Monograph No. 7:
Problem Solving in the Mathematics Classroom
April 1982
Publication of the Mathematics Council of The Alberta Teachers’ Association
Editor’s Comments
The development of the ability to solve problems has long been recognized as one of the major goals of mathematics education. With the recommendation by the National Council of Teachers of Mathematics (NCTM) that “Problem Solving Must be the Focus of School Mathematics in the 1980’s,” the goal of teaching problem solving in the mathematics classroom has taken on the fervor of a campaign slogan. Still , there Is only one group of people capable of attaining this goal: the classroom teachers.
Interest in problem solving is not new to Alberta’s educators- Perhaps
the finest work on the teaching of problem solving in the early childhood
years was published by Doyal Nelson and Joan Kirkpatrick Worth of the
University of Alberta i n the 37th Yearbook of the NCTM. Long before the
problem-solving bandwagon began to r o l l , Alberta Education noted in its 1977 Curriculum Guide for Elementary Mathematics that problem solving was a “unifying theme which permeates all the strands of the elementary school mathematics program.” Representative of the new impetus for the teaching of problem solving are the changes suggested in the 1981 revision of Alberta Education’s Curriculum Guide for Elementary Mathematics^ The revised curriculum guide includes the learning of problem-solving skills as a separate strand. The authors of the guide are quick to point out that the inclusion of a problem-solving strand ” i s not intended to portray problem solving as a topic unto itself. ” Rather than a change i n the curriculum, the inclusion of the problem-solving strand represents an effort to make teachers more aware of how they might teach for the development of problem solving abilities . In order_to help facilitate the teaching of the new scope and sequence of problem-solving skills. Alberta^Education has produced a manual entitled .Let Problem Solving Be The Focus i n the 1980’s. In addition to a scope and sequence chart of problem-solving skill s for elementary mathematics categorized by Polya’s four phases for solving problems (understanding the problem, devising a plan, carrying out the plan, and looking back), the manual provides an array of suitable problems for students of varying developmental abilities.
This edition of the Math Monograph provides teachers with a wide range of articles on the teaching of problem solving In the mathematics classroom. The monograph i s separated into four sections: Understanding the Problem, Devising a Plan, Carrying Out the Plan, and Looking Back. The f i r s t section includes articles which provide a sense of the “problem” of teaching for problem solving: What i s given? What is our goal? In general terms, how might the goal be attained? The second section provides suggested plans for attacking related classes of problems. The articles i n part three focus on the solution to specific problems- Finally, the last section includes articles which reflect on the past, present, and future of teaching for problem solving. At times the placement of an article into a section was arbitrary: I.e., several articles could be placed comfortably within any one of the sections.
This monograph presents the thoughts of a diverse group of authors, representing seventeen states and provinces. Despite the diversity , two common threads run through the articles . The first is a common notion for the meaning of the word “problem.” A problem Is defined as a “task” which an individual attempts to resolve, given that this resolution is within the person’s ability and it is not resolved by the person’s immediate application of some algorithm- Resolution of the task i s taken as the individual’s belief, stated or implied, that he has obtained the “actual” solution. Whether or not a task i s a problem is dependent on the characteristics of the individual and his attempted paths to resolution. The second common thread woven i n the articles is the belief that the actions of the teachers can affect the development of their students’ abilities to solve problems-
The articles included in this monograph have been specifically written for this audience. They are not reprinted from other publications- Several people are responsible for the selection and editing of the articles for the monograph. In the spring of 1980 over 40 letters soliciting submissions for possible inclusion in the monograph were sent to individuals speaking on the teaching of problem solving at meetings of the National Council of Teachers of Mathematics in Calgary, Regina and Seattle. Letters were also sent to appropriate speakers at the Vancouver meeting of the Research Council on Diagnostic and Prescriptive Mathematics. Under the guidance of Lyle Pagnucco and Rich King, at least four teachers reviewed each submission. Articles were accepted based on the recommendations of the reviewers and edited to avoid redundancy and to ensure that the examples provided were phrased appropriately for the Intended audience. Later the articles were re-edited i n an attempt to provide the greatest possible amount of Information i n a limited amount of space. For example, only those bibliographic entries specifically referred to in an article were included with the l i s t of references at the end of each article. Readers interested in detailed bibliographies of mathematical problem solving are directed to Sarah Mason’s annotated bibliography i n the 1980 Yearbook of the NCTM and Frank Lester’s chapter on problem solving research i n NCTM’s Research i n Mathematics Education.
Finally , it is with sincere appreciation that I acknowledge the skillful and dedicated efforts of Judy McDonald. I t i s through her technical skill that you are now able to share this edition of the MATH Monograph with your fellow teachers.
Sid Rachlin
1 – 5
6 – 7
Sid Rachlin
8
Part I: Understanding the Problem – The Given and the Goal
9 – 16
Problem Solving: Some Means and Ends
C. Edwin McClintock
17 – 32
An Instructional System for Mathematical Problem Solving
Randall I. Charles
33 – 43
Diagnosing Reading Difficulties in Verbal Problem Solving
Jeffrey C. Barnett
44 – 48
Leading Problem Solving in an Elementary School Classroom
Kil S. Lee
49 – 60
Problem Solving for the High School Mathematics Student
Cheryl Kantecki and Lee E. Yunker
60
Part II: Devising a Plan – Alternatives for Related Problems
61 – 66
Visualization: A Problem-Solving Approach
Barbara Moses
67 – 69
Graphic Representations of Word Problems
Verena Sharkey
70 – 73
Teaching Model Problems and the Colour Coding of Problems
Bruce Hedderick
74 – 83
Teaching the Solution of Arithmetic Story Problems as a True Problem-Solving Task
C. Mauritz Lindvall
84 – 87
Using Machine Technology to Enhance Problem Solving in the Middle School Mathematics Classroom
Karen L. Jones, Charles E. Lamb, Fredrick L. Silverman
88 – 94
Al Anderson
94
Part III: Carrying out the Plan – Problems for the Classroom
95 – 100
We Have This Problem with the Hall Lockers
James E. Riley
101 – 103
Nuts! or How Children Solve Problems
John Firkins
104 – 108
Elliott Bird
109 – 113
Problem Solving with Nim Games
Raymond E. Spauldlng and David L Albig
114 – 119
The Olympics – A Problem-Solving Plot
Shirely S. Heck and C. Ray Williams
120 – 125
H. Laurence Ridge
126
Part IV: Looking Back – Looking Ahead
127 – 140
Recent Advances in Mathematics Education: Ideas and Implications
Alan H. Schoenfeld
141 – 145
Issues in Mathematical Problem-Solving Research
Frank K. Lester, Jr.
146 – 165
Ye Shall Be Known by Your Generations
Stephen I. Brown
166 – 170
Trick Questions and Tricky Questions
Richard King
171 – 173
Problem Solving: Goals and Strategies
Jesse A, Rudnick and Stephen Krulik