24 hours to Master Physics- from Beginners to Advanced level from Udemy

What's inside

Learning objectives

Concept building
Problem solving strategy

School or college level preparation
Getting ready for competitive exams

Concept building
Problem solving strategy
School or college level preparation
Getting ready for competitive exams

Syllabus

Introducing SI units and other types of quantities

This lecture is to set the rhythm of the course and introduce Units and Standards of various quantities

Quiz on Units and Standards

In this section, we will introduce vectors, learn how to add or subtract vector algebraically and will also learn about relative velocity

Vectors

Relative velocity

Practice questions on Vectors and Relative velocity: Part 1

Practice questions on Vectors and Relative velocity: Part 2

Quiz on Vectors and Relative velocity

To learn the difference between Displacement and Distance

Introduction: Part 1

Practice questions: Part 2

Practice questions: Part 3

Acceleration and equations of motion

Practice questions: Part 4

Quiz on Displacement vs Distance

At the end of this section, we will develop a clear understanding about the difference between Velocity vs Speed

Introduction : Part 1

Speed vs Velocity: Part 4

Speed vs Velocity: Part 5

Quiz on Velocity vs Speed

We will learn about the relation between position vs time graph

Graphical analysis: Position vs time part 1

Graphical analysis: Position vs time part 2

Graphical analysis: Position vs time part 3

Graphical analysis: Position vs time part 4

Quiz on Graphical analysis of Position vs time

We will learn about the relation between velocity vs time graph

Graphical analysis: Velocity vs time part 1

Graphical analysis: Velocity vs time part 2

Quiz on graphical analysis of Velocity vs Time

We will learn how acceleration affects motion. We will also introduce the famous equations of motion

This is a level 1 section - all have practice questions of different variety on equations of motion. At the end of this section, we will be well versed with apt usage of these equations.

Practice questions on equations of motion: Level 1 Part 1

Practice questions on equations of motion: Level 1 Part 2

Practice questions on equations of motion: Level 1 Part 3

Practice questions on equations of motion: Level 1 Part 4

Quiz on Equations of motion Level 1

This is a level 1 section - all have practice questions of different variety on equations of motion. At the end of this section, we will be comfortable in solving difficult questions as well

Practice questions on equations of motion: Level 2 Part 1

Equations of motion_ practice questions lecture 2 part 2

Equations of motion_ practice questions lecture 2 part 3

Quiz on Equations of motion Level 2

In these 5 lectures, we will learn how to extrapolate our knowledge of equations of motion in Freefall.

Practice questions - Freefall: Part 1

Practice questions - Freefall: Part 2

Practice questions - Freefall: Part 3

Practice questions - Freefall: Part 4

Practice questions - Freefall: Part 5

Quiz on Freefall

What are vector components? Why is that required? Let's learn

Vector components - Part 1

Vector components - Part 2

Quiz on vector components

Stepping in 2D Kinematics now. We will learn the inside out of projectile motion with some important formulas

Projectile motion - Introduction

Projectile motion - Concept builder question

In the coming 3 parts, we will apply the concepts of projectile motion in solving problems

Part 1

Part 2

Part 3

Quiz on Projectile motion

We will introduce Dynamics now - starting with Force and Newton's law

Introdution to Force and Newton's law

It is important to understand the types of forces, its properties along with nomenclature. This lecture provides a crisp idea about it.

Types of Forces

This is really important to understand before moving to problems related to Newton's law. We will introduce FBD here followed by practice questions in the coming lecture

FBD - Introduction

After learning how to draw FBD, it is time to get our hands dirty. This lecture provides practice questions on drawing FBD

FBD - Practice questions - Part 1

FBD - Practice questions - Part 2

We all set now to try problems on Newton's law. We will use knowledge of FBD here - aggressively!

Newton's law - Practice questions - Part 1

Newton's law - Practice questions - Part 2

Quiz on Newton's law

How to tackle a situation where the object is placed on a wedge or Inclined plane. We will build the concept in this lecture

Inclined plane - Concept builder

After building the concepts of Inclined plane, we will apply this knowledge in solving questions in the following 4 parts

Part 4

Applying FBD and Newton's law in elevator related questions

Applying FBD and Newton's law in Tension related questions

Introducing Attwood Machine and solving practice questions

Quiz on Newtons law (Related to Section 20-23)

We will introduce friction and build theory in these 2 parts.

Activities

Be better prepared before your course. Deepen your understanding during and after it. Supplement your coursework and achieve mastery of the topics covered in 24 hours to Master Physics- from Beginners to Advanced level with these activities:

Review Vector Algebra

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Strengthen your understanding of vector algebra to prepare for kinematics and dynamics problems.

Browse courses on Vector Algebra

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Review vector addition and subtraction.
Practice dot and cross products.
Solve problems involving vector components.

Read 'Physics for Scientists and Engineers'

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Supplement course material with a comprehensive textbook that provides additional explanations and examples.

View Physics for Scientists and Engineers, Extended... on Amazon

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Read chapters related to the current course topic.
Work through example problems in the book.
Attempt end-of-chapter problems for practice.

Solve Kinematics Problems

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Reinforce your understanding of kinematics by solving a variety of problems.

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Find kinematics problems from textbooks or online resources.
Solve problems involving constant acceleration.
Solve problems involving projectile motion.
Check your answers and review solutions.

Four other activities

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Show all seven activities

Read 'Six Easy Pieces' by Richard Feynman

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Gain a deeper understanding of fundamental physics concepts through Feynman's engaging explanations.

View Six Not-So-Easy Pieces: Einstein's Relativity,... on Amazon

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Read one chapter at a time.
Reflect on the concepts presented.
Discuss the ideas with others.

Create a Physics Blog

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Solidify your understanding by explaining physics concepts in your own words.

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Choose a platform for your blog.
Write articles explaining key concepts from the course.
Include diagrams and examples to illustrate your points.
Share your blog with others and solicit feedback.

Tutor Physics Students

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Reinforce your understanding by helping other students learn physics.

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Offer tutoring services to students in introductory physics courses.
Prepare for tutoring sessions by reviewing relevant material.
Explain concepts clearly and patiently.
Provide helpful feedback and guidance.

Build a Physics Simulation

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Apply your knowledge of physics to create a simulation of a physical system.

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Choose a physical system to simulate.
Write code to model the system's behavior.
Test your simulation and refine your model.
Visualize the results of your simulation.

Career center

Learners who complete 24 hours to Master Physics- from Beginners to Advanced level will develop knowledge and skills that may be useful to these careers:

Physics Teacher

Physics teachers educate students on the principles of physics, fostering an understanding of the natural world. This course can help physics teachers deepen their understanding of classical mechanics, enabling them to explain concepts more clearly and effectively to their students. The course's comprehensive coverage of kinematics, dynamics, and other fundamental topics, prepares a teacher to answer student questions with confidence, design engaging demonstrations, and develop challenging problem sets. Physics teachers can use the problem-solving strategies taught in this course to show their students different ways of answering questions.

See salaries and explore the career path for Physics Teacher

Astrophysicist

Astrophysicists study the physics of the universe, including the properties and behavior of celestial objects such as stars, planets, and galaxies. Classical mechanics plays a crucial role in understanding the motion of celestial bodies, gravitational interactions, and the dynamics of astrophysical systems. This course ensures that an astrophysicist has a strong foundation in the fundamental principles of mechanics. The course covers motion, force, energy, and gravitation, preparing one to analyze astronomical phenomena, model the behavior of celestial objects, and conduct research in areas such as cosmology and stellar dynamics. This role often requires a doctorate.

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Mechanical Engineer

A mechanical engineer researches, designs, develops, manufactures, and tests mechanical devices and systems. This course provides a solid foundation in classical mechanics, which is essential for understanding the behavior of mechanical systems. The course's coverage of topics such as Newton's laws of motion, friction, and rotation, directly applies to the analysis and design of machines, engines, and other mechanical components. A future mechanical engineer benefits from the problem-solving strategies taught in this course. Students develop a stronger understanding of force, motion, and energy. Mechanical engineers can then apply these concepts to design and improve mechanical systems, such as engines, machines, and robotics.

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Robotics Engineer

A robotics engineer designs, builds, tests, and maintains robots and robotic systems. Classical mechanics forms the backbone of robotics, governing the movement, control, and interaction of robots with their environment. This course helps a future robotics engineer by providing them with a deep understanding of kinematics, dynamics, and control principles. The course material on topics such as rotation, friction, and Newton's laws directly applies to the design and programming of robot manipulators, autonomous vehicles, and other robotic devices. Learning the problem solving strategies in this course is important because they provide a good understanding of the underlying physics that is necessary to design robots that operate reliably and efficiently.

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Research Scientist

Research scientists design and conduct experiments, analyze data, and publish findings in various scientific fields. In many areas of physics, a strong understanding of classical mechanics is essential for designing experiments, interpreting results, and developing theoretical models. This course would be useful for a research scientist because it builds a rigorous foundation in the principles of mechanics. The course's coverage of dynamics, kinematics, and problem-solving approaches, prepares scientists to tackle complex research questions. Often, research scientists must complete a doctorate.

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Aerospace Engineer

Aerospace engineers design, develop, test, and supervise the manufacturing of aircraft, spacecraft, and missiles. The principles of classical mechanics are fundamental to aerospace engineering, particularly in areas such as flight dynamics, propulsion, and structural analysis. This course's detailed exploration of topics like projectile motion, Newton's laws, and rotational dynamics is invaluable for aspiring aerospace engineers. They will use this information to understand the motion of aircraft, design efficient propulsion systems, and analyze the structural integrity of aerospace vehicles. The problem-solving skills emphasized in the course prepare an aerospace engineer to tackle the complex challenges inherent in this field.

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Geophysicist

Geophysicists study the physical properties and processes of the Earth, including its structure, composition, and dynamics. Classical mechanics is crucial for understanding phenomena such as plate tectonics, earthquakes, and the flow of fluids within the Earth. A geophysicist benefits from having a strong grasp of the material taught in this course. The course covers dynamics, kinematics, and problem-solving approaches, This enables them to model geological processes, analyze seismic data, and explore the Earth's interior. Advanced degrees are very common.

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Biomedical Engineer

Biomedical engineers develop medical devices and technologies, applying engineering principles to solve healthcare problems. A future biomedical engineer can make use of the principles of mechanics when designing artificial limbs, analyzing biomechanics, and developing medical imaging techniques. This course helps build a solid foundation in classical mechanics, which is essential for understanding the forces, motion, and materials involved in biological systems and medical devices. The lessons in problem-solving that this course offers will prepare a biomedical engineer to tackle the complex challenges in this interdisciplinary field.

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Acoustical Engineer

Acoustical engineers deal with sound and vibration. They work on noise control, sound reproduction, and the design of spaces for optimal sound quality. A course teaching mechanics equips an acoustical engineer with knowledge of wave mechanics, vibration, and the behavior of materials under stress. The course's lessons in mechanics and motion informs the design of quieter products, better concert halls, and effective noise barriers. The mechanics principles taught in the course will help with modeling and predicting acoustic phenomena.

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Structural Engineer

Structural engineers analyze and design structures to ensure their safety and stability. A course teaching mechanics is useful for structural engineers because they must understand the forces and stresses acting on buildings, bridges, and other structures. Learning how to perform structural analysis, load calculations, and material selection is crucial, and this course may provide insight into the properties of force and stress acting on structures. The structural engineer uses these skills to design safe and efficient structures that can withstand various loads and environmental conditions.

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Civil Engineer

Civil engineers design, construct, and maintain the built environment, including roads, bridges, buildings, and other infrastructure. While civil engineering encompasses various disciplines, a solid understanding of classical mechanics is crucial for structural analysis and design. This course may be helpful for someone to understand the principles of statics and dynamics, which are essential for assessing the forces and stresses acting on structures. The course's coverage of topics like force, friction, and equilibrium, provides a foundation for analyzing the stability and safety of civil engineering projects. Someone who becomes a civil engineer will appreciate the problem-solving skills taught in this course.

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Patent Attorney

Patent attorneys advise clients on intellectual property law, particularly patents. They prosecute patent applications, conduct patent searches, and litigate patent disputes. While technical expertise may be a plus, patent attorneys who specialize in physics-related inventions need a solid understanding of this course so they can grasp the underlying principles and technologies. The analytical and problem-solving skills learned from this course are helpful, and a background in physics can provide a competitive edge in this specialized field. This career path typically requires a law degree.

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Data Scientist

Data scientists analyze large datasets to extract meaningful insights and develop predictive models. While the connection to classical mechanics isn't immediately obvious, the analytical and problem-solving skills honed through this course are transferable to data science. A future data scientist can benefit from learning how to approach complex problems, break them down into smaller components, and apply mathematical techniques to find solutions. The course helps further data analysis skills and the ability to identify patterns and relationships, both of which are valuable assets in data science.

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Software Engineer

Software engineers design, develop, and test software applications and systems. While the direct application of classical mechanics might be limited, the problem-solving and analytical skills developed through this course are invaluable. A software engineer will benefit, for example, from the experience of breaking down complex problems into smaller, manageable components, and applying logical reasoning to find solutions. These are essential skills for designing efficient algorithms, debugging code, and developing robust software systems. This course may help someone to develop a structured approach to problem-solving that they can apply to software development.

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Financial Analyst

Financial analysts evaluate investments and provide financial guidance to individuals and organizations. While seemingly unrelated, the analytical and problem-solving skills emphasized in this course can be valuable assets in finance. Financial analysts can use the skills learned during the course on concepts to model financial markets, assess risk, and make informed investment decisions. This course may come in handy when determining how to approach complex problems, break them down into smaller components, and apply mathematical techniques to find solutions.

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24 hours to Master Physics- from Beginners to Advanced level

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