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Strike it out—add it up

Published online by Cambridge University Press:  22 September 2016

Calvin T. Long*
Affiliation:
Washington State University, Washington 99164, U.S.A.

Extract

If you were to ask a random sample of students from your school if they liked mathematics, what do you suppose their responses would be? Almost certainly most of them would respond negatively and some would do so with considerable vigour. But what of the others? Some students do like mathematics and we might well ask why this is so? Do you suppose it is because these students realise that knowledge of mathematics is a necessary survival skill in today’s increasingly technological society? Surely the answer is no. Do you suppose it is because they realise that mathematics has many useful real life applications or that lack of knowledge of mathematics will effectively prevent them for entering college in most disciplines? Again the answer is almost surely no. Certainly mathematics is relevant and we should teach our students that this is so and we should teach them useful and appropriate applications as well. At the same time, it is my experience that student attitudes towards mathematics are much like they are towards exercise—in general, they do not exercise because it contributes to good health, but because exercising is usually done in the form of a game or a competition that they find attractive in and of itself. Similarly, what turns students on to the study of mathematics and provides the needed motivation for learning are the remarkable patterns and surprising results with which our subject is so replete. Successful teachers realise this fact and utilise it to maintain a high level of interest and enthusiasm which enables them at the same time to teach ideas which, while useful and necessary, may be more prosaic.

Type
Research Article
Copyright
Copyright © Mathematical Association 1982

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References

1. Long, Calvin T., Mathematical excitement—the most effective motivation, The Math. Teacher, 75, 413415 (1982).Google Scholar
2. Moessner, Alfred, Eine Bemerkung iiber die Potenzen der Natürlichen Zahlen, Bayer, Akad. Wiss, Math.-Nat. Kl. S.-B. No. 3, 29 (1951).Google Scholar
3. Paasche, Ivan, Ein Zahlentheoretisch-Logarithmischer Rechenstab, Math. u. Naturwiss-Unterr. 6, 2628 (1953/54).Google Scholar
4. Paasche, Ivan, Eine Verallgemeinerung des Moessnerschen Satzes, Compositio Math. 12, 263270(1955).Google Scholar