Presentation is loading. Please wait.

Presentation is loading. Please wait.

… constant forces  integrate EOM  parabolic trajectories. … linear restoring force  guess EOM solution  SHM … nonlinear restoring forces  ? linear.

Published byRoberta Shepherd Modified over 8 years ago

Similar presentations

Presentation on theme: "… constant forces  integrate EOM  parabolic trajectories. … linear restoring force  guess EOM solution  SHM … nonlinear restoring forces  ? linear."— Presentation transcript:

1 … constant forces  integrate EOM  parabolic trajectories. … linear restoring force  guess EOM solution  SHM … nonlinear restoring forces  ? linear spring x F nonlinear spring? x F Real Oscillators

2 The spring of air : P, V m A P atm +x 0 use Ideal Gas Law: PV=NRT chamber volume: V=Ax Stable Equilibrium at x eq = NRT / (mg + AP atm ) 0 0 EOM

3 Taylor Series Expansions: Turns a function into a polynomial near x = a Example:

4 Expand NRT/x around x eq : Is it safe to linearize it? Better check a unitless ratio. How about: (Yes, excellent choice Dr. Hafner!)

5 Displacement 5% of x eq : 0.05.0025 …. SHM with Perhaps you would prefer…...

6 Simple Pendulum: Length: L Mass: m  mg cos  T mg cos  sin  mg Stable Equilibrium: Displace by  mg cos  -x EOM: Expand it!

7 Derivatives:

8 Now express as a unitless ratio of the dependent variable and some parameter of the system: SHM with Displacement 5% of length: 0.05 0.0000625 …

9 The world is not linear. However, one can use a Taylor expansion to linearize an EOM by assuming only small perturbations around a point of stable equilibrium (which may not be the origin).

Download ppt "… constant forces  integrate EOM  parabolic trajectories. … linear restoring force  guess EOM solution  SHM … nonlinear restoring forces  ? linear."

Similar presentations

Lecture D31 : Linear Harmonic Oscillator

Lecture D31 : Linear Harmonic Oscillator
PHYS 20 LESSONS Unit 6: Simple Harmonic Motion Mechanical Waves

PHYS 20 LESSONS Unit 6: Simple Harmonic Motion Mechanical Waves
Pendulums Physics 202 Professor Lee Carkner Lecture 4 “The sweep of the pendulum had increased … As a natural consequence its velocity was also much greater.”

Pendulums Physics 202 Professor Lee Carkner Lecture 4 “The sweep of the pendulum had increased … As a natural consequence its velocity was also much greater.”
Simple Harmonic Motion

Simple Harmonic Motion
More Oscillations Physics 202 Professor Vogel (Professor Carkner’s notes, ed) Lecture 3.

More Oscillations Physics 202 Professor Vogel (Professor Carkner’s notes, ed) Lecture 3.
Harmonic Oscillator. Hooke’s Law  The Newtonian form of the spring force is Hooke’s Law. Restoring forceRestoring force Linear with displacement.Linear.

Harmonic Oscillator. Hooke’s Law  The Newtonian form of the spring force is Hooke’s Law. Restoring forceRestoring force Linear with displacement.Linear.
Simple Harmonic Motion Physics 202 Professor Lee Carkner Lecture 3.

Simple Harmonic Motion Physics 202 Professor Lee Carkner Lecture 3.
Physics 151: Lecture 30, Pg 1 Physics 151: Lecture 33 Today’s Agenda l Topics çPotential energy and SHM çResonance.

Physics 151: Lecture 30, Pg 1 Physics 151: Lecture 33 Today’s Agenda l Topics çPotential energy and SHM çResonance.
Nonlinear Systems Modeling: some nonlinear effects Standard state equation description Equilibrium points Linearization about EPs Simulation and insight.

Nonlinear Systems Modeling: some nonlinear effects Standard state equation description Equilibrium points Linearization about EPs Simulation and insight.
The simple pendulum Energy approach q T m mg PH421:Oscillations F09

The simple pendulum Energy approach q T m mg PH421:Oscillations F09
Simple Harmonic Motion

Simple Harmonic Motion
Duffing Oscillator.

Duffing Oscillator.
Physics 151: Lecture 32, Pg 1 Physics 151: Lecture 32 Today’s Agenda l Topics çThe Pendulum – Ch. 15 çPotential energy and SHM.

Physics 151: Lecture 32, Pg 1 Physics 151: Lecture 32 Today’s Agenda l Topics çThe Pendulum – Ch. 15 çPotential energy and SHM.
Oscillations Phys101 Lectures 28, 29 Key points:

Oscillations Phys101 Lectures 28, 29 Key points:
1.To recognise that a loaded spring is an application of SHM 2.To review Hooke’s law 3.To establish the period of an oscillating loaded spring 4.To review.

1.To recognise that a loaded spring is an application of SHM 2.To review Hooke’s law 3.To establish the period of an oscillating loaded spring 4.To review.
9 Differential Equations. 9.1 Modeling with Differential Equations.

9 Differential Equations. 9.1 Modeling with Differential Equations.
Physics 207: Lecture 19, Pg 1 Lecture 20Goals: Wrap-up Chapter 14 (oscillatory motion) Wrap-up Chapter 14 (oscillatory motion) Start discussion of Chapter.

Physics 207: Lecture 19, Pg 1 Lecture 20Goals: Wrap-up Chapter 14 (oscillatory motion) Wrap-up Chapter 14 (oscillatory motion) Start discussion of Chapter.
The simple pendulum L m θ. L m θ mg The simple pendulum L m θ mg mg sinθ.

The simple pendulum L m θ. L m θ mg The simple pendulum L m θ mg mg sinθ.
NAZARIN B. NORDIN What you will learn: Load transfer, linear retardation/ acceleration Radius of gyration Moment of inertia Simple.

NAZARIN B. NORDIN What you will learn: Load transfer, linear retardation/ acceleration Radius of gyration Moment of inertia Simple.
… constant forces  integrate EOM  parabolic trajectories. … linear restoring force  guess EOM solution  SHM … nonlinear restoring forces  ? linear.

… constant forces  integrate EOM  parabolic trajectories. … linear restoring force  guess EOM solution  SHM … nonlinear restoring forces  ? linear.

Similar presentations

Ads by Google