Mastering Engineering Mechanics: Complete Dynamics

Become a Pro at Kinematics / Kinetics of Particles and Rigid Bodies

What you'll learn

Analyze various types of motion, including linear, curvilinear, and projectile motion, through clear and concise explanations.

Gain a deep comprehension of Newton's Laws of Motion and D'Alembert's Principle

Learn to connect the dots between work, energy, and power. Understanding of how forces interact within a system.

Build proficiency in using the Impulse-Momentum Theorem to understand and solve problems involving collisions and impulsive forces

Requirements

1. A Passion for Physics: If you’ve ever stared at a falling apple and wondered, “Hmm, what’s the gravitational acceleration here?”—you’re already halfway there!

2. Basic Math Skills: Fear not, my friend! We won’t be solving differential equations while riding unicycles. But a solid grasp of algebra and trigonometry will keep you from getting lost in the mathematical Bermuda Triangle.

And there you have it! If you meet these requirements, congratulations—you’re ready to join the ranks of the mechanically enlightened!

Description

Welcome to "Mastering Engineering Mechanics: Complete DYNAMICS," the ultimate guide to mastering the principles of dynamics in engineering mechanics. Whether you're a student aiming to excel in your exams or a teacher looking to deepen your understanding, this course is designed to take you on a comprehensive journey through the key concepts of dynamics.In this course, you'll explore:1. Kinematics of Linear Motion: Dive into the fundamentals of linear motion, learning to describe and analyze motion along a straight path using position, velocity, and acceleration.2. Kinematics of Curvilinear Motion: Understand the complexities of motion along curved paths. We’ll break down the principles that govern the movement of objects in two and three dimensions, making it simple and intuitive.3. Kinematics of Projectile Motion: Master the fascinating world of projectile motion, where you'll learn to predict the trajectory of objects moving under the influence of gravity.4. Kinetics of Particles using Newton's Laws of Motion and D'Alembert's Principle: Gain a solid grasp of how forces affect the motion of particles. You’ll delve into Newton’s Laws and explore the powerful D'Alembert's Principle to solve real-world engineering problems.5. Work, Power, and Energy: Explore the relationships between work, energy, and power. We’ll guide you through concepts like kinetic and potential energy, and how they relate to the forces at play in a system.6. Impulse Momentum Theorem and Collisions: Understand how momentum and impulse govern the interactions between bodies. This section will equip you with the tools to analyze and solve problems involving collisions and other impulsive forces.This course is meticulously crafted to provide you with clear explanations, practical examples, and engaging problem-solving techniques. Whether you’re a beginner or someone looking to refresh your knowledge, "Mastering Engineering Mechanics: Complete DYNAMICS" will give you the confidence and skills to tackle dynamics problems with ease.Enroll today and take the first step towards mastering the essential concepts of engineering mechanics that form the foundation of many advanced fields in engineering!

Overview

Section 1: Kinematics of Linear Motion

Lecture 1 Enter the World of DYNAMICS: Rest Vs Motion

Lecture 2 Position Vs Displacement

Lecture 3 What is Average Velocity really ?

Lecture 4 Mystery of Instantaneous Velocity decoded

Lecture 5 Understanding Acceleration

Lecture 6 Example 1 on Particle's Position, Velocity and Acceleration

Lecture 7 Example 2 on Particle's Position, Velocity and Acceleration

Lecture 8 Example 1 on Uniformly Accelerating Motion

Lecture 9 Example 2 on Uniformly Accelerating Motion

Lecture 10 Example 3 on Uniformly Accelerating Motion

Lecture 11 Example 4 on Uniformly Accelerating Motion

Lecture 12 Example 1 on Motion under Gravity

Lecture 13 Example 2 on Motion under Gravity

Lecture 14 Example 3 on Motion under Gravity

Lecture 15 Example 4 on Motion under Gravity

Section 2: Kinematics of Curvilinear Motion

Lecture 16 Introduction to Curvilinear Motion and Examples

Lecture 17 Curvilinear Motion: Distance and Displacement

Lecture 18 Curvilinear Motion: Average and Instantaneous Velocity

Lecture 19 Curvilinear Motion_Average and Instantaneous Acceleration

Lecture 20 Curvilinear Motion Analysis via Rectangular Coordinates

Lecture 21 Example 1 on CM by Rectangular Coordinates

Lecture 22 Example 2 on CM by Rectangular Coordinates

Lecture 23 Curvilinear Motion Analysis via Path Coordinates

Lecture 24 Example 1 on CM via Path Coordinates

Lecture 25 Example 2 on CM via Path Coordinates

Section 3: Kinematics of Projectile Motion

Lecture 26 Introduction to Projectile Motion

Lecture 27 Position of Projectile

Lecture 28 Equation of Trajectory

Lecture 29 Time of Flight

Lecture 30 Range

Lecture 31 Maximum Height

Lecture 32 Velocity at any position on the trajectory

Lecture 33 Example 1 on Projectile Motion

Lecture 34 Example 2 on Projectile Motion

Lecture 35 Example 3 on Projectile Motion

Lecture 36 Example 4 on Projectile Motion

Section 4: Kinetics of Particles_Newtons Laws and D Alemberts Principle

Lecture 37 Newtons 2nd Law of Motion

Lecture 38 D-Alembert's Principle

Lecture 39 Example 1 on Rectilinear Motion

Lecture 40 Example 2 on Rectilinear Motion

Lecture 41 Practice Problems on Rectilinear Motion

Lecture 42 Solutions to Problems on Rectilinear Motion

Lecture 43 Example 1 on Curvilinear Motion

Lecture 44 Example 2 on Curvilinear Motion

Section 5: Kinetics of Particles_Work Energy Principle

Lecture 47 What is WORK ?

Lecture 48 Mathematical Formula for Work

Lecture 49 Positive_Negative and Zero Work

Lecture 50 Graphical Analysis of Work

Lecture 51 Work Energy Theorem for Constant Force

Lecture 52 Work Energy Theorem for Variable Force

Lecture 53 Work Done by Force of Friction

Lecture 54 Work Done by Force of Gravity

Lecture 55 Work Done by Spring Force

Lecture 56 Conservative and Non Conservative Forces

Lecture 57 Principle of Conservation of Mechanical Energy

Lecture 58 Power

Lecture 59 Example 1

Lecture 60 Example 2

Lecture 61 Example 3

Lecture 62 Example 4

Lecture 63 Practice Problems on Work and Energy

Lecture 64 Solutions to Practice Problems on Work and Energy

Section 6: Kinetics of Particles_Impulse Moment Theorem & Collisions Central Impact

Lecture 65 What is Impulse ?

Lecture 66 Defining Impulse

Lecture 67 Impulse Momentum Theorem

Lecture 68 Graphical Interpretation of Impulse

Lecture 69 Example 1 on Impulse Momentum Theorem

Lecture 70 Example 2 on Impulse Momentum Theorem

Lecture 71 Practice Problems on Impulse & Momentum

Lecture 72 Solutions to Practice Problems on Impulse & Momentum

Lecture 73 Collision Basics & Examples

Lecture 74 Terms Related to Impact

Lecture 75 Elastic Collisions Analysis

Lecture 76 Example 1 on Elastic Collision

Lecture 77 Example 2 on Elastic Collision

Lecture 78 Example 3 on Elastic Collision

Lecture 79 Practice Problem on Elastic Collisions

Lecture 80 Solutions to Practice Problem on Elastic Collisions

Lecture 81 Inelastic Collision and INDIANA JONES

Lecture 82 Inelastic Collision Analysis

Lecture 83 Example 1 on Inelastic Collision

Lecture 84 Example 2 on Inelastic Collision

Lecture 85 Coefficient of Restituion_Detailed Analysis

Lecture 86 Example 1_Bouncing Ball

Lecture 87 Example 2_Bouncing Ball

Lecture 88 Example 3_Bouncing Ball

1. Engineering Enthusiasts: If you’re the type who disassembles toasters just to see how they work (and occasionally puts them back together), this course is your backstage pass to the mechanics show!,2. Engineering Students: Whether you’re a fresh-faced undergrad or a seasoned grad student, buckle up! We’ll dive into forces, moments, and equilibrium like it’s a high-speed chase through a physics-themed amusement park.,3. Physics Lovers: Ever wondered why bridges don’t crumble under the weight of rush-hour traffic? Or why your bicycle doesn’t spontaneously combust when you pedal uphill? Join us, fellow physics aficionados!,4. Future Inventors: If you’ve ever scribbled designs for a perpetual motion machine on the back of your math notebook (admit it, we all have), this course will fuel your creative fire.,So, my dear students, fasten your seatbelts, adjust your imaginary hard hats, and let’s rev up those brain gears. The road to understanding mechanics is paved with curiosity, equations, and a dash of magic