Discrete Math: Master Discrete Mathematics
Similar coupons:
Welcome to this Discrete Math course.
Discrete Mathematics is the math of distinct, countable objects (like integers or steps) rather than continuous, smooth lines (like calculus). It is the backbone of modern technology. It provides the core rules and logic required for programming, digital networks, computer security, and data analysis. In this course, you will be learning the core of Discrete Mathematics, namely:
1. "Set Theory (Sets), Relations and Functions" - Sets, Relations and Functions form an integral part of Discrete Math. Many important fields like Computer Science,Actuarial Science, Data Science, Artificial Intelligence (AI) and many more use Set Theory, Relations and Functions. They are considered to be the base from where all the other branches of mathematics are derived.
2. " Discrete Mathematical Induction (MI)" - Mathematical Induction plays a very important role in Computer Programming and Algorithm Correctness Proofs. Usually coders have to write a program codeand then a correctness proof to prove the validity that the program will run fine for all cases. Mathematical Induction plays a very important role there. Mathematical Induction is also an indispensable tool for Mathematicians. Mathematicians use induction to conclude the truthfulness of infinitely many Mathematical Statements and Algorithms.
This Discrete Math course will not only help you master the core concepts of Set Theory, Relations, Functions, and Discrete Mathematical Induction, but will also make you confident in applying them practically. After completing this Discrete Mathematics course, you will be able to:
define aSETand represent the same in different forms; (Set Theory)
define different types of sets such as, finite and infinite sets, empty set, singleton set, equivalent sets, equal sets, sub sets, proper subsets, supersets, give examples of each kind of set, and solve problems based on them; (Set Theory)
define union and intersection of two sets, and solve problems based on them; (Set Theory)
define universal set, complement of a set, difference between two sets, and solve problems based on them; (Set Theory)
define Cartesian product of two sets, and solve problems based on them; (Set Theory)
represent union and intersection of two sets, universal sets, complement of a set, difference between two sets by Venn Diagram; (Set Theory)
solve problems based on Venn Diagram; (Set Theory)
defineRELATIONand quote examples of relations; (Relations)
find the domain and range of a relation; (Relations)
represent relations diagrammatically; (Relations)
define different types of relations such as, empty relation, universal relation, identity relation, inverse relation, reflexive relation, symmetric relation, transitive relation, equivalence relation, and solve problems based on them; (Relations)
defineFUNCTIONand give examples of functions; (Functions)
find the domain, codomain and range of a function; (Functions)
define the different types of functions such as injective function (one-to-one function), surjective function (onto function), bijective function, give examples of each kind of function, and solve problems based on them; (Functions)
define and give examples of even and odd functions; (Functions)
figure out if any given function is even, odd, or neither from graphs as well as equations; (Functions)
define composition of two functions; (Functions)
find the composition of functions; (Functions)
define the inverse of a function; (Functions)
find the inverse of any given function; (Functions)
find the domain and range of the inverse function; (Functions)
define ThePrinciple ofDISCRETEMATHEMATICALINDUCTIONand use it for Proving Mathematical Statements; (Mathematical Induction)
Mathematical Induction for"Proving the Sum of an Arithmetic Progression"; (Mathematical Induction)
Mathematical Induction for"Proving the Sum of squares of first n natural numbers"; (Mathematical Induction)
Mathematical Induction in"Proving the Divisibility"; (Mathematical Induction)
Mathematical Induction in"Proving the Inequality"; (Mathematical Induction)
Mathematical Induction for "Proving the Sum of a Geometric Progression"; (Mathematical Induction)
Mathematical Induction ina"Brain Teasing Real World Problem"; (Mathematical Induction)
Mathematical Induction for"Proving a result from Geometry"; (Mathematical Induction)
Mathematical Induction in "The Towers of Hanoi"; (Mathematical Induction) and
Learn to use Mathematical Induction to do Computer Program/Algorithm Correctness proofs. (Mathematical Induction)
We recommend this Discrete Math course to everyone who is a Mathor a Computer Science student, or any Working Professional in the field of Computer Science, Data Science, Artificial Intelligence (AI), Computer Programming and Algorithms, Quantum Computing, or any other area which involves programming, data analysis, computer security and digital networks.
Basic knowledge of Pre Calculus will be good to have but not a strict mandatory requirement.
You can also join my other course on Udemy which teaches Pre Calculus, Trigonometry and Calculus Foundations in a single 9 hour course if you wish to learn or revise those areas alongside; OR you can also join both of my courses as a Bundle from the Bundle buying option you can find below by scrolling down on this page.
Master Discrete Mathematics as Discrete Math forms the core of Computer Science, Data Science, Algorithms, AI, Quantum Computing and More.
Master Set Theory - Learn Sets, Types of Sets, Set Operations, Venn Diagrams and more; Master Relations - Learn about Relations, Types of Relations and more
Master Functions - Learn Functions, Types of Functions and more; Master Mathematical Induction - Learn Principle of Mathematical Induction, Live Proofs and more
By the end of this course, you will be able to define a set and represent the same in different forms;
define different types of sets such as finite & infinite set, empty set, singleton set, equivalent sets, equal sets, sub sets, proper subsets, supersets;
define union and intersection of two sets, and solve problems based on them;
define universal set, complement of a set, difference between two sets, and solve problems based on them;
define Cartesian product of two sets, and solve problems based on them;
represent union and intersection of two sets, universal sets, complement of a set, difference between two sets by Venn Diagram;
solve problems based on Venn Diagram;
define relation and quote examples of relations;
find the domain and range of a relation;
represent relations diagrammatically;
define different types of relations such as empty relation, singleton, identity relations, inverse, reflexive, symmetric, transitive & equivalence relations;
define function and give examples of functions;
find the domain, codomain and range of a function;
define the different types of functions such as injective function (one-to-one function), surjective function (onto function) & bijective function;
define and give examples of even and odd functions;
figure out if any given function is even, odd, or neither from graphs as well as equations;
define composition of two functions;
find the composition of functions;
define the inverse of a function;
find the inverse of any given function;
find the domain and range of the inverse function;
Understand the concept of Mathematical Induction and the logic behind it;
Learn to prove statements using Mathematical Induction;
Learn to apply Mathematical Induction in a Brain Teasing Real World Problem;
Understand the application of Mathematical Induction in Computer Program/Algorithm Correctness Proofs;
Learn to apply Mathematical Induction for proving a Result from Geometry;
Learn to apply Mathematical Induction for proving the Divisibilities;
Learn to apply Mathematical Induction for proving the sum of Arithmetic Progressions;
Learn to apply Mathematical Induction for proving the the Sum of squares of first n natural numbers;
Learn to apply Mathematical Induction for proving the Inequalities;
Learn to apply Mathematical Induction for proving the sum of Geometric Progressions.
Math Students
Computer Programmers and Computer Science Students
Engineering Students
Working Professionals in the fields of Computer Science, AI, Data Science, Quantum Computing, or any other areas which involve programming, data analysis, computer security and digital networks.
