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Lecture 13 Elements of Probability

Lecture 13 Elements of Probability. CSCI – 1900 Mathematics for Computer Science Spring 2014 Bill Pine. Lecture Introduction. Reading Kolman – Section 3.3, 3.4 Sample spaces Events Probability Pigeonhole principle. Sample Space.

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Lecture 13 Elements of Probability

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  1. Lecture 13Elements of Probability CSCI – 1900 Mathematics for Computer Science Spring 2014 Bill Pine

  2. Lecture Introduction • Reading • Kolman – Section 3.3, 3.4 • Sample spaces • Events • Probability • Pigeonhole principle CSCI 1900

  3. Sample Space • Sample Space - the set containing all possible outcomes of an experiment • Examples: • Experiment: Flip a coin, record Heads or Tails. • Sample Space: O={H, T} • Experiment: Flip a coin twice • Sample Space: O={HH, HT, TH, TT} CSCI 1900

  4. Sample Space (cont) • Examples (cont) • Experiment: Roll two dices, each die has 1-6 spots • O={ (1,1), (1,2), (1,3), (1,4), (1,5), (1,6), (2,1), (2,2), (2,3), (2,4), (2,5), (2,6), (3,1), (3,2), (3,3), (3,4), (3,5), (3,6), (4,1), (4,2), (4,3), (4,4), (4,5), (4,6), (5,1), (5,2), (5,3), (5,4), (5,5), (5,6), (6,1), (6,2), (6,3), (6,4), (6,5), (6,6) } • The number of ways of rolling a particular total may be found on a diagonal (e.g. ways to roll a total of 6 is highlighted) CSCI 1900

  5. Event • A statement about a particular outcome of an experiment is an event • A subset of the sample space • The total of the spots on two die is 6 • E={ (5,1) , (4,2), (3,3), (2,4), (1,5)} CSCI 1900

  6. Events (cont) • Example: Consider the experiment of tossing a die and recording the outcome of the top face • O={1, 2, 3, 4, 5, 6} (The universal set) • Let E be the event that the number of spots is even • E={2, 4, 6} • Let F be the event the number of spots is prime • F={2, 3, 5} • E  F ={2, 3, 4, 5, 6} ( Event: number of spots is even or prime) • E  F ={2} (Event: the number of spots is even and prime) • E = {1, 3, 5} (Event: the number of spots is not even) CSCI 1900

  7. Events (cont) • Recall : • If E  F= Ø, then E and F are disjoint • Also called mutually exclusive • This means at most one can occur at a time CSCI 1900

  8. Probability • Each event can be assigned a number, p(E) called the probability of event E • If all outcomes are equally likely to occur, then p(E) = |E| / |O| • Example. O={H,T} for flipping a coin • Let E={ Event: coin turned up heads}={H} • |E| = 1 |O| = 2 • p(E)=|E| / |O|=1/2 CSCI 1900

  9. Probability (cont) • Example. Rolling two fair dice • For O see slide 4 • Let E= {Event: number of spots add to 6} • E = { (1,5), (2,4), (3,3), (4,2), (5,1) } • |E| = 5 • p(E)=|E| / |O| • p(E)= 5/36 CSCI 1900

  10. Probability (cont) • Sometimes outcomes are not equally likely • Consider the following “unfair” die • Let O = {1, 2, 3, 4, 5, 6} • p1 = 1/12 • p2 = 1/12 • p3 = 1/3 • p4 = 1/6 • p5 = 1/4 • p6 = 1/12 • p (even number) = 1/12 + 1/6 + 1/12 = 4/12 = 1/3 • p(odd number) = 1/12 + 1/3 + 1/4 = 8/12 = 2/3 CSCI 1900

  11. Properties of Probabilities • Property 1: 0 <= p(E) <= 1 • Property 2: p(O)=1 and p(Ø)=0 • Property 3: p(EF)=p(E)+p(F) - p(EF) If E and F are disjoint, then p(EF)=p(E)+p(F) • Property 4: The probability that an event E will not happen 1 - p(E) • Property 5: If E and F are independent, thenp(EF) = p(E)*p(F) CSCI 1900

  12. Example • A box contains six red balls and four green balls. Four balls are selected at random. What is the probability that two of the selected balls are red and the other two green? • Choose two red from 6 • Choose two green from 4 • |O|= 10 C 4 = 210 • |E|= 6 C 2 * 4 C 2 = 15*6 =90 • P(E)= 90/210 = 3/7 CSCI 1900

  13. Example • A few poker hands • Total possible hands = 52C5 = 2,598,960 • Royal Flush  4 possible handsOdds are 4 in 2,598,960  1 in 649,740 • Straight Flush  40 possible handsOdds are 40 in 2,598,960  1 in 64,974 • Four Aces  48 possible handsOdds are 48 in 2,598,960  1 in 54,145 CSCI 1900

  14. Example (cont) • What is the probability that a hand of five cards from a standard deck contains four cards of one kind? • Pick the type of kind (2,3,…A) 13 C 1 = 13 • Pick the four of that kind 4 C 4 = 1 • Pick 1 of the 48 remaining 48 C 1= 48 • |E| = 13*1*48, the number of 5 card hands having 4 of a kind • P(E) = |E|/|U| = 624/ 2,598,960  .00024 CSCI 1900

  15. Pigeonhole Principle • Reading • Kolman – Section 3.3 • If you put n Pigeons in k Holes and n > k then at least one hole will have more than one pigeon in it • Everybody has to be somewhere CSCI 1900

  16. Example • If there are 8 people in a room at least two of them must have been born on the same day of the week … • The people are the pigeons • The days of the week are the pigeonholes CSCI 1900

  17. Using the Pigeonhole Principle • If we are putting 27 files on 26 flash drives, at least one drive will have 2 or more files • Identify the pigeons and the pigeonholes • The drives are the pigeonholes The files are the pigeons • We have 26 holes and 27 pigeons • Therefore by the pigeonhole principle at least one disk must have more than 1 file on it CSCI 1900

  18. Extended Pigeonhole Principle • If you put 2K + I People on K Starships then at least one Starship will have more than two people on it • You can extend this with 3K + I, 4K + I and so on • This is just an application of the Remainder Theorem CSCI 1900

  19. Using the Extended Principle • If we have 433 problems are to be done by 20 students show that at least one student must do more than 21 problems • Identify the pigeons and the pigeonholes • The students are the pigeonholes The problems are the pigeons • Apply the Remainder Theorem • 433 = 21 * 20 + 13 • Therefore K = 21 I=13 CSCI 1900

  20. Key Concepts Summary • Sample spaces • Events • Probability • Pigeonhole principle CSCI 1900

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