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BMMA 1st Term Midterm Exam Cheat Sheet
This is a draft cheat sheet. It is a work in progress and is not finished yet.
What is Inductive Reasoning
It is the process of reaching a general conclusion by examining specific examples. |
Conjecture is the conclusion brought upon this reasoning. This conclusion may be right or wrong |
Uses of Inductive Reasoning
Use Inductive Reasoning to Predict a Number |
Using inductive reasoning to predict the next number |
Use Inductive Reasoning to Make a Conjecture |
Using inductive reasoning to make a conjecture about the relationship between the size of the resulting number and the size of the original number |
Use Inductive Reasoning to Solve an Application |
Scientists often use inductive reasoning. |
What is Deductive Reasoning?
It is the process of reaching a conclusion by applying general assumptions, procedures, or principles. |
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Uses of Deductive Reasoning |
Using Deductive Reasoning to Establish a Conjecture |
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Logic Puzzles |
These can be solved by using deductive reasoning and a chart that enables us to display the given information in a visual manner. |
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Problem Solving with Patterns
Term of a Sequence |
An ordered list of numbers such as 5,14,27,44,65 … is called a sequence. |
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The numbers in a sequence that are separated by commas are the terms of the sequence. |
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. It is customary to use the subscript notation to designate the nth term of a sequence. |
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The “nth” term is a formula with “n” in it which enables you to find any term of a sequence without having to go up from one term to the next. |
a1 represents the 1st term of a sequence. |
“n” stands for the term number, so to find the 50th term, we would just substitute 50 in the formula in place of “n”. |
a2 represents the 2nd term of a sequence. |
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a3 represents the 3rd term of a sequence.. |
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aN represents the nth term of a sequence. |
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Difference Table |
The difference table shows the differences between successive terms of the sequence |
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Polya’s Four-Step Problem Solving Strategy
Understand the Problem |
Can you restate the problem in your own words? |
This part of Polya’s four-step strategy is often overlooked. You must have a clear understanding of the problem. |
Can you determine what is known about these types of problems? |
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Is there a missing information that, if known, would allow you to solve the problem? |
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Is there an extraneous information that is not needed to solve the problem? |
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What is the goal? |
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Devise A Plan |
Make a list of the known information. • Make a list of information that is needed. |
. Successful problem solvers use a variety of techniques when they attempt to solve a problem. |
Draw a diagram. • Make an organized list that shows all the possibilities. |
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Make a table or a chart. • Work backwards. |
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Try to solve a similar but simpler problem. • Look for a pattern. |
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Write an equation. If necessary, define what each variable represents. • Perform an experiment. |
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Guess at a solution, then check your result. |
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Carry out the Plan |
Once you have devised a plan, you must carry it out. |
Work carefully. • Keep an accurate and neat record of all your attempts. |
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Realize that some of your initial plans will not work and that you may have to devise another plan or modify your existing plan. |
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Review the Solution |
Ensure that the solution is consistent with the facts of the problem. • Interpret the solution in the context of the problem. |
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Ask yourself if there are generalizations of the solution that could apply to other problems. |
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