also learned something about gravity and the moon’s gravitational pull. But if you are using many mainstream homeschool science curricula, those facts were never pulled together to show the student how the moon is at the core of all these facts and they are interrelated. That’s why it’s so difficult for many kids (and adults alike!) to make the leap between one science fact and how it impacts so many other areas of the world around us. This also makes it very hard to extract a random fact later because the child must rely on rote learning.

The Whole Science Teaching Approach

A better, more effective way to teach homeschool science is through an exponential approach. By helping kids make their own connection between subjects, they are much better equipped to draw broader conclusions. This is also a great way to encourage their natural curiosity and develop hands-on experimentation that offers exciting new discoveries in the child’s mind.

The whole science homeschool teaching approach is all about extrapolation. Once your student has assimilated some core concepts they are prepared to expand that knowledge and apply it to different, everyday situations.

For instance, let’s go back to that random fact about the moon’s gravitational pull on earth. That’s a physic concepts and that explains much about a lunar eclipse, which is a topic generally brought up in astronomy. Those same gravitational forces are at work when it comes to oceanic tide cycles, a topic that may be part of biology learning. By painting the bigger picture, a student can connect the dots between physics and astronomy and biology herself and become excited about learning more.

This approach also compartmentalizes and organizes bits of information so they can easily be retrieved at will and on demand. And it aids the homeschool science teacher, who often doesn’t understand the information herself, present complex concepts and help the student come to a conclusion that need not be foregone.

When it comes to teaching a difficult subject such as science, the homeschool teacher would be wise to use a whole science approach rather than relying on a random fact methodology.



Source by Dr Rebecca Keller

10 Mar

Should the Teaching of Mathematics in Secondary Schools Be Resource Based?

Traditionally, the teaching of Mathematics in secondary schools rarely included the use of resources other than a text book. This was “satisfactory” because most of the student body was academically included. In today’s jargon, using Gardener’s learning styles; they were most likely maths-logic learners.

The prevailing pedagogue was “Chalk and Talk”. In simple terms it was lecture style approach followed by lots of worked exercises from simple to harder (more complex) examples. There was little or no attempt to teach problem solving skills needed to solve unfamiliar problems.

With the introduction of all students into secondary education in the mid twentieth century, the steady raising of the school leaving age and the expectation of parents that their offspring get the opportunity to seek university qualifications mathematics teachers had to work with students who could not learn just with the “Chalk and Talk” approach. Many able learners found that Mathematics seemed to have no real life meaning to them and they sought, when allowed, to leave their Mathematics classes for other subjects.

The “Chalk and Talk” approach did not help the slow learner to absorb the Mathematics that they needed to survive as a citizen in modern society. Behaviour problems abounded in Mathematics classrooms.

It became obvious to teachers and administrators and syllabus writers that vast changes needed to be made in the teaching of Mathematics. In Australia, corporations were crying out for problem solvers. They found Mathematics graduates were not. This prompted syllabus writers to look at the teaching approaches that would not only lead students to become real problem solvers but pedagogue that would enhance the learning of those who were not maths-logic learners. This also meant that assessment procedures should reflect the ways in which particular topics were taught.

Added to all of this was the advent of the calculator, (four operations, scientific and graphics calculators) which meant that much more in the way of real life problems could be incorporated in a mathematics lesson. The computer added further to this. At the same time, the time allocated to the teaching of Mathematics was being reduced particularly in secondary schools with other subject disciplines gaining that time.

The technology revolution meant there were topics in the Mathematics syllabus that were redundant and thus removed. The field of Mathematics had expanded. The study of probability and statistics had expanded dramatically and was widely used in the community. Consequently, many new topics were added to the syllabus to reflect modern developments in Mathematics and its use in the community.

Many of these new topics were not conducive to “Chalk and Talk”. Some required a hands-on approach; others needed the use of multi-media; and still other required the use of technology. Internet became a valuable resource for real life problems. Technology often allowed the teacher to work at greater depth in less time with their students.

Some of these resources could be used successfully in non-traditional assessment items. These assessment techniques often allowed the non-maths-logic thinkers to gain greater success.

More importantly, more students were beginning to become more interested and more successful in Mathematics. Teachers began to see less behaviour problems in their classrooms and greater on task work by students.

Thus it became obvious to educators in Mathematics that the pedagogue required to teach Mathematics to all students in secondary schools required Mathematics department to create their own set of physical resources to create the best possible learning experiences for their students. So the answer to the title of the article “Should the Teaching of Mathematics in Secondary Schools be Resource Based?” must be an emphatic “YES”.



Source by Richard D Boyce

11 Feb

10 Tips For Teaching Middle School Math

As a teacher for 11 years and middle-school math teaching consultant, I’ve seen a wide array of different math programs and classes. I’m sharing here the 10 best teaching tips I’ve compiled over the years.

1. Provide compelling content to study.

Years ago, a colleague I was working with said, “Maybe class can be fun, but I can’t make class compelling. I have to teach math!” It’s an assumption worth exploring.

Take Ron Berger’s middle-school math project to study levels radon in their own homes. Studying radon is boring. But Berger’s class project has got to be one of the most compelling projects in math class history. What if his students discovered dangerous levels of radon in the homes of one geographic area and published the results as they had intended? What would happen to real estate values in that area? What he found is that students were highly engaged in mapping, taking averages, looking at standard deviations- students that heretofore didn’t care one bit about radon or the other concepts.

So what’s the trick? The trick is that there isn’t one. You can’t trick students into finding something compelling if it isn’t. Take a little bit of time to develop a few topics of study throughout the year that you find compelling- the Economy, the Presidential Campaigns, the Human Body, etc. Find an authentic way to present your result- the paper, the web, a magazine. Keep the project small, authentic and do-able.

Students of teachers that do take this kind of time have better outcomes on state tests than students of teachers who only stick to the text. Almost any social studies context provides a backdrop for learning that adds depth.

Even teachers who hold a math “topics” class only once a month see real benefits, so you don’t have to abandon your regular class. And, you’ll find that students are more engaged when regular class is held.

If you want to go really deep and have solid administrator support, look into the school reform movement of Expeditionary Learning Schools who have an excellent approach to thematic teaching.

2. Don’t use extraneous rewards such as candy, purchase points, stickers, etc.

There is nothing more certain than seeing the culture of a math class decline over a period of years when a teacher bribes them. The intent of the teacher, of course, is good. A teacher cares about his or her students and wants the very best for them. “I don’t care how they learn math,” one teacher said to me. “I just want them to learn it so that they are prepared.” The teacher cared enough to purchase candy out of her own pocket, but the real message to students is this: the “positive reinforcement” of candy means “math isn’t worth doing on its own.” The research is clear on the matter too, and shows us that extrinsic, non-relevant rewards hurt learning.

Even if the effects aren’t immediate, over time so called “positive reinforcements” like these mentioned above erode an otherwise high-quality math program. As a teacher, you are much better off trying to create inherently compelling curriculum than buying candy.

3. Build a culture where students teach each other.

For many teachers, one student helping another is called cheating. But I actually found that the better middle-school math programs all encouraged students to team together at certain times throughout the week. The activities were usually graded as complete or not-complete, and when tied to meaningful tasks, such as building a survey together and collecting original data, student comprehension was greater than on individual tasks.

Building the kind of culture that works for student pairs or groups takes years and lots of practice. But before you give up and decide it doesn’t work, determine if you are following tips #1 and #2 first.

4. Give less, but more meaningful work, including homework.

The Trends in International Mathematics and Science Study labels the curriculum in the United States as “a mile wide and an inch deep.” Their review of math texts in middle-school found that some were almost 700 pages long. With heavy pressure to teach to the standards, as a teacher you might be tempted to skip and jump to many topics throughout the text. Don’t. It achieves little learning.

Choose the most important pieces before the beginning of the year, and keep it simple. Teach the concepts you do teach with depth.

The national advisory counsel formed from the study recommended “put first things first” and suggested that indeed, less is more. Take the time to cull the curriculum to a manageable size for your students, and present them with only that. If you have to “cover” standards, find out what standards and document when you indeed teach them in class. You’ll find that teaching with depth often reaches to a broad array of standards.

It’s helpful to know what’s driving the breadth. As the national study panel concurs, publishers are trying to meet demands of hundreds of different districts by including everything that any school might want. And while publishers have been attempting custom publishing, it is just as difficult to create a math curriculum for a small district as a large one. Thus, the challenges of book publishing lead to a single, uniformly created overarching textbook. Often this is a very large text or an entire series.

In the classroom, teachers and students become overwhelmed and unable to handle the scope or breadth of learning in this form. As teachers, we have to recognize that predominantly negative emotions surround math in middle-school, and that anything we can reduce those emotions will go a long way toward gains in learning learning. Placing a 500 page text in front of a 7th grade student is unlikely to help, so use it sparingly and build little, home-made notebooks for daily use.

5. Model thinking, not solutions or answers.

Don’t show a student how to solve something. Instead “think aloud”. For example, you might have a whiteboard with a problem up, and start by saying, “o.k., I notice that the 4 numbers I am to sum are all in the thousands category, and that the first is near 3,000, the second near 5,000, and the third… I am confused about…” Model exactly what you thinking including confusion, emotions, skills, strategies and more.

When you do this, also let your students know how mathematicians think. One piece of research that is helpful to know is that mathematicians spend a long time thinking about how to set up a problem, a little bit of time doing the problem, and a long time “looking back” by asking the question, “Does this make sense?’ Model that for your students, by putting up a complex problem on the board and spending time not just jumping into a solution, but just talking about what strategies you might use to solve the problem.

6. Provide feedback that is immediate, relevant to the task, non-comparative, and leads the way to next steps.

Many teachers believe that grading is a form of feedback. It isn’t. Grading, when done well, can be a form of assessment of learning, but the distinction should be clear. Grades are not an effective tool as assessment for learning. Grades are the end of the road, when you assess what has been learned, but they should not be intended to inform a student where to go next.

Take, for example, three groups of students who received different kinds of “feedback” on math papers they had “turned in.” The first group received only narrative feedback (no score) informing them where and how they made mistakes. The second group received a grade (or score) and narrative feedback. The third group received just a grade. Not surprisingly, the students who received narrative feedback improved when re-tested. Those who had received only a grade did not have the information to improve, and performed the same when re-tested. But here is the surprising part. There was no difference between “grade-only” group and the group that received the grade and narrative feedback. Why? The students who received both a grade and narrative feedback completely ignored the written suggestions and only looked at the score. “I got a blah, blah, blah… what did you get?”

Because we live in a world where grades and formalized assessments are so important, work with the system by differentiating assessment for learning and assessment of learning.

When you are grading, one guide is to reference Rick Stiggins strategies of assessment for learning. That way, when you are conducting an assessment of learning (i.e. grading), you’ll notice that you are momentarily stepping out of the role of improving a student’s learning and won’t have the conflict of trying to do two things at once.

7. Change mimeographed sheets to problems you and your students personally develop.

A pervasive aspect of our culture is to give out page after page of information. In faculty meetings, business meetings and conferences, hundreds of pages of documents are handed out. It makes us look organized and prepared. It’s also a way to “cover” content. But for a middle-school math student, it also makes it hard to determine what is important. Was it the fractions part? Was it the decimals section? Was it the number line? Was it the triangle puzzle problem? Was it the cartoon?

Instead of another mimeographed page, have your student write their own story problems. Tell them to add artwork for comprehension. Give them the latitude to make them fun. Celebrate them by posting them in class. Give them 5 home-made story problems they create for homework instead of a mimeographed sheet with 30 problems, and really dive into improving them through revision.

8. Use story to teach math.

Write a story, a real story with characters and plot, and add the math problem set. Write about wizards that need to use angles for their sorcery. Write about spice trading ships on the deep seas. Write a story that lasts a whole page before even getting to the math portion. You’ve engaged the right-side, or less analytical, part of the brain and you’ll see a powerful effect of enhanced engagement.

9. Get math tutor volunteers once a week for two-months before state testing.

As a teacher or administrator, spend time during the fall months by planning for and scheduling a single day each week during the months of February and March (right before testing) to have volunteers come in to teach math in small groups. But what’s nice is that if developed correctly, these volunteers don’t need to have any special training in math.

Start with a simple plan. Each student has 10 skills they have chosen to work on during the whole class tutoring session and have written down their practice problems in class. The phone calls are made, the specific planning with an administrator is done, and volunteers come in and help the students answer the 10 questions during class with support. Schedule tutoring once every week for two months before testing and see your scores greatly improve.

10. Work with the emotions your students have for math.

10a. Ask your students how they feel about math. Use a bit of class time periodically to gain a better sense of where they are. And, just let them feel how they feel. If they like math, they like it. If they are bored, empathize. If your students can’t stand math, you will gain far more ground by seeing their perspective than trying to prove they are wrong. As a teacher this is hard because we are so accustomed to trying to “fix” the situation, and of course, our ego is tied to student emotion. If our students are bored, we feel like we aren’t doing the right thing. But the larger truth is that there is an ebb and flow in all of us for the topics we are learning. When the boredom, frustration and negativity does emerge, try understanding it. Perhaps class does feel a little boring. That’s o.k. Sometimes it will. And then slowly, over a period of years, build those compelling pieces into your classes so that you punctuate boring times with excitement and joy.

10b. Go slowly. Changing the direction of your math class is like trying to change the direction of a large ship, especially when dealing with emotions. Even once everything is place for the changes to occur, you will notice the “ship’s” momentum going in the same old direction before you sense any real shifts. This is part of the process. It took me three years to develop a coherent math program at my middle-school and even then, we occasionally slipped in to old patterns. Good luck!



Source by Scott Laidlaw

16 Nov

The Art of Teaching Homeschool Science

When it comes to homeschooling your kids in the subject of science, is there a cut-and-dried formula? While many parents have been led to believe there is, the reality is that it’s more beneficial to treat the process as an art than a science. It’s important for kids to use their natural curiosity to explore the world around them and truly enjoy science class. The following artful tips will help you teach homeschool science in a way that makes it fun and engaging.

Active Learning Through Open Inquiry

There are lots of scientific facts and data to be learned. But rather than have your child passively learn via memorization, science becomes interactive through the process of open inquiry. Encourage your kids to think about how things might work before telling them how scientists have discovered they actually do work; encourage them to question.

Kids are born with natural curiosity and will ask questions in the natural course of their learning. Rather than answer their queries with rote facts, answer them with questions of your own that make them think more deeply about a subject. If your child asks, “Why is the sky is blue?”, counter that with, “What do you think there is in the atmosphere that produces the color blue?” That’s open inquiry that encourages exploration and discovery.

Science Should Be Explored

There is a way of teaching that chokes off a child’s natural curiosity and then there is a way of teaching that encourages inquisitive minds to further explore scientific theories and facts.

If you think that science is a “hard” subject to learn, it’s probably because you were taught to memorize random facts or complicated equations. This is not the most effective approach to teaching science. Just knowing random facts about something doesn’t mean you understand it.

The same is true for your child. Don’t worry about having her memorize a set of facts, but encourage her to ask questions that come from her innate sense of curiosity. So rather than asking her to learn the Latin names for each species of North American bird, for instance, help her find the answers to things she wants to know, such as how birds are able to fly and how they communicate with each other and what types of food they eat.

Break the Rules of Experimentation

Performing hands-on experiments is a vital part of learning science. But rather than insisting that experiments follow a prescribed set of steps or rules, allow your child to dive right in and maybe even make mistakes. Guidelines are good but there’s no reason you can’t break the rules and, in fact, you should do so regularly. This encourages lots of questions and further experimentation to see what might happen if… if a variable is changed or if the experiment is moved or if the same results would occur with other variables. You never know, you and your child might just discover something new.

Teaching your kids science is about more than just following a prescribed curriculum. Every now and then you should step outside the box and see what happens. Have your kids think about broader possibilities and help them discover answers to their questions on their own. All science is really an art; it’s not black and white but shades of gray that color the results of those who dare to be curious and explore the world around them.



Source by Dr Rebecca Keller

12 Aug

Teaching High School Mathematics in One Hour Time Slots

In the mid-1990s, the administration of the school in which I taught decided to change from using 40 minute teaching periods to 70 minute periods. It allowed the administration to gain extra teaching time from each teacher within the industrial award provisions. In fact, it allowed the administration to have English, Science and Mathematics teachers teach an extra class without having more time in the classroom.

My school became one of the first to do this and became an example for other schools to follow in the following years. As a result of this, I was asked to present a workshop to a nearby high school Mathematics Department explaining how my Mathematics Department had gone about adjusting to this major change.

Below is a synopsis of what I spoke about during this workshop.

For the teachers, personally:

  • It is hard work.
  • The class time must be regarded as “untouchable” and you must fight to prevent it being “borrowed” even by the administration.
  • Detailed planning is essential. It is easy for the teacher to waste/lose time without realising it is happening.
  • They need to develop a strategy to cope with absent students as even one period missed is a great chunk of their learning time.
  • Additionally, teachers need to develop a strategy for any absences they may have. In fact, teachers would be tempted to teach on even when they are not well so as to not lose valuable teaching time.
  • Their lessons must become a series of mini lessons to cover the course and to survive physically.
  • It is possible to teach a whole unit in one period.
  • They need to work smart. They must use every available tool or pedagogue to get the message across to the students.
  • Group planning by teachers will improve the quality of lessons presented to the students.

For the teachers and students:

  • There is a lack of continuity created by less teaching periods spread over the week. (In some schools, there was a two week rotation of periods.)
  • It is difficult to create a work ethic when you see the class less frequently.
  • Learnings skills must be taught more thoroughly because students must become more accountable for their learning, homework and study.
  • Learning to think mathematically must become a priority to help the students accept more accountability for their learning.
  • Mentoring becomes a useful tool to consolidate learning.
  • Learning the basic skills and procedures is paramount to gaining worthwhile success in their learning.
  • There is time to pursue problem solving in unfamiliar contexts provided the teacher’s planning covers the mandated learning.

Many of the ideas raised above had become part and parcel of Mathematics teaching since the late 1980s brought about by the introduction of new syllabuses in Mathematics that opened up the teaching of Mathematics moving away from the traditional “Chalk and Talk” Maths lesson to lessons using a variety of pedagogue.

Personally, I found teaching with 70 minute periods challenged me to use a greater degree of teaching pedagogue. Initially, I found I was rushing to cover the course. I did find that teaching had become more stimulating.

As head of Mathematics in my school, I did not see any significant change in the standard of the work produced by teachers and students. It just goes to show how adaptable teachers and students can be.



Source by Richard D Boyce