Presentation is loading. Please wait.

Presentation is loading. Please wait.

CSE 321 Discrete Structures

Published byIrwan Kusumo Modified over 6 years ago

Similar presentations

Presentation on theme: "CSE 321 Discrete Structures"— Presentation transcript:

1 CSE 321 Discrete Structures
Winter 2008 Lecture 13 Induction and Recursion

2 Announcements Readings Midterm: Extra Office Hour
Monday Recursion 4.3 (5th Edition: 3.4) Midterm: Friday, February 8 In class, closed book Estimated grading weight: MT 12.5%, HW 50%, Final 37.5% Extra Office Hour Thursday, 5:30-6:20 pm, CSE 582 Homework 5 is available

3 Highlights from Lecture 12
Mathematical Induction P(0)  k (P(k)  P(k+1))   n P(n) Strong Induction  k ((P(0)  P(1)  …  P(k))  P(k+1))

4 Induction Example A set of S integers is non-divisible if there is no pair of integers a, b in S where a divides b. If there is a pair of integers a, b in S, where a divides b, then S is divisible. Given a set S of n+1 positive integers, none exceeding 2n, show that S is divisible. What is the largest subset non-divisible subset of {1, 2, 3, 4, 5, 6, 7, 8, 9, 10 }.

5 If S is a set of n+1 positive integers, none exceeding 2n, then S is divisible
Base case: n =1 Suppose the result holds for n If S is a set of n+1 positive integers, none exceeding 2n, then S is divisible Let T be a set of n+2 positive integers, none exceeding 2n+2. Suppose T is non-divisible.

6 Proof by contradiction
Claim: 2n+1  T and 2n + 2  T Claim: n+1  T Let T* = T – {2n+1, 2n+2}  {n+1} If T is non-divisible, T* is also non-divisible /

7 Recursive Definitions
F(0) = 0; F(n + 1) = F(n) + 1; F(0) = 1; F(n + 1) = 2  F(n); F(0) = 1; F(n + 1) = 2F(n)

8 Fibonacci Numbers f0 = 0; f1 = 1; fn = fn-1 + fn-2

9 Bounding the Fibonacci Numbers
Theorem: 2n/2  fn  2n for n  6

10 Recursive Definitions of Sets
Basis step: 0  S Recursive step: if x  S, then x + 2  S Exclusion rule: Every element in S follows from basis steps and a finite number of recursive steps

11 Recursive definitions of sets
Basis: 6  S; 15  S; Recursive: if x, y  S, then x + y  S; Basis: [1, 1, 0]  S, [0, 1, 1]  S; Recursive: if [x, y, z]  S,  in R, then [ x,  y,  z]  S if [x1, y1, z1], [x2, y2, z2]  S then [x1 + x2, y1 + y2, z1 + z2] Powers of 3

12 Strings The set * of strings over the alphabet  is defined
Basis:   S ( is the empty string) Recursive: if w  *, x  , then wx  *

13 Function definitions Len() = 0;
Len(wx) = 1 + Len(w); for w  *, x   Concat(w, ) = w for w  * Concat(w1,w2x) = Concat(w1,w2)x for w1, w2 in *, x  

Download ppt "CSE 321 Discrete Structures"

Similar presentations

22C:19 Discrete Structures Induction and Recursion Spring 2014 Sukumar Ghosh.

22C:19 Discrete Structures Induction and Recursion Spring 2014 Sukumar Ghosh.
Discrete Mathematics Math 6A Homework 9 Solution.

Discrete Mathematics Math 6A Homework 9 Solution.
Recursive Definitions and Structural Induction

Recursive Definitions and Structural Induction
CSE 20 DISCRETE MATH Prof. Shachar Lovett Clicker frequency: CA.

CSE 20 DISCRETE MATH Prof. Shachar Lovett Clicker frequency: CA.
Induction and recursion

Induction and recursion
CSE115/ENGR160 Discrete Mathematics 04/03/12 Ming-Hsuan Yang UC Merced 1.

CSE115/ENGR160 Discrete Mathematics 04/03/12 Ming-Hsuan Yang UC Merced 1.
CSE 321 Discrete Structures Winter 2008 Lecture 12 Induction.

CSE 321 Discrete Structures Winter 2008 Lecture 12 Induction.
CSE115/ENGR160 Discrete Mathematics 03/31/11

CSE115/ENGR160 Discrete Mathematics 03/31/11
Lecture 13 3.4 Recursive Definitions. Fractals fractals are examples of images where the same elements is being recursively.

Lecture Recursive Definitions. Fractals fractals are examples of images where the same elements is being recursively.
Module #1 - Logic 1 Based on Rosen, Discrete Mathematics & Its Applications. Prepared by (c)2001-2004, Michael P. Frank. Modified By Mingwu Chen Induction.

Module #1 - Logic 1 Based on Rosen, Discrete Mathematics & Its Applications. Prepared by (c) , Michael P. Frank. Modified By Mingwu Chen Induction.
1 Section 3.4 Recursive Definitions. 2 Recursion Recursion is the process of defining an object in terms of itself Technique can be used to define sequences,

1 Section 3.4 Recursive Definitions. 2 Recursion Recursion is the process of defining an object in terms of itself Technique can be used to define sequences,
CSE115/ENGR160 Discrete Mathematics 03/29/11 Ming-Hsuan Yang UC Merced 1.

CSE115/ENGR160 Discrete Mathematics 03/29/11 Ming-Hsuan Yang UC Merced 1.
Induction and recursion

Induction and recursion
Chapter 6 Mathematical Induction

Chapter 6 Mathematical Induction
Discrete Mathematics, 1st Edition Kevin Ferland

Discrete Mathematics, 1st Edition Kevin Ferland
CSE 20 Lecture 12 Induction CK Cheng 1. Induction Outlines Introduction Theorem Examples: The complexity calculation – Tower of Hanoi – Merge Sort – Fibonacci.

CSE 20 Lecture 12 Induction CK Cheng 1. Induction Outlines Introduction Theorem Examples: The complexity calculation – Tower of Hanoi – Merge Sort – Fibonacci.
Mathematical Induction. F(1) = 1; F(n+1) = F(n) + (2n+1) for n≥1 100816449362516941 10987654321 F(n) n F(n) =n 2 for all n ≥ 1 Prove it!

Mathematical Induction. F(1) = 1; F(n+1) = F(n) + (2n+1) for n≥ F(n) n F(n) =n 2 for all n ≥ 1 Prove it!
Discrete Mathematics and Its Applications Sixth Edition By Kenneth Rosen Chapter 4 Induction and Recursion 歐亞書局.

Discrete Mathematics and Its Applications Sixth Edition By Kenneth Rosen Chapter 4 Induction and Recursion 歐亞書局.
CSE 20: Discrete Mathematics for Computer Science Prof. Shachar Lovett.

CSE 20: Discrete Mathematics for Computer Science Prof. Shachar Lovett.
CSE 311 Foundations of Computing I Lecture 15 Recursive Definitions and Structural Induction Autumn 2011 CSE 3111.

CSE 311 Foundations of Computing I Lecture 15 Recursive Definitions and Structural Induction Autumn 2011 CSE 3111.

Similar presentations

Ads by Google