Its heart is a series of small behavior preserving transformations. Each transformation called a "refactoring" does little, but a sequence of these transformations can produce a significant restructuring. Since each refactoring is small, it's less likely to go wrong. The system is kept fully working after each refactoring, reducing the chances that a system can get seriously broken during the restructuring.
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The Concept Concept of factoring Teaching of Place-Value Richard Garlikov An analysis of representative literature concerning the widely recognized ineffective learning of "place-value" by American children arguably also demonstrates a widespread lack of understanding of the concept of place-value among elementary school arithmetic teachers and among researchers themselves.
Just being able to use place-value to write numbers and perform calculations, and to describe the process is not sufficient understanding to be able to teach it to children in the most complete and efficient manner.
A conceptual analysis and explication of the concept of "place-value" points to a more effective method of teaching it. However, effectively teaching "place-value" or any conceptual or logical subject requires more than the mechanical application of a different method, different content, or the introduction of a different kind of "manipulative".
And it is necessary to understand those different methods. Place-value involves all three mathematical elements.
Practice versus Understanding Almost everyone who has had difficulty with introductory algebra has had an algebra teacher say to them "Just work more problems, and it will become clear to you. You are just not working enough problems.
Meeting the complaint "I can't do any of these" with the response "Then do them all" seems absurd, when it is a matter of conceptual understanding.
It is not absurd when it is simply a matter of practicing something one can do correctly, but just not as adroitly, smoothly, quickly, or automatically as more practice would allow.
Hence, athletes practice various skills to make them become more automatic and reflexive; students practice reciting a poem until they can do it smoothly; and musicians practice a piece until they can play it with little effort or error.
And practicing something one cannot do very well is not absurd where practice will allow for self-correction. Hence, a tennis player may be able to work out a faulty stroke himself by analyzing his own form to find flawed technique or by trying different things until he arrives at something that seems right, which he then practices.
But practicing something that one cannot even begin to do or understand, and that trial and error does not improve, is not going to lead to perfection or --as in the case of certain conceptual aspects of algebra-- any understanding at all.
What is necessary to help a student learn various conceptual aspects of algebra is to find out exactly what he does not understand conceptually or logically about what he has been presented.
There are any number of reasons a student may not be able to work a problem, and repeating to him things he does understand, or merely repeating 1 things he heard the first time but does not understand, is generally not going to help him.
Until you find out the specific stumbling block, you are not likely to tailor an answer that addresses his needs, particularly if your general explanation did not work with him the first time or two or three anyway and nothing has occurred to make that explanation any more intelligible or meaningful to him in the meantime.
There are a number of places in mathematics instruction where students encounter conceptual or logical difficulties that require more than just practice. Algebra includes some of them, but I would like to address one of the earliest occurring ones -- place-value.
From reading the research, and from talking with elementary school arithmetic teachers, I suspect and will try to point out why I suspect it that children have a difficult time learning place-value because most elementary school teachers as most adults in general, including those who research the effectiveness of student understanding of place-value do not understand it conceptually and do not present it in a way that children can understand it.
And they may even impede learning by confusing children in ways they need not have; e. And a further problem in teaching is that because teachers, such as the algebra teachers referred to above, tend not to ferret out of children what the children specifically don't understand, teachers, even when they do understand what they are teaching, don't always understand what students are learning -- and not learning.
There are at least two aspects to good teaching: It is difficult to know how to help when one doesn't know what, if anything, is wrong. The passages quoted below seem to indicate either a failure by researchers to know what teachers know about students or a failure by teachers to know what students know about place-value.
If it is the latter, then it would seem there is teaching occurring without learning happening, an oxymoron that, I believe, means there is not "teaching" occurring, but merely presentations being made to students without sufficient successful effort to find out how students are receiving or interpreting or understanding that presentation, and often without sufficient successful effort to discover what actually needs to be presented to particular students.
That is not always easy to do, but at least the attempt needs to be made as one goes along. Teachers ought to have known for some time what researchers have apparently only relatively recently discovered about children's understanding of place-value: Jones and Thornton, p.
His [sic; Her] investigation showed that despite several years of place-value learning, children were unable to interpret rudimentary place-value concepts. It should not be surprising that something which is not taught very well in general is not learned very well in general.
The research literature on place-value also shows a lack of understanding of the principle conceptual and practical aspects of learning place-value, and of testing for the understanding of it.
Researchers seem to be evaluating the results of conceptually faulty teaching and testing methods concerning place-value. And when they find cultural or community differences in the learning of place-value, they seem to focus on factors that seem, from a conceptual viewpoint, less likely causally relevant than other factors.
I believe that there is a better way to teach place-value than it is usually taught, and that children would then have better understanding of it earlier.
Further, I believe that this better way stems from an understanding of the logic of place-value itself, along with an understanding of what is easier for human beings whether children or adults to learn.
A teacher must at least lead or guide in some form or other. How math, or anything, is taught is normally crucial to how well and how efficiently it is learned.Due to time constraints in my corner of the world (school started a week ago) I’m gonna have to shelve my typically softspoken online persona and get straight to it.
If you’d like to see assessment amount to more than a meaningless exercise in classroom control, if you’d like to see cheating. Introduction to Factoring Could you explain the concept of factoring and give examples of its practical uses?
Factoring is an idea you might be familiar with from multiplication. If you need help in intermediate algebra, you have come to the right place. Note that you do not have to be a student at WTAMU to use any of these online tutorials.
Component-based directives are becoming increasingly popular in the Angular community. One reason for this is that Angular 2 will be all about components and people are preparing their 1.x code for the upgrade. Another reason is that componentization just makes apps easier to work with. The Concept and Teaching of Place-Value Richard Garlikov. An analysis of representative literature concerning the widely recognized ineffective learning of "place-value" by American children arguably also demonstrates a widespread lack of understanding of the concept of place-value among elementary school arithmetic teachers and among researchers themselves. STEM stands for science, technology, engineering, and math. Learn more about what STEM education is, why it is important and explore standards.
2 Concept Note: Program Details (Program Details should be a maximum of two (2) pages in length) (1) Development Objective(s): (a) To promote faster, private sector-led growth by improving the access of African exporters and importers to domestic.
Solving Quadratic Equations [ top of page] (5/98). Recall a linear equation is one that looks like ax + b = cx + d, and our strategy was to get all x terms on the left, all constants on the right, then divide by the coefficient on x to solve.
The technology of building information modeling is a new phenomenon in the world of construction engineering industry; it is constantly developing and changing borders and application forms.