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Math Notes
Introduction The Fundamental Counting Principle described on this page begins with a basic property of counting. If we can break the problem up into smaller parts and count these smaller parts more easily, then we can multiply the number of the smaller parts together to discover the number of the whole. The simplest example is with a two-digit number. One possible method of counting the number of two digit numbers would be to make a list of them all and then count them. But this is tedious and time consuming. Instead, what we can do is break up our two-digit number into two parts: the first digit and the second digit. For the sake of keeping track of these parts we can represent them as spaces or as boxes to hold their places. _______ ________ Now what we need to determine is the number of possible values for each part. How many numbers can we put into the first digit? Well, we didn't specify that we are allowed to use numbers starting with zero so there is a little bit of ambiguity in the problem, but let's assume that we mean numbers that we would actually write as two digits normally. That means a number starting with 0 isn't possible, so we are left with 1, 2, 3, 4, 5, 6, 7, 8 and 9 to fill the first digit. That's nine possibilities. Now, how many numbers can we put in the second digit? Well, now we can use 0 because we do write numbers that end in zero as two digits. So our options for the second digit are all ten numbers 0, 1, 2, 3, 4, 5, 6, 7, 8 and 9. So now our places look like this: ___9___ ___10___ To get the number of two digit numbers, we just multiply 9*10 = 90. So there are 90 two-digit numbers. We know from experience that the smallest one is 10 and the biggest one is 99. We can extend this principle to much more complicated situations, and I will refer back to it from time to time. Worked Examples As the title of this page suggests, the Fundamental Counting Principle is most often used whenever Order Matters. It can be used for cases that either allow or disallow Repetition, but I will concentrate my examples here on cases With Repetition, because the cases with No Repetition will be discussed in Counting Methods III. A. Suppose we wished to determine the number of three-letter words whose middle letter is a vowel and whose first and last letters were consonants. Right away we see that we have a three-letter word, so it makes sense to try to divide this problem up into three parts. _______ ________
________ Let's start with the middle letter. How many vowels are there in the alphabet? Well, there's a, e, i, o and u. If we were talking about real English words, we might also wish to count y; however, most problems of this type consider y a consonant. That gives us five possibilities for the middle letter. The rest of the alphabet is consonants, so since there are 26 total letters, 26-5 = 21 consonants. (Note: if you choose to do this problem counting y as a vowel, remember that it's also a consonant.) This gives us the following: ___21___ ___5___
___21____ The total possible words of this configuration would then be 21*5*21 = 2205. B. How many possible telephone numbers are there for each telephone exchange? First, we have to figure out what this problem is asking. The telephone exchange is the first three digits of a telephone number. For television shows, the exchange 555 has been set aside just for them--so they never have to use a real number. Another way of asking this question is: choose one telephone exchange (let's say yours), how many people can have the same first three digits as you? Since a telephone has seven digits, we could start out this way: _______ ________ ________ _______ ________ ________ _________ We have seven slots, but since we are talking about fixing the first three digits, the exchange part of the number, we are really starting out with: ____1___ ____1___ ___1____ _______ ________ ________ _________ (Suppose I choose 555 as the exchange I'm working with, then there is only one possible choice for the first digit, and only one possible choice for the second, and one possible choice for the third digit. The other digits are what we still have to determine. This will be true for any fixed exchange.) The remaining four slots can be filled in with any number. There are no restrictions on the last four digits of a phone number. Phone companies like to give certain numbers to businesses and certain others to residents but that doesn't affect the total number of numbers. Each remaining digit can be any of: 0, 1, 2, 3, 4, 5, 6, 7, 8 and 9. So, we'll fill in the remaining slots with 10's. ____1___ ____1___ ___1____ ___10___ ___10____ ___10____ ___10____ So the answer to our question is 1*1*1*10*10*10*10 = 10,000. C. How many alphanumeric 6-letter passwords are there? By alphanumeric, we mean any letter or number. For each letter or space in the password we have ten number possibilities and 26 letter possibilities. Assuming the simplest scenario, where case doesn't matter and we aren't allowed to use special characters like # or what have you, each space in the password has 36 possible values. This gives us: ___36___ ___36___ ___36___ ___36___ ___36___ ___36___ The answer to our problem then is 36*36*36*36*36*36 or (36)6 = 2,176,782,336 possible combinations. Problem Solving Tips What I try to do when solving these kinds of problems is look for a few key things before I begin, and as I go through the problem.
Additional Problems with Answers 1. How many five digit numbers are there? 2. How many five digit even numbers are there? 3. In Ohio, the regular license plates have three letters, followed by four numbers. How many different license plates are there? 4. Suppose you flip a coin five times? How many different sets of five flips are there? 5. Suppose you are going to a restaurant that serves items a la carte. You decide to order three things: one meat dish, one vegetable dish and one bread. You could order beef, chicken or fish for the meat dish. You could order carrots, beans, broccoli, or corn for the vegetable dish. And you could order biscuits, muffins, or sweet bread for the bread dish. How many different possible dinners could be served? 6. Suppose you are dealing four cards from a deck and you end up with one card from each suit. How many different hands of this kind are there? (Hint: remember that there are 13 cards in each suit.) 7. A couple is interested in having children. They've decided on having three. Suppose they've chosen the names Chris, Kelly and Pat (all unisex names). How many possible ways can they name their three children? (They won't give two children the same name.) 8. How many radio station call signs are there? (Hint: They have to start with W or K and have four letters.) 9. How many ways are there to roll three six-sided dice? (Pretend you are rolling one die three times.) 10. Suppose you have a keypad with twelve keys on it for your security system. How many different four-key passcodes are there? Challenge Problems: 11. Suppose you have four friends and you want to buy tickets to the midnight showing of Star Wars: Episode III. How many different ways can the five of you wait in line? (Hint: Once you pick one friend to stand first in line, they can't stand anywhere else in line. If there are five ways for the first person to stand in line, how many people are left to stand second? third? etc.?) 12. How many 8-digit passwords are there using alphanumeric characters and case matters? You may want to state your answer in scientific notation. 13. If it takes you five seconds to check each of the passwords in problem #12, how long will it take to test them all? State your answer in years. Answers to Problems: 1. 105 = 100,000, if you allow 0 as a first digit,
otherwise 9*104=90,000 Links to Outside Sources
College Algebra Tutorial on The Fundamental Counting Principle Links to Supporting Topics Counting Methods II -- With Repetition,
Order Doesn't Matter History If you know of any links the discuss the history, origin or development of the Fundamental Counting Principle, please email me at the address below. |
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