-- KINEMATICS --

Kinematics – Lecture

19 Topics

P01-010 – Measuring Time & Position

P01-020 – Particle Model

P01-030 – Position Vector

P01-040 – Displacement Vector

P01-050 – Average Velocity Vector

P01-060 – Average Acceleration Vector

P01-070 – Instantaneous Velocity

P01-080 – Instantaneous Acceleration

P01-090 – Relationship Between Velocity & Acceleration

P01-100 – Kinematic Equations with Constant Acceleration

P01-110 – Application: Free-Fall

P01-200 – Angular Position & Displacement

P01-210 – Average Angular Velocity

P01-220 – Average Angular Acceleration

P01-230 – Instantaneous Angular Velocity

P01-240 – Instantaneous Angular Acceleration

P01-250 – Relationship Between Angular Speed & Acceleration

P01-260 – Kinematic Equations for Circular Motion

P01-270 – Relating Angular and Linear Quantities

Kinematics – Problems

16 Topics

P01R2015 – Components & Dot Product

P01G2015 – Average Velocity

P01R2015 – Acceleration on an incline

P01R2015 – Vertical Free-fall

P01G2019 – Rocket Launch

P01G2019 – Cars Racing Alongside Each Other

P01R2021 – Physics Rocks

P01B2020 – Trains Approaching

P01R2015 – Catching the Bus

P01R2015 – Highway Patrol

P01G2007 – Balls Colliding in Mid-air

P01G2008 – Passing a Car

P01B2017 – Dropped and Tossed Balls

P01S2016 – Throwing a Rock from a Truck

P01S2019 – Missiles Colliding

P01S2015 – Dropping vs. Throwing

-- PROJECTILE MOTION --

Projectile Motion – Lecture

7 Topics

P02-010 – Projectile Motion

P02-020 – Equations of Motion

P02-030 – Equation of the Path y = f(x)

P02-040 – Finding the Maximum Height

P02-050 – Property of the Path of the Projectile

P02-060 – Range of the Projectile

P02-070 – Launch Angle and Range Maximization

Projectile Motion – Problems

15 Topics

P02R2015 – Analysis of a Jump

P02R2015 – Hoop Spacing

P02G2018 – Air Drop

P02R2015 – A Ball Game

P02G2017 – Ball Toss

P02R2015 – Clearing the Edge of a Cliff

P02G2005 – Home Run

P02G2016 – Ball Thrown in the Air

P02G2020 – Football Toss

P02G2021 – Projectile Launched from Unknown Height

P02S2008 – A Bouncing Superball

P02S2019 – Ball Flying Past a Window

P02S2013 – Throwing a Rockk Over a Plateau

P02S2010 – Tennis Ball Launcher and Mobile Target

P02S2016 – Throwing Gum Out an Elevator

-- DYNAMICS --

Newton’s Laws – Lecture

13 Topics

P03-010 – Force and Vector Representation

P03-020 – Common Forces: weight force

P03-030 – Common Forces: tension force

P03-040 – Common Forces: normal force

P03-050 – Common Forces: friction forces

P03-060 – Common Forces: spring force & Hooke’s Law

P03-070 – Free-Body Diagram

P03-080 – Net Force

P03-090 – Newton’s First Law

P03-100 – Newton’s Second Law

P03-110 – Newton’s Third Law

P03-120 – Application: ideal string

P03-130 – Application: ideal pulley

Newton’s Laws – Problems

30 Topics

P03G2018 – Blocks Slipping on an Incline

P03R2015 – Hanging Mass

P03R2015 – Keeping a Box at Rest

P03G2007 – Holding a Block on an Incline

P03G2008 – Holding a Block Up Against a Wall

P03G2016 – Pressing a Block Against a Wall

P03R2015 – Resting or Sliding Up an Incline

P03R2015 – Acceleration and Friction Forces

P03G2005 – Holding Up a Block

P03G2015 – Pushing on Three Blocks

P03B2006 – Who is Pulling Who?

P03G2016 – Joint Inclines

P03G2017 – Pulling Three Blocks

P03G2018 – Pulling and Lifting

P03G2020 – Connected Blocks

P03R2015 – Atwood Machine

P03R2015 – Acceleration Constraint

P03R2015 – Pulling Two Connected Boxes

P03G2021 – Minimum Slipping Force

P03G2022 – Pulling Blocks on an Incline

P03S2008 – Three Blocks at Rest

P03S2016 – Two Blocks Compressing a Spring

P03S2013 – Rocket Launch

P03S2009 – Max and Min Angle of an Incline

P03S2016 – Corvette Flying Off a Cliff

P03S2016 – Pulling Stacked Blocks

P03S2019 – Sliding Up a Wedge at Rest

P03S2008 – Two Blocks on the Verge of Slipping

P03S2013 – Lifting a Box with Pulleys

P03S2015 – Climbing Up a Rope

-- CIRCULAR MOTION --

Circular Motion – Lecture

14 Topics

P04-010 – Circular Motion

P04-020 – RTZ Coordinate System

P04-030 – Direction of Acceleration

P04-040 – Components of Acceleration

P04-050 – Derivation of the Components of Acceleration

P04-060 – Uniform & Non-Uniform Circular Motion

P04-070 – Period of Revolution

P04-080 – Newton’s Second Law

P04-090 – Angular Position & Displacement

P04-100 – Instantaneous Angular Velocity

P04-110 – Instantaneous Angular Acceleration

P04-120 – Relationship Between Velocity and Acceleration

P04-130 – Kinematic Equations for Circular Motion

P04-140 – Relating Angular & Linear Quantities

Circular Motion – Problems

17 Topics

P04G2016 – Lift Force on a Plane

P04B2017 – Interconnected Masses

P04B2020 – Tether Ball

P04B2006 – Space Ride

P04G2017 – Toy Car

P04G2018 – Holding a Block against a Wall

P04S2016 – Sliding Around a Funnel

P04S2016 – Pendulum on Planet Vulcan

P04B2016 – Banked Curve vs. Flat Curve

P04G2019 – Semicircular Hill and Valley

P04G2005 – Flying in a Loop

P04R2015 – Around the Loop

P04G2022 – Pendulum

P04S2016 – Car Driving Inside a Cone

P04S2019 – RC Car in a Can

P04S2013 – Riding Inside a Spherical Cage

P04S2015 – Racing Outside a Banked Curve

-- WORK & ENERGY --

Work & Energy – Lecture

14 Topics

P05-010 – Energy

P05-020 – Kinetic Energy

P05-030 – Gravitational Potential Energy

P05-040 – Elastic Potential Energy

P05-050 – Mechanical Energy

P05-060 – Work Done by a Force

P05-070 – Calculating the Work Done by a Force

P05-080 – Conservative Force

P05-100 – Work Done by the Weight Force

P05-110 – Work Done by the Spring Force

P05-120 – Work-Kinetic Energy Theorem

P05-130 – Derivation of the Work-Kinetic Energy Theorem

P05-140 – Conservation of Mechanical Energy

P05-150 – Power and Mechanical Power

Work & Energy – Problems

20 Topics

P05G2007 – Package Landing on a Spring

P05S2016 – Sliding Over a Hill

P05L2022 – From One Spring to Another

P05G2019 – Block on a Vertical Spring

P05G2020 – Frictionless Ramp

P05G2016 – Mass-Spring System

P05R2015 – Rough Sliding

P05G2017 – Shooting a Crate

P05G2018 – Back and Forth Between Springs

P05R2021 – Launching a Block Up a Rough Incline

P05G2016 – Non-Conservative Force

P05G2018 – Projectile Launched from a Ramp

P05G2019 – Pushing a Block on the Ceiling

P05B2016 – Roller Coaster

P05G2021 – Friction Under a Spring

P05S2009 – Sliding Mounds and Block

P05S2016 – Sliding Down and Bouncing Back Up

P05S2019 – Down and Up Twice

P05S2013 – Stretching a Spring

P05S2015 – Sliding Off a Ramp with Friction

-- IMPULSE & MOMENTUM --

Impulse & Moment. – Lecture

10 Topics

P06-010 – Momentum Vector

P06-020 – Newton’s Second Law in Momentum Form

P06-030 – Conservation of Momentum

P06-040 – Impulse of a Force

P06-050 – How to Calculate an Impulse

P06-060 – Impulse-Momentum Theorem

P06-070 – Inelastic & Elastic Collisions

P06-080 – Solving Strategy: perfectly inelastic collision

P06-090 – Solving Strategy: head-on elastic collision

P06-100 – Solving Strategy: off-center elastic collision

Impulse & Moment. – Problems

20 Topics

P06G2005 – Game of Catch

P06L2018 – Plate Pieces

P06R2015 – Explosion of a Hockey Puck

P06R2015 – Ballistic Pendulum

P06G2019 – Blocks & Compressed Spring

P06B2006 – Saving Lois?

P06G2007 – Three Colliding Blocks

P06G2017 – Sequence of Collisions

P06R2019 – Two Collisions in a Row

P06B2016 – Fireworks

P06G2016 – Collision Between Three Masses

P06G2018 – Masses Bouncing Off Each Other

P06G2020 – Speed Before and After a Collision

P06R2020 – Inelastic Collision vs. Elastic Collision

P06D2009 – Fun with a Slingshot

P06S2008 – Canoe Disagreement

P06S2019 – Space Chase

P06S2013 – Launching Two Blocks with a Spring

P06S2016 – Sliding Blocks Compressing a Spring

P06S2016 – Sliding Down and Back Up

-- CENTER OF MASS --

Center of Mass – Lecture

11 Topics

P08-010 – Center of Mass of a System of Particles

P08-020 – Position of the Center of Mass

P08-030 – Velocity of the Center of Mass

P08-040 – Acceleration of the Center of Mass

P08-050 – Newton’s Second Law and Center of Mass

P08-060 – Center of Mass of a Rigid Body

P08-070 – Computation: center of mass of a uniform rod of mass

P08-080 – Computation: center of mass of a uniform cylinder

P08-090 – Computation: center of mass of a uniform solid sphere

P08-100 – Computation: center of mass of a compound body

P08-110 – Computation: center of mass of a hollow body

Center of Mass – Problems

11 Topics

P08G2019 – Stacked Blocks

P08R2015 – Walking to the End of the Canoe

P08D2014 – Elephant on a Train Car

P08R2015 – Collision and COM of Two Blocks

P08R2015 – Two Sliding Masses

P08R2015 – Two Sliding Masses at it Again

P08R2015 – COM of Three Boxes

P08R2015 – Exploding Firework

P08S2015 – Jumping the Plank

P08R2015 – A Grenade Exploding in Midair

P08R2015 – COM of rigid bodies

-- TORQUE - STATICS --

Statics – Lecture

5 Topics

P09-010 – Equilibrium of an Extended Body

P09-020 – Introduction: three simple cases

P09-030 – Reminder: cross product of two vectors

P09-040 – Torque Created by a Force

P09-050 – Equilibrium Condition for an Extended Body

Statics – Problems

17 Topics

P09R2020 – Balanced Beam

P09R2020 – Balanced Beam with Hanging Mass

P09B2021 – Drawbridge

P09R2015 – Resting Ladder

P09R2015 – Ladder and Painter

P09B2019 – A Ball Attached to an Incline

P09S2016 – Balanced Sphere

P09R2015 – Straw Balanced Across a Glass

P09G2019 – Non-Uniform Hanging Bar

P09B2011 – Marble Quarry Crane

P09G2007 – Rod in Equilibrium

P09G2016 – Balancing a Horizontal Rod

P09G2017 – Two Balanced Rods

P09G2020 – Beam with Two Sections

P09S2009 – Disk Balanced Between Rods

P09B2018 – Static Equilibrium of a Crane

P09G2018 – Balanced Pole

-- TORQUE - DYNAMICS --

Dynamics – Lecture

10 Topics

P10-010 – Solid Rotation

P10-020 – Angular Velocity Vector

P10-030 – Angular Acceleration Vector

P10-040 – Moment of Inertia

P10-050 – List of Moments of Inertia

P10-060 – Computation: moment of inertia of a solid rod

P10-070 – Computation: moment of inertia of a solid cylinder

P10-080 – Computation: moment of inertia of a solid sphere

P10-090 – Parallel-Axis Theorem

P10-100 – Newton’s Second Law for Rotational Motion

Dynamics – Problems

19 Topics

P10S2015 – Helicopter Blade

P10G2005 – Rotating a Disk and a Rod

P10G2016 – Rotating Cylinder

P10D2013 – Pushing a Dresser

P10G2018 – Pushing a Door and a Box

P10R2015 – Kinematics of a Hollow Sphere

P10R2015 – Atwood Machine

P10G2019 – Blocks & Non-ideal Pulley

P10G2007 – Pulley Lowering a Block

P10L2018 – Moment of Inertia of a Pulley

P10B2017 – Measuring Rotational Inertia

P10S2016 – Rolling on a Circular Track

P10S2016 – Rolling and Slipping

P10S2009 – Pulling a Spool of Thread

P10S2013 – Pulling Strings Off a Disk

P10S2015 – Spherical Spintop

P10S2019 – Accelerating Joint Disks

P10S2015 – Disk and Mass Contraption

P10S2016 – Block Pulling a Rolling Disk

-- TORQUE - ENERGY & MOMENTUM --

Energy & Moment. – Lecture

11 Topics

P11-010 – Angular Momentum

P11-020 – Newton’s Second Law in Angular Momentum Form

P11-030 – Conservation of Angular Momentum

P11-040 – Impulse-Momentum Theorem of Angular Momentum

P11-050 – Rolling Motion

P11-060 – Rolling w/o Slipping and Static Friction

P11-070 – Rotational Kinetic Energy

P11-080 – Rolling Kinetic Energy

P11-090 – Work Done by a Torque

P11-100 – Work-Kinetic Energy Theorem

P11-110 – Conservation of Energy for Rolling w/o Slipping

Energy & Moment. – Problems

17 Topics

P11G2019 – Biking Down a Hill

P11B2012 – Rolling up an Incline

P11G2007 – Kinetic Energy of a Spool

P11G2008 – Rotating Rod

P11G2016 – Unraveling a String Wound on a Sphere

P11G2017 – Velocity of a Rolling Disk

P11R2015 – Atwood Machine

P11G2018 – Two-Disk Pulley

P11R2015 – Down the Incline

P11G2015 – Around the Loop

P11G2005 – Pulley with Friction

P11R2015 – Vertical Swinging Rod

P11S2013 – Rolling Up and Off a Ramp

P11S2015 – Rolling…or Not

P11S2009 – Spring-Launched Objects

P11S2019 – Rolling on a Sliding Plank

P11S2016 – Fleas Jumping Off a Disk

-- FLUIDS --

Fluids – Lecture

10 Topics

P12-010 – Definitions for Fluids

P12-020 – Mass Density & Pressure

P12-030 – Fundamental Equation of Hydrostatics

P12-040 – Hydrostatic Pressure in a Uniform Gravitational Field

P12-050 – Buoyant Force & Archimedes’ Principle

P12-060 – Floating Condition and Neutrally Buoyant Objects

P12-070 – Pascal’s Principle

P12-090 – Volume Flow Rate & Mass Flow Rate

P12-100 – Continuity Equation

P12-110 – Bernoulli’s Equation

Fluids – Problems

21 Topics

P12R2015 – U-Shaped Tube with Oil and Water

P12R2015 – The Hidden Part of the Iceberg

P12B2017 – Floating in Two Fluids

P12B2021 – Hydraulic Press

P12G2005 – Floating Glass Beaker

P12G2007 – Boat with a Ballast

P12G2016 – Floating Cylinder

P12G2019 – Anchored Barge

P12G2018 – Piece of Iron with Cavities

P12G2020 – Weighing Suspended Blocks in Water

P12G2016 – Flow Through a Horizontal Pipe

P12G2019 – Large Hole in Water Tank

P12G2008 – Hose Draining a Tank

P12G2015 – Flow Through a Pipe

P12G2017 – Flow Through Pitot Tube

P12G2018 – Narrow Pipe on a Tank

P12R2015 – Pitot Tube

P12G2007 – Water Leaking Out of a Tank

P12S2019 – Suspended Floating Iron Cylinder

P12S2013 – Syringe of Water

P12S2009 – Leaky Cylindrical Tank

-- OSCILLATIONS --

Oscillations – Lecture

19 Topics

P13-010 – Oscillatory Motion

P13-020 – Definitions: period, frequency, and amplitude

P13-030 – Modeling Oscillations Mathematically

P13-040 – Velocity & Acceleration of Oscillations

P13-050 – Maximum Speed and Maximum Acceleration

P13-060 – Methods to Determine the Phase Constant

P13-070 – Review: second-order differential equations

P13-080 – Classic Oscillators: horizontal mass-spring oscillator

P13-090 – Classic Oscillators: vertical mass-spring oscillator

P13-100 – Classic Oscillators: simple pendulum

P13-110 – Classic Oscillators: physical pendulum

P13-120 – Classic Oscillators: torsional pendulum

P13-130 – Conservation of Energy: horizontal oscillator

P13-140 – Conservation of Energy: vertical mass-spring oscillator

P13-150 – Conservation of Energy: simple pendulum

P13-160 – Conservation of Energy: physical pendulum

P13-170 – Conservation of Energy: torsional pendulum

P13-180 – Springs in Series or in Parallel

P13-190 – Modeling Damped Oscillations

Oscillations – Problems

16 Topics

P13R2015 – Mathematics of Oscillations

P13R2015 – Energy of a Horizontal Oscillator

P13G2015 – Collision then Oscillations

P13R2015 – Energy of a Simple Pendulum

P13B2017 – Mass-Spring Systems

P13G2008 – Oscillating Block

P13G2017 – Horizontal Oscillator

P13G2019 – Mass of an Oscillating Block

P13R2015 – Superposed Oscillating Blocks

P13G2018 – Mass Dropped on an Oscillator

P13R2015 – Springs in Series and in Parallel

P13S2011 – Oscillating Plate

P13S2013 – Oscillating Rod

P13S2019 – Oscillating While Rolling Without Slipping

P13S2016 – Collision with a Rod

P13S2009 – Elastic Collisions and Oscillations

-- MECHANICAL WAVES --

Mechanical Waves – Lecture

21 Topics

P14-010 – Fundamental Definitions

P14-020 – Classification of Waves

P14-030 – One-Dimensional Sinusoidal Traveling Waves

P14-040 – Period and Wavelength

P14-050 – Speed of a Traveling Wave

P14-060 – Principle of Superposition

P14-070 – Constructive and Destructive Interference

P14-080 – Conditions for Constructive and Destructive Interference

P14-090 – Waves on a String Under Tension

P14-100 – Celerity of a Wave on a String

P14-110 – Reflection of a Wave at a Boundary

P14-120 – Standing Waves

P14-130 – Patterns, Fundamental Frequency, Harmonics

P14-140 – Soundwaves

P14-160 – Standing Waves in a Column of Air

P14-170 – Column of Air Closed at Both Ends

P14-180 – Column of Air Open at Both Ends

P14-190 – Column of Air with Open/Closed Ends

P14-200 – Beats

P14-210 – Doppler Effect

P14-220 – Intensity and Sound Level

Mechanical Waves – Problems

16 Topics

P14G2007 – Standing Wave on a Wire

P14G2015 – Standing Wave on a String

P14G2016 – Vibrating Wire

P14G2018 – Standing Wave Pattern

P14R2015 – Two Strings

P14G2008 – Another Vibrating Wire

P14G2019 – Standing Waves in a Pipe

P14R2015 – A Tuning Fork and a Tube

P14R2015 – Interfering Soundwaves

P14G2007 – Bat Flying Toward a Wall

P14G2015 – Extraterrestrial Doppler Shift

P14G2017 – Doppler-Shifted Train Whistle

P14R2015 – Foghorns on the Bay

P14G2016 – Oscillating Speaker

P14S2009 – Vibrating Hanging Wires

P14Y2010 – Hanging Rope

P01-020 – Particle Model

Physics 7A – Spring 2024 (Golightly) Kinematics – Lecture P01-020 – Particle Model

Particle Model

The description of the motion of an object if often complex, especially if one must account for the overall motion of the object (the path it appears to follow) as well as the motion of the object itself (rolling, twirling, etc.). As a way to ease into Kinematics, which seeks to describe the motion of an object without understanding the causes for the motion, we will at first neglect its shape and size treat it as a particle.

A particle has no size, no top nor bottom, no front nor back, and therefore the objects we will consider will either be point-like masses or will be treated as point-like masses. While this Particle Model fails to fully describe certain types of motion, it is a very good model to describe the overall motion of a solid as it moves along a path and makes for a manageable introduction to Kinematics. As a consequence, any object for which we will study the motion will be treated as a particle with all of its mass concentrated at a point.

As we advance through mechanics, we will eventually reach the limit of the Particle Model and will have to develop a better description for more advanced motions such a rotation and rolling. Until that point, however, we will continue to use the Particle Model consistently.