Exam 3 (Open Notes) on Dec. 5th: Module 5 (Dijkstra Shortest Path algorithm and Floyd-Warshall All Pairs Shortest Paths algorithm) and Module 6 (entire module) from 9 AM to 10.50 AM at ENB 212
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Syllabus
Lecture Slides
Question Bank
Project Descriptions
Quizzes and Exams
Code Tutorial
Dr. Meg’s Desktop Selected Lecture Videos
Quiz, Exam and Project Schedules
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Syllabus
Lecture Slides
Module 1: Algorithm Efficiency Analysis
Module 6: P, NP, NP-Complete Problems
Question Bank
QB Module 1: Algorithm Efficiency Analysis
QB Module 2 – Classical Design Techniques
QB Module 4 – Dynamic Programming
QB Module 5 – Graph Theory Algorithms
Project Descriptions
Project 1 (Bubble Sort vs. Insertion Sort): Due on Sept 21
Project 2 (Element Uniqueness Problem): Due on Oct. 5
Project 3 (Recursive Algorithm to Find the Minimum Integer in an Array): Due on Oct. 12
Project 5 (Binary Search Algorithm to Search for a Value with a Certain Precision): Due on Nov. 2
Project 8 (Breadth First Search Algorithm): Due on Nov. 30
Quizzes and Exams
Quiz 3 (Take Home: Due on Oct. 17, in-class)
Quiz 4 (Take Home: Due on Oct. 24, in-class)
Quiz 5 (Take Home: Due on Oct. 31, in-class)
Quiz 6 (Take Home: Due on Nov. 7, in-class)
Code Tutorial
Dr. Meg’s Desktop Selected Lecture Videos (YouTube Links)
Module 1: Analyzing the Efficiency of Algorithms
Time-Complexity analysis of a recursive algorithm to compute the factorial of an integer
Example for solving recurrence relations
Time-complexity analysis of an iterative algorithm to determine whether an array has unique elements
Decrease and Conquer – Insertion Sort Algorithm and Examples
Module 2: Classical Algorithm Design Techniuqes
Brute Force Algorithms QB – String Matching Problems
Divide and Conquer – Theorem-Proof: In order Traversal of a Binary Search Tree
Divide and Conquer – Master Theorem
Binary Search Algorithm and Examples
Comparison of Bottom-up and Top-down Approaches for Heap Construction
Transform and Conquer – Proof for Euclid’s GCD Formula
Transform and Conquer – Heap Sort
Space-Time Tradeoffs for the Sorting Algorithms (Merge, Insertion and Heap Sorts)
Module 3: Greedy Technique
Greedy Technique – Fractional Knapsack Problem
Greedy Technique – Huffman Codes (Variable Length Prefix-free Encoding)
Module 4: Dynamic Programming
Dynamic Programming: Coin-row Problem Discussion and Example
Dynamic Programming: Binomial Coefficient
Dynamic Programming Solution for the Coin Collecting Problem in a Two-Dimensional Grid
Dynamic Programming: Integer Knapsack Problem (0-1 Knapsack Problem)
Module 5: Graph Theory Algorithms
Depth First Search on Directed Graph
Depth First Search and Articulation Points
Breadth First Search and 2-Colorability of Graphs
Topological Sort on DAGs and Proof for Neccessary and Sufficient Condition
Dijkstra’s Algorithm for Shortest Path Trees and Proof for Correctness
Bellman-Ford Algorithm for Shortest Path Trees and Examples New!!
Kruskal’s Algorithm: Examples to find Minimum Spanning Trees
Kruskal’s Algorithm: Proof of Correctness
Properties (1 and 2) of Minimum Spanning Tree: IJ-Cut and Minimum Weight Edge
Prim’s Algorithm for Minimum Spanning Trees and Proof for Correctness
Floyd’s All Pairs Shortest Paths Algorithm
Part 1 Part 2 Part 3 Part 4 Part 5 Part 6 Part 7
Module 6: P, NP and NP-Complete Problems
Polynomial Reduction: Hamiltonian Circuit to Traveling Salesman Problem
Polynomial Reductions: Independent Set, Clique and Vertex Cover
Multi-fragment Heuristic for the Traveling Salesman Problem
Quiz, Exam and Project Schedules