Oscillations Simple Harmonic Motion Velocity and Acceleration in SHM

Slides:

Advertisements

Similar presentations

Oscillations and Simple Harmonic Motion:

Advertisements

Copyright © 2014 John Wiley & Sons, Inc. All rights reserved.

Chapter 15 Oscillations Who breaks the glass?! (credit: metaist.com)

Chapter 15 Oscillations Oscillatory motion Motion which is periodic in time, that is, motion that repeats itself in time. Examples: Power line oscillates.

Phy 212: General Physics II Chapter 15: Oscillations Lecture Notes.

Simple Harmonic Motion

Simple Harmonic Motion

SHM SHM australia

Fundamentals of Physics

Chapter 13 Oscillatory Motion.

Chapter 13 Vibrations and Waves.

Halliday/Resnick/Walker Fundamentals of Physics 8th edition

Chapter 15 Oscillatory Motion.

13. Oscillatory Motion. Oscillatory Motion 3 If one displaces a system from a position of stable equilibrium the system will move back and forth, that.

PHY131H1S - Class 21 Today: Oscillations, Repeating Motion Simple Harmonic Motion Oscillations / Circular Motion Connection Potential and Kinetic Energy.

Simple Harmonic Motion

Chapter 15– Oscillations I.Simple harmonic motion (SHM) - Velocity - Acceleration II. Force law for SHM - Simple linear harmonic oscillator - Simple linear.

Chapter 12 Oscillatory Motion. Periodic Motion Periodic motion is motion of an object that regularly repeats The object returns to a given position after.

Chapter 13: Oscillatory Motions

Chapter 12 Oscillatory Motion.

Chapter 16 Oscillations Guitar string; drum; diaphragms in telephones and speaker systems; quartz crystal in wristwatches …. Oscillations in the real world.

A. Introduction 1. Oscillations: motions that repeat themselves a)Swinging chandeliers, boats bobbing at anchor, oscillating guitar strings, pistons in.

Simple Harmonic Motion

Simple Harmonic Motion

OSCILLATIONS Chapter 15. Simple Harmonic Motion (SHM) Systems.

SIMPLE HARMOIC MOTION CCHS Physics.

Chapter 15 Oscillations What is Physics? Simple Harmonic Motion The Force Law for Simple Harmonic Motion Energy in Simple Harmonic.

15.1 Motion of an Object Attached to a Spring 15.1 Hooke’s law 15.2.

Chapter 15 Oscillatory Motion.

Chapter 15 Oscillations.

Chapter 15 Oscillatory Motion.

16.1 Simple Harmonic Motion

Chapter 15 Oscillatory Motion. Intro Periodic Motion- the motion of an object that regularly repeats There is special case of periodic motion in which.

Copyright © 2010 Pearson Education, Inc. Lecture Outline Chapter 13 Physics, 4 th Edition James S. Walker.

Copyright © 2009 Pearson Education, Inc. Chapter 14 Oscillations.

Oscillations – motions that repeat themselves Period ( T ) – the time for one complete oscillation Frequency ( f ) – the number of oscillations completed.

Chapter 15 Oscillatory Motion.

Chapter 11 Vibrations and Waves.

PHY 2048C General Physics I with lab Spring 2011 CRNs 11154, & Dr. Derrick Boucher Assoc. Prof. of Physics Sessions 19, Chapter 14.

Chapter 15 Oscillatory Motion. Periodic Motion Periodic motion is motion of an object that regularly repeats The object returns to a given position after.

Chapter 15 Oscillations. Periodic motion Periodic (harmonic) motion – self-repeating motion Oscillation – periodic motion in certain direction Period.

8/8/2011 Physics 111 Practice Problem Statements 14 Oscillations SJ 8th Ed.: Chap 15.1 – 15.5 Oscillations – Basics Hooke’s Law: A Mass on a Spring Simple.

Oscillatory motion (chapter twelve)

Elements of Waves and Thermal Physics Wed. 14:50 – 16:20 Place: Room 2214 Assoc. Prof. H. SAIBI, West building 2, 431, Ito Campus.

Oscillations – motions that repeat themselves Period ( T ) – the time for one complete oscillation Frequency ( f ) – the number of oscillations completed.

Chapter 15 Oscillatory Motion.

Vibrations and Waves Hooke’s Law Elastic Potential Energy Simple Harmonic Motion.

SIMPLE HARMONIC MOTION. STARTER MAKE A LIST OF OBJECTS THAT EXPERIENCE VIBRATIONS:

Periodic Motions.

Oscillations Readings: Chapter 14.

Oscillations. Periodic Motion Periodic motion is motion of an object that regularly returns to a given position after a fixed time interval A special.

Physics 141Mechanics Lecture 21 Oscillation Yongli Gao You may not know it, but every atom/molecule in your body is oscillating. For any system, there's.

1 10. Harmonic oscillator Simple harmonic motion Harmonic oscillator is an example of periodic motion, where the displacement of a particle from.

PHY 151: Lecture Motion of an Object attached to a Spring 12.2 Particle in Simple Harmonic Motion 12.3 Energy of the Simple Harmonic Oscillator.

Harmonic Motion.

Chapter 15 Oscillations.

Oscillations AP Physics C.

Oscillatory Motion.

Oscillations Readings: Chapter 14.

Vibrations & Waves Part 1: Periodic Motion.

Simple Harmonic Motion

Fundamentals of Physics School of Physical Science and Technology

Chapter 15 Oscillations.

Physics : Oscillatory Motion

Chapter 15: Oscillatory motion

Oscillations Simple Harmonics.

Copyright © 2014 John Wiley & Sons, Inc. All rights reserved.

Chapter 15 Oscillations 1.

Simple Harmonic Motion and Wave Interactions

Presentation transcript:

Oscillations Simple Harmonic Motion Velocity and Acceleration in SHM Force Law Torsion Pendula Physical Pendula SHM and Uniform Circular Motion Damped SHM Forced Oscillations and Resonance pps by C Gliniewicz

The regular back and forth movement of an object is called harmonic motion. Frequency is the number of oscillations that are completed each second. The SI unit of frequency is the hertz (Hz). The period is the time for one cycle to be completed. The period is the inverse of the frequency. Simple Harmonic Motion is a periodic motion in a sinusoidal manner. The position is described by The amplitude, , is the term in front of the cosine function. It is the maximum distance the object moves from the rest position. The phase angle is the symbol φ. The angular frequency is ω. The velocity of the particle is simple harmonic motion is the derivative of position function. pps by C Gliniewicz

The potential energy in simple harmonic motion is elastic energy. The acceleration is simple harmonic motion is the derivative of the velocity. In simple harmonic motion, the acceleration is proportional to the displacement, but opposite in sign and the two quantities are related by the square of the angular frequency. The force causing the motion is described by Hooke’s Law. One can combine the acceleration and Newton’s Second Law to find the force. Solving for ω, The potential energy in simple harmonic motion is elastic energy. The kinetic energy in simple harmonic motion is translational kinetic energy. pps by C Gliniewicz

A pendulum can be created by twisting an object. The total energy of the system is the sum of the potential and kinetic energies. A pendulum can be created by twisting an object. A real pendulum can have a complicated distribution of mass, much different from a simple pendulum. One needs to know the location of the center of mass, its distance from the pivot and the moment of inertia about the pivot. Knowing these quantities, one can solve for the acceleration of gravity at any location. Geologists surveying for metals have done these measurements. pps by C Gliniewicz

Simple harmonic motion is just the projection of uniform circular motion on a diameter of the circle in which the motion occurs. A pendulum swinging through air eventually comes to a stop due to the drag force created by the air. A pendulum in a more viscous fluid would stop even faster. The fluid provides a drag force based on the speed with which the pendulum moves. The drag is a damping force. For a spring pendulum pps by C Gliniewicz

A person on a swing being pushed by another is undergoing forced oscillations. Two angular frequencies are involved, the natural frequency of the swing and the driving frequency. If the two frequencies are equal, then resonance occurs and the swing will reach large amplitude. This resonance can be disastrous in some situations such as Tacoma Narrows Bridge collapse or the collapse of buildings during the Mexico City earthquake.