My Physics lectures for High School and College students.

Physics is not difficult if you practice with problems
⏱️ Length: 13.4 total hours
👥 258 students
🔄 October 2025 update

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Course Overview
- Instructor’s Core Philosophy: This course is built upon the fundamental principle that physics is inherently accessible and deeply rewarding when approached through consistent, analytical problem-solving, fostering an environment where complex concepts become clear and manageable.
- Structured Pedagogical Approach: Experience a meticulously designed learning path that gradually introduces foundational concepts, ensuring a solid comprehension before progressing to more intricate applications, suitable for diverse academic backgrounds.
- Interactive Learning Paradigm: Beyond passive lectures, the course actively promotes engagement by demonstrating how to dissect challenging physics questions, encouraging students to think critically rather than merely memorize formulas.
- Real-World Application Emphasis: Explore how theoretical physics principles manifest in everyday phenomena and practical engineering scenarios, enhancing intuition and making the subject matter highly relatable and less abstract.
- Flexible Learning Cadence: Comprising 13.4 total hours of focused instruction, the material is presented in an digestible format that supports self-paced learning, allowing students to review difficult sections at their convenience.
- Comprehensive Conceptual Exposition: Each topic is thoroughly explained from first principles, ensuring that students grasp the ‘why’ behind the physics, not just the ‘how’ of calculations, leading to a profound understanding.
- Evolving Curriculum Commitment: The ‘October 2025 update’ reflects an ongoing dedication to refining content, incorporating contemporary insights, and ensuring the highest quality of instruction and relevance for learners.
- Targeted Audience Engagement: Specifically curated to bridge the gap between high school physics introductions and the rigors of college-level coursework, making it an ideal resource for both preparatory and foundational studies.
- Building Analytical Agility: The instruction is geared towards cultivating a mindset that thrives on deconstructing problems, identifying core principles, and constructing logical solution pathways, moving beyond mere numerical answers.
- Accessible Explanations: Complex physical phenomena are broken down into understandable components using clear language, intuitive analogies, and visual aids, dispelling the common apprehension associated with physics.
Requirements / Prerequisites
- Basic Algebraic Fluency: A comfortable grasp of fundamental algebraic operations, including solving equations, manipulating variables, and working with exponents, is essential for navigating the mathematical components of the course.
- High School Math Readiness: Familiarity with pre-calculus concepts, such as trigonometry (sine, cosine, tangent) and vector addition, will significantly aid in understanding directional quantities and geometrical problem setups.
- Foundational Problem-Solving Mindset: A willingness to approach challenges analytically and persist through iterative attempts at finding solutions is more valuable than prior extensive physics knowledge.
- Active Engagement Spirit: Students should be prepared to actively participate in the learning process, which includes practicing alongside the instructor, pausing to reflect, and attempting problems independently.
- Essential Study Materials: Access to basic stationery such as pen, paper, and a scientific calculator capable of trigonometric functions is highly recommended for working through examples and exercises.
- Curiosity for the Physical World: An inherent interest in how the universe works, from the motion of everyday objects to the forces governing them, will greatly enhance the learning experience.
- No Prior Physics Experience Required: While some high school physics background is helpful, the course is designed to be self-contained for beginners, starting with fundamental concepts and building upwards.
- Time Commitment for Practice: Beyond the lecture hours, allocating dedicated time for independent practice and reviewing challenging concepts will be crucial for solidifying understanding.
- Openness to New Concepts: A readiness to embrace new ways of thinking about motion, energy, and forces, even if they sometimes challenge intuitive preconceptions, is key to success.
Skills Covered / Tools Used
- Systematic Problem Decomposition: Develop the ability to break down complex multi-step physics problems into manageable, sequential parts, identifying relevant information and isolating unknown variables.
- Conceptual Model Building: Learn to construct mental and diagrammatic models of physical systems, simplifying scenarios to their essential components for effective analysis, such as point masses or ideal pulleys.
- Vector Analysis and Manipulation: Master the graphical and analytical methods for adding, subtracting, and resolving vectors into components, critical for dealing with forces, velocities, and accelerations in multiple dimensions.
- Free-Body Diagram Construction: Gain proficiency in drawing accurate free-body diagrams to represent all forces acting on an object, an indispensable tool for applying Newton’s Laws and solving dynamics problems.
- Mathematical Application and Translation: Hone the skill of translating physical descriptions and conceptual understanding into precise mathematical equations, and conversely, interpreting mathematical results in physical terms.
- Unit Consistency and Dimensional Analysis: Learn to meticulously track units throughout calculations to ensure dimensional consistency, a powerful method for error checking and verifying the validity of derived formulas.
- Graphical Interpretation: Develop the ability to extract meaningful physical information from motion graphs (position-time, velocity-time, acceleration-time) and represent kinematic scenarios graphically.
- Strategic Equation Selection: Cultivate the discernment to choose the most appropriate physics equations or principles (e.g., kinematics, work-energy theorem, conservation laws) based on the specific problem context.
- Critical Error Identification: Enhance the skill of reviewing one’s own solutions to identify and correct logical flaws, computational mistakes, or conceptual misunderstandings.
- Approximation and Estimation: Understand when and how to use approximations to simplify calculations or to quickly estimate the magnitude of an expected answer, fostering a deeper physical intuition.
Benefits / Outcomes
- Solidified Foundational Knowledge: Emerge with an extremely strong grasp of classical mechanics, providing an unshakeable foundation for pursuing more advanced topics in physics, engineering, or related scientific disciplines.
- Enhanced Academic Performance: Significantly improve performance in high school physics courses, standardized tests, AP exams, and introductory college physics curricula due to the comprehensive problem-solving focus.
- Boosted Analytical Thinking: Cultivate highly transferable analytical and critical thinking skills applicable not just to physics but to any field requiring logical reasoning, data interpretation, and strategic planning.
- Increased Problem-Solving Confidence: Develop a robust toolkit and a systematic approach to tackle novel and challenging problems, replacing apprehension with a sense of capability and resilience.
- Improved Scientific Literacy: Gain a deeper appreciation for the principles governing the physical world, fostering a more informed perspective on scientific news, technological advancements, and natural phenomena.
- Preparation for Advanced Studies: Be exceptionally well-prepared for university-level physics, engineering physics, or mechanics courses, possessing a conceptual clarity and problem-solving prowess that many peers might lack.
- Development of Physics Intuition: Beyond just calculating answers, you will begin to anticipate physical behaviors and outcomes, developing an intuitive understanding of forces, motion, and energy interactions.
- Greater Academic Independence: Acquire the skills necessary to approach and conquer complex scientific challenges independently, reducing reliance on rote learning and promoting genuine intellectual curiosity.
- Effective Study Habits: The course’s emphasis on consistent practice and structured thinking will instill valuable study habits that are beneficial across all academic subjects.
- Foundation for STEM Careers: Lay essential groundwork for future careers in science, technology, engineering, and mathematics by mastering the core principles that underpin these fields.
PROS
- Exceptional Value for Practice: The course’s explicit and sustained focus on problem-solving as the primary learning mechanism ensures a practical mastery of mechanics that goes beyond theoretical understanding.
- Highly Accessible Instruction: The instructor’s ability to demystify complex physics concepts makes the material engaging and understandable for a broad audience, from high school students to college learners.
- Strong Foundation Building: Provides an incredibly robust and thorough introduction to classical mechanics, essential for anyone planning further studies in STEM fields.
- Flexibility for Diverse Learners: The self-paced video format allows students to learn at their optimal speed, revisiting challenging sections as often as needed for complete comprehension.
- Up-to-Date and Relevant: The recent content update ensures that the material is current, accurate, and pedagogically sound, reflecting best practices in physics education.
- Confidence Through Competence: Students will genuinely feel more confident in their physics abilities due to the hands-on, problem-centric approach, translating directly into improved academic performance.
CONS
- Requires Significant Self-Discipline: Success in this problem-intensive course heavily relies on the student’s consistent self-motivation and dedication to practice outside of the guided lectures.