Presentation is loading. Please wait.

Presentation is loading. Please wait.

Divide-and-Conquer 7 2  9 4   2   4   7

Published byShanon Norton Modified over 6 years ago

Similar presentations

Presentation on theme: "Divide-and-Conquer 7 2  9 4   2   4   7"— Presentation transcript:

1 Divide-and-Conquer 7 2  9 4  2 4 7 9 7  2  2 7 9  4  4 9 7  7
Merge Sort 12/9/2018 8:09 AM Divide-and-Conquer 7 2   7  2  2 7 9  4  4 9 7  7 2  2 9  9 4  4 Divide-and-Conquer

2 Outline and Reading Divide-and-conquer paradigm (§5.2)
Review Merge-sort (§4.1.1) Recurrence Equations (§5.2.1) Iterative substitution Recursion trees Guess-and-test The master method Integer Multiplication (§5.2.2) Divide-and-Conquer

3 Divide-and-Conquer Divide-and conquer is a general algorithm design paradigm: Divide: divide the input data S in two or more disjoint subsets S1, S2, … Recur: solve the subproblems recursively Conquer: combine the solutions for S1, S2, …, into a solution for S The base case for the recursion are subproblems of constant size Analysis can be done using recurrence equations Divide-and-Conquer

4 Merge-Sort Review Merge-sort on an input sequence S with n elements consists of three steps: Divide: partition S into two sequences S1 and S2 of about n/2 elements each Recur: recursively sort S1 and S2 Conquer: merge S1 and S2 into a unique sorted sequence Algorithm mergeSort(S, C) Input sequence S with n elements, comparator C Output sequence S sorted according to C if S.size() > 1 (S1, S2)  partition(S, n/2) mergeSort(S1, C) mergeSort(S2, C) S  merge(S1, S2) Divide-and-Conquer

5 Recurrence Equation Analysis
The conquer step of merge-sort consists of merging two sorted sequences, each with n/2 elements and implemented by means of a doubly linked list, takes at most bn steps, for some constant b. Likewise, the basis case (n < 2) will take at b most steps. Therefore, if we let T(n) denote the running time of merge-sort: We can therefore analyze the running time of merge-sort by finding a closed form solution to the above equation. That is, a solution that has T(n) only on the left-hand side. Divide-and-Conquer

6 Iterative Substitution
In the iterative substitution, or “plug-and-chug,” technique, we iteratively apply the recurrence equation to itself and see if we can find a pattern: Note that base, T(n)=b, case occurs when 2i=n. That is, i = log n. So, Thus, T(n) is O(n log n). Divide-and-Conquer

7 (last level plus all previous levels)
The Recursion Tree Draw the recursion tree for the recurrence relation and look for a pattern: time bn depth T’s size 1 n 2 n/2 i 2i n/2i Total time = bn + bn log n (last level plus all previous levels) Divide-and-Conquer

8 Guess-and-Test Method
In the guess-and-test method, we guess a closed form solution and then try to prove it is true by induction: Guess: T(n) < cn log n. Wrong: we cannot make this last line be less than cn log n Divide-and-Conquer

9 Guess-and-Test Method, Part 2
Recall the recurrence equation: Guess #2: T(n) < cn log2 n. if c > b. So, T(n) is O(n log2 n). In general, to use this method, you need to have a good guess and you need to be good at induction proofs. Divide-and-Conquer

10 Master Method Many divide-and-conquer recurrence equations have the form: The Master Theorem: Divide-and-Conquer

11 Solution: logba=2, so case 1 says T(n) is O(n2).
Master Method, Example 1 The form: The Master Theorem: Example: Solution: logba=2, so case 1 says T(n) is O(n2). Divide-and-Conquer

12 Solution: logba=1, so case 2 says T(n) is O(n log2 n).
Master Method, Example 2 The form: The Master Theorem: Example: Solution: logba=1, so case 2 says T(n) is O(n log2 n). Divide-and-Conquer

13 Solution: logba=0, so case 3 says T(n) is O(n log n).
Master Method, Example 3 The form: The Master Theorem: Example: Solution: logba=0, so case 3 says T(n) is O(n log n). Divide-and-Conquer

14 Solution: logba=3, so case 1 says T(n) is O(n3).
Master Method, Example 4 The form: The Master Theorem: Example: Solution: logba=3, so case 1 says T(n) is O(n3). Divide-and-Conquer

15 Solution: logba=2, so case 3 says T(n) is O(n3).
Master Method, Example 5 The form: The Master Theorem: Example: Solution: logba=2, so case 3 says T(n) is O(n3). Divide-and-Conquer

16 Solution: logba=0, so case 2 says T(n) is O(log n).
Master Method, Example 6 The form: The Master Theorem: Example: (binary search) Solution: logba=0, so case 2 says T(n) is O(log n). Divide-and-Conquer

17 Solution: logba=1, so case 1 says T(n) is O(n).
Master Method, Example 7 The form: The Master Theorem: Example: (heap construction) Solution: logba=1, so case 1 says T(n) is O(n). Divide-and-Conquer

18 Iterative “Proof” of the Master Theorem
Using iterative substitution, let us see if we can find a pattern: We then distinguish the three cases as The first term is dominant Each part of the summation is equally dominant The summation is a geometric series Divide-and-Conquer

19 Integer Multiplication
Algorithm: Multiply two n-bit integers I and J. Divide step: Split I and J into high-order and low-order bits We can then define I*J by multiplying the parts and adding: So, T(n) = 4T(n/2) + n, which implies T(n) is O(n2). But that is no better than the algorithm we learned in grade school. Divide-and-Conquer

20 An Improved Integer Multiplication Algorithm
Algorithm: Multiply two n-bit integers I and J. Divide step: Split I and J into high-order and low-order bits Observe that there is a different way to multiply parts: So, T(n) = 3T(n/2) + n, which implies T(n) is O(nlog23), by the Master Theorem. Thus, T(n) is O(n1.585). Divide-and-Conquer

Download ppt "Divide-and-Conquer 7 2  9 4   2   4   7"

Similar presentations

Divide-and-Conquer 7 2  9 4   2   4   7

Divide-and-Conquer 7 2  9 4   2   4   7
AVL Trees1 Part-F2 AVL Trees 6 3 8 4 v z. AVL Trees2 AVL Tree Definition (§ 9.2) AVL trees are balanced. An AVL Tree is a binary search tree such that.

AVL Trees1 Part-F2 AVL Trees v z. AVL Trees2 AVL Tree Definition (§ 9.2) AVL trees are balanced. An AVL Tree is a binary search tree such that.
A simple example finding the maximum of a set S of n numbers.

A simple example finding the maximum of a set S of n numbers.
Data Structures Lecture 9 Fang Yu Department of Management Information Systems National Chengchi University Fall 2010.

Data Structures Lecture 9 Fang Yu Department of Management Information Systems National Chengchi University Fall 2010.
5/5/20151 Analysis of Algorithms Lecture 6&7: Master theorem and substitution method.

5/5/20151 Analysis of Algorithms Lecture 6&7: Master theorem and substitution method.
September 12, 20021 Algorithms and Data Structures Lecture III Simonas Šaltenis Nykredit Center for Database Research Aalborg University

September 12, Algorithms and Data Structures Lecture III Simonas Šaltenis Nykredit Center for Database Research Aalborg University
Divide-and-Conquer Recursive in structure –Divide the problem into several smaller sub-problems that are similar to the original but smaller in size –Conquer.

Divide-and-Conquer Recursive in structure –Divide the problem into several smaller sub-problems that are similar to the original but smaller in size –Conquer.
1 Divide-and-Conquer CSC401 – Analysis of Algorithms Lecture Notes 11 Divide-and-Conquer Objectives: Introduce the Divide-and-conquer paradigm Review the.

1 Divide-and-Conquer CSC401 – Analysis of Algorithms Lecture Notes 11 Divide-and-Conquer Objectives: Introduce the Divide-and-conquer paradigm Review the.
Merge Sort1 Part-G1 Merge Sort 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4.

Merge Sort1 Part-G1 Merge Sort 7 2  9 4   2  2 79  4   72  29  94  4.
Merge Sort1 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4.

Merge Sort1 7 2  9 4   2  2 79  4   72  29  94  4.
Divide-and-Conquer1 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4.

Divide-and-Conquer1 7 2  9 4   2  2 79  4   72  29  94  4.
Divide-and-Conquer1 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4.

Divide-and-Conquer1 7 2  9 4   2  2 79  4   72  29  94  4.
Data Structures, Spring 2004 © L. Joskowicz 1 Data Structures – LECTURE 3 Recurrence equations Formulating recurrence equations Solving recurrence equations.

Data Structures, Spring 2004 © L. Joskowicz 1 Data Structures – LECTURE 3 Recurrence equations Formulating recurrence equations Solving recurrence equations.
Data Structures, Spring 2006 © L. Joskowicz 1 Data Structures – LECTURE 3 Recurrence equations Formulating recurrence equations Solving recurrence equations.

Data Structures, Spring 2006 © L. Joskowicz 1 Data Structures – LECTURE 3 Recurrence equations Formulating recurrence equations Solving recurrence equations.
Analysis of Recursive Algorithms

Analysis of Recursive Algorithms
Divide-and-Conquer1 7 2  9 4  2 4 7 9 7  2  2 79  4  4 9 7  72  29  94  4 Modified by: Daniel Gomez-Prado, University of Massachusetts Amherst.

Divide-and-Conquer1 7 2  9 4   2  2 79  4   72  29  94  4 Modified by: Daniel Gomez-Prado, University of Massachusetts Amherst.
CS 104 Introduction to Computer Science and Graphics Problems Data Structure & Algorithms (3) Recurrence Relation 11/11 ~ 11/14/2008 Yang Song.

CS 104 Introduction to Computer Science and Graphics Problems Data Structure & Algorithms (3) Recurrence Relation 11/11 ~ 11/14/2008 Yang Song.
Updates HW#1 has been delayed until next MONDAY. There were two errors in the assignment. 2-1. Merge sort runs in Θ(n log n). Insertion sort runs in Θ(n2).

Updates HW#1 has been delayed until next MONDAY. There were two errors in the assignment Merge sort runs in Θ(n log n). Insertion sort runs in Θ(n2).
Recurrences The expression: is a recurrence. –Recurrence: an equation that describes a function in terms of its value on smaller functions Analysis of.

Recurrences The expression: is a recurrence. –Recurrence: an equation that describes a function in terms of its value on smaller functions Analysis of.
CSE 421 Algorithms Richard Anderson Lecture 11 Recurrences.

CSE 421 Algorithms Richard Anderson Lecture 11 Recurrences.

Similar presentations

Ads by Google