Monday, April 6, 2009
Math Teachers at Play #4, Krypto, Updates (Odds and Evens),...
1) The latest "biweekly" edition of our new Carnival, Math Teachers at Play, is currently being hosted by Misty over at Homeschool Bytes. I enjoyed the "step by step" approach, progressing from primary math activities like Candy Math through middle school posts like Division of Fractions Conceptually to secondary articles like Ten 16th Century word problems. I contributed a post on Function Questions for the SATs. I'm not including any direct links to these articles. Go to Misty's site to enjoy this carnival!
2) I'm putting a lot of effort into the SAT Math Tips feature in the sidebar (readers of my feed won't get to see this of course unless they visit the site). I realize a good part of the country takes the ACT but the suggestions may be applicable to any standardized test and the math content is valid for anyone who wants to use it.
3) The Read More feature I recently instituted has some bugs as I'm sure you noticed. It doesn't work in RSS or Atom feeds of course and it sometimes doesn't work properly even on this site. I'm a coder at heart but I'm not sure it's worth all the effort. Clearly the Blogger developers are not interested in making things easy for us. You may see Read more... even if there is nothing else to see or it may not work all! Too late for me to migrate to Wordpress at this point... Please be patient with me here as I work through this.
4) The Math Problems of the Day in the sidebar are of good quality and are challenging but I'm seeing more repetition of questions. I will evaluate this and decide if I want to keep this feature.
5) No, I haven't forgotten about the next MathNotations contest I promised for April or May. Stay tuned...
6) Ever hear of Krypto or 24 (the game not the TV show!) or the more well-known "Four Fours Game"? I played many years ago and have always enjoyed the challenge of this tantalizing arithmetic game. I've used it effectively in upper elementary and middle school classrooms when I was a math staff developer to reinforce order of operations and basic fact recall (no calculator allowed!). Ok, so I'm now driving you crazy with another KenKen-like game!!
Click on Read more to learn more. (if this works!).
Here is a sample play of Krypto:
Suppose you're dealt the following five number cards:
5, 9, 4, 11, 1.
A 6th or objective card is turned up, say 2.
Using some or all of the four basic arithmetic operations and the 5 numbers exactly once, produce the objective number. This one is straightforward using only addition and subtraction:
11 +たす 5 -ひく 9 -ひく 4 -ひく 1 =わ 2. Krypto! You've Won!
It is possible to be dealt an "impossible" hand for which there is no solution or there could be many solutions for the same hand! The original game did not allow the use of parentheses but you could choose any variation you wish, including reducing the number of cards to 4. An ordinary deck could be used modifying the face cards to be 11,12, etc.
If you want to play the online version from mphgames, go here for instructions and play. Your browser must be java-enabled but most are. For more background on the game and a discussion of the underlying combinatorial mathematics and a discussion of the computer program which generates it, look here.
ENJOY KRYPTO WITH OR WITHOUT YOUR STUDENTS!!
Posted by Dave Marain at 6:16 AM 14 comments
Labels: carnival of mathematics, games, more, SAT strategies, update
Sunday, December 14, 2008
Teaching Probabilities and Strategies Via Games!
NCTM Teaching Standards:
Target Audience: Grades 7-12
Tools Needed: Graphing calculator with a random integer generator or an online random number generator (look here for example)
Classroom Organization
(After demo mode): Students working in groups of 3 (two opponents, the 3rd calls out the numbers and keeps score; roles are rotated)
Sample Classroom Scenario
Who thinks they can beat me at a game of chance? I will demo the game, then I will play against an opponent. If you beat me two out of three, you are the new champ and you can pick your opponent. After 10 minutes, you will be playing in small groups and recording the results.
The Play
Using a random integer generator we will generate random digits, one at a time, from 1 through 9, inclusive (no zeros). The object is to build a 5-digit integer which is greater than your opponent's by placing each 'called' digit into one of the five place-value positions. Once you place a digit you cannot change it!
Let's try it... Ok, Marissa, turn on the random integer generator, press Enter and call out the first integer. FOUR!
Ok, I'll place it here: ___ ___ 4 ___ ____
Call out the next integer: SIX!
I'll place it here: ___ 6 4 ___ ___
Next: TWO!
___ 6 4 ___ 2
Next: FOUR!
___ 6 4 4 2
Last digit! FIVE!
5 6 4 4 2
How did I do? Could I have used a better strategy? Do you think you could have beaten me?
Who wants to play! To win, you have to beat me two out of three. Ok, Dimitri, I will work on my paper and you work on yours. Remember, you cannot change a digit's position once you place it...
Brief Discussion of Strategy Based on Probability Arguments:
Suppose the first two digits called are 3 and 6 in that order. Would it be better to place the 6 in the thousands' place or the ten thousands' (leftmost) position? If you place the digits here:
___ 6 ___ 3 ___, what is the probability that at least one of the next three digits chosen will be 6,7,8, or 9. (Otherwise, your strategy would have backfired). To compute this, we look at the complementary condition, i.e., we determine the probability that the next 3 digits chosen will all be in the range 1 through 5. The probability of this is (5/9)(5/9)(5/9) or approximately 17%, so the probability that our strategy works is about 83%, odds that seem worth playing! Experienced game players often compute these probabilities mentally or have seen these situations so many times they know these probabilities by heart!
Notes
(1) Students may not know there is a Random Integer generator built into many graphing calculators. For example on the TI-84, press MATH, then PRB, then 5:randInt(.
From the home screen, Enter randInt(1,9), ENTER. Each time you press ENTER another "random" digit will be displayed. The person calling these out must be instructed to announce only ONE digit at a time!
(2) Why 5-digit numbers? This seems to make the game fairly interesting and moving at a good pace. Expect ties of course!
Perhaps this is a good activity before the holidays. Have fun and let me know how it goes!
Posted by Dave Marain at 9:32 AM 11 comments
Labels: discrete math, games, probability, winning strategies
Tuesday, February 12, 2008
[1,2]-3-[4,5]-6-[7,8]...21 Helping Children Devise and Understand Winning Strategies
Do you remember playing those fun counting games in elementary school? No, well, play along as if you do! The teacher or a friend would go first and always seem to win or you would go first and always lose. You knew there was a trick and if you figured it out it was exhilarating - like understanding the key to a magic trick.
Like most parlor games, there's genuine mathematics underlying these counting games. In this post we will describe a few of these and an investigation to help students not only devise a winning strategy (or algorithm) but to come to an understanding how division and remainders play a significant role.
Variation #1: The Game of '21'
Age Group: Certainly appropriate for children even as early as 1st grade (however, devising winning strategies and explaining why they work might be a bit ambitious!)
# of players: 2 is best
Object: To win, make your opponent say some target number like 21
Rules: First player starts counting from 1 and says either '1' or '1-2'; Other player then says the next number or the next two numbers; play continues in this way until someone is forced to say the number '21'. Verbal or written directions here are far more confusing than just demonstrating actual play.
Sample Play: See title of post for a partial play
Winning Strategy (partial): If you go first, say '1,2'. If you don't, your opponent can beat you if she/he knows the strategy.
Further Discussion: For the younger children, let them play against each other in pairs for a few minutes to allow them to feel comfortable with the game. Then you can ask if anyone wants to 'challenge the master' - you, that is! Tell them because you are older, you deserve the courtesy of going first (that will last for about 30 seconds or less!). After playing against students for a while, they will figure out that part of the winning strategy is to go first and say '1,2' but most will not pick up on the rest of the method. To mystify them even more, you can let them go first. You most likely will still win because you know the strategy and they will most likely not catch on for some time! There's always one sharp youngster even in the primary grades whose eyes will start glowing and will say, "Let me go first. I can beat you." At that point, you may want to say, "Game over!"
Winning Strategy: Those of you who are familiar with these kinds of counting games, know that they are all variations on the same basic theme and are simpler versions of the classic game, NIM. In this version of '21', some children will quickly see that, whoever gets to 2o has to win. It will take them a little longer to work backwards from there to see that to get to 20 you have to get to reach 17, which is 3 less than 20. To get to 17, you have to reach 14, which is 3 less than 17. Thus, working backwards, the winning positions, or 'magic numbers' if you will, are 20-17-14-11-8-5-2. Reversing this provides you with a guaranteed win but of course you need to go first and say '1,2'! But learning and using this strategy does not imply that the child understands WHY it works!
Using questions to help children begin to grasp the underlying idea: Children will immediately see why '20' is a winning position but ask them to explain why 17 also is (Possible student response: "Because if you say '17, then the other person can only get to 19 and you will be able to get to 20"). Continue to subtract 3 to obtain other 'magic numbers.' Ask the children why subtracting 3 is critical. Why 3? Children, even older ones, will soon see what is going on. Some may ask if one has to memorize all of these numbers. Don't answer that! Just smile and let them figure it out for themselves. Allow the children to practice the winning strategy on each other until they feel comfortable. They will surely want to try this out on other friends, teachers or family members!
Underlying Concept: At what grade level are children expected to grasp the essential idea that repeated subtraction is equivalent to division? Thus, in our problem, working backwards, starting from the winning position of 20 and continually subtracting 3, is equivalent to dividing 20 by 3:
20 ÷ 3 = 6 with a remainder of 2.
This can be interpreted to mean that after performing six subtractions by 3, the number 2 will remain! Of course, the repeated subtractions reveal all of the winning positions so children may not be appreciate the benefit of division. Help them to see that the remainder does reveal that one needs to go first and say '1,2' to guarantee a win.
A Million Variations
Well, maybe not that many in this post, but I'm sure you can see the possibilities are endless. You may want to ask children to devise their own version and a winning strategy as an outside project or assignment. They may invent something really cool no one has thought of! You might want to first ask the group how they could modify the game: "If you were going to invent your own game, what might you change about the game of 21?"
Some suggested variations:
(1) Whoever says '21' wins
(2) '21' loses but this time students can say the next number or the next two numbers or the next three numbers. Thus, if you go first and say '1,2,3', I would say '4'; then you might say '5,6' and I would say '7,8'. Am I guaranteed to win if I play correctly?
(3) Start from some number like 50 and allow children to subtract any number from the set {1,2,3,4,5,6}. Then you subtract one of these 6 numbers from the result and repeat play until one player reaches the number '1'. That player wins. This 'Game of 50' is also famous and will mystify adolescents as much as younger children! I'll let our readers explain the strategy and why it works! By the way, don't underestimate how much reinforcement of basic subtraction skill this game provides!
Posted by Dave Marain at 8:27 PM 4 comments
Labels: division algorithm, division concept, games, investigations, subtraction, winning strategies