Lecture 8: Differential Equations II - PowerPoint PPT Presentation

1 / 26
About This Presentation
Title:

Lecture 8: Differential Equations II

Description:

... oscillator is one whose equation of ... This condition is called resonance. ... there is a different solution which describes the situation after a finite time. ... – PowerPoint PPT presentation

Number of Views:88
Avg rating:3.0/5.0
Slides: 27
Provided by: steveb99
Category:

less

Transcript and Presenter's Notes

Title: Lecture 8: Differential Equations II


1
Lecture 8 Differential Equations II
  • Lecture 8
  • Second order differential equations
  • Damped harmonic motion
  • Forced harmonic motion
  • Problem Set 8
  • Finish 5.00pm

2
First order differential equations
  • A differential equation is an equation which
    contains one or more derivatives of some quantity
    (y)
  • The order of the differential equation is the
    order of the highest derivative which occurs in
    the equation.
  • a, b and c are constant coefficients

First order
Second order
3
Examples in physics
  • We have already met a special case of this
    equation
  • This describes simple harmonic motion
  • Note that if we have the additional term
  • Then if yf1(x) and yf2(x) are solutions then
  • Is also a solution ? This is the principle of
    superposition This principle also applied to SHM.

4
Damped Harmonic Motion
  • A damped harmonic oscillator is one whose
    equation of motion is
  • Where is the ?0 angular frequency without damping
    (SHM) and ? is the damping term.
  • Damping arises from frictional forces of some
    kind in an oscillator.
  • The negative sign is because the force opposes
    the motion.

Spring constant
eg in a spring
5
Damped Harmonic Motion
  • Resistance in an electrical circuit
  • In differential form
  • The differences from SHM arise because energy is
    lost due to resistive heating.

R
V
L
C
So for this example
6
Damped Harmonic Motion
  • Solution
  • Try a solution of the form
  • This must be true for all the times t, so

7
Damped Harmonic Motion
  • Our original equation is linear and homogenous
    and so the principle of superposition applies
    the general solution is
  • Where A and B are constants that can be derived
    from the initial conditions.
  • If we define
  • Then the solution is

8
Damped Harmonic Motion
  • There are 3 different cases
  • Then q is real and positive. There are no
    oscillations because the energy loss is so great
    that the system cannot complete one cycle.
  • The actual motion depends on the initial
    conditions (eg is x is the displacement of a
    particle then the constants A and B are
    determined from the initial position and
    displacement).

(i) Heavy damping (dead beat)
9
Damped Harmonic Motion
x
Initial velocity
t
Up to here Determined by initial conditions
  • In an electrical circuit
  • for no oscillations

10
Damped Harmonic Motion
  • Light damping
  • In this case q is imaginary.
  • Let
  • So we get damped oscillations of angular
    frequency (smaller than 0)
  • If x represents a physically observable quantity
    it must be real.
  • Choose A and B to be complex numbers in order to
    make x real

Oscillations described by sin() Term and decay
exponentially
11
Damped Harmonic Motion
  • This is damped harmonic motion
  • In the electrical case
  • Oscillations for

12
Damped Harmonic Motion
  • (iii) ie q0 Critical damping
  • This corresponds to an oscillation of infinite
    period or zero frequency.
  • In this case, the most general solution is

13
Damped Harmonic Motion
x
t
  • At large times for fixed value of ?0 the value
    corresponds to the most rapid decay possible
    without overshooting and oscillations.
  • Useful in needle indicators.

14
Energy Loss
  • In a mechanical oscillator
  • then
  • The energy is quite a complicated function of t.

15
Energy Loss
  • For the case of light damping
  • Can neglect the first term in dx/dt
  • The energy decays exponentially with a decay
    constant that is twice that of the amplitude.
  • Describe decay by Quality factor, Q

So
16
Forced Harmonic Motion
  • This occurs when the harmonic oscillator is acted
    on by a sinusoidally varying external force
    driving force.
  • The equation becomes
  • An example would be an electrical circuit

R
L
C
17
Forced Harmonic Motion
  • Lets consider a situation with no damping
  • Try a solution of the form
    with Agt0
  • As the time dependence must cancel out we either
    have
  • or

18
Forced Harmonic Motion
  • 3 different cases
  • The requirement Agt0 means that ?0
    and so the displacement x(t) is in phase with the
    driving force.
  • Then so the displacement
    is 180o out of phase with the driving force
  • This condition is called resonance.
  • The amplitude A is infinite the driving force
    had supplied an infinite amount of energy which
    would take an infinite amount of time if it was
    supplied at a finite rate.

19
Forced Harmonic Motion
  • For this special case there is a different
    solution which describes the situation after a
    finite time.
  • This function describes the response of the
    system to the driving force

Amplitude grows with time
Displacement lags by ?/2
A
A0
?0
?
20
Forced Harmonic Motion
  • With damping (effects of energy dissipation)
  • The solution has two parts
  • x Forced vibrations Response
  • DHM Remains
  • (steady state)
  • decays as

1
21
Forced Harmonic Motion
  • To find a solution use the method of complex
    exponentials.
  • Introduce a new variable y which obeys
  • (y has no physical significance, it just helps
    the maths)
  • Solve this equation and take the real part z to
    find x.

2
22
Forced Harmonic Motion
  • Try a solution
  • Then
  • This is a solution provided that
  • Put this back into eqn 3, write

3
complex number
23
Forced Harmonic Motion
  • This gives
  • Which can be written in the form

where
and
24
Forced Harmonic Motion
A
Amplitude
A0
?max
?
?
Phase
?0
?
ie at
25
Forced Harmonic Motion
  • These are smoothed out versions of the
    idealised curves for no damping.
  • Maximum amplitude when
  • Amax is not infinite because energy is
    dissipated.
  • At resonance
  • Amplification factor

for light damping
A
High Q factor ? high and narrow peak at the
resonant frequency
?
?0
26
Summary Lecture 8 Diff Eqns II
  • Lecture 8
  • Second order differential equations
  • Damped harmonic motion
  • Forced harmonic motion
  • Problem Set 8
  • Finish 5.00pm
Write a Comment
User Comments (0)
About PowerShow.com