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Overview

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Solving MD systems on the example of a vibrating string. Laplace ... spinet. guitar to xylophone. Excitation models (II): Struck (string) (0) b. y ,k. a (N) ... – PowerPoint PPT presentation

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Title: Overview


1
Overview
  • Introduction Solving 1-D systems
  • Derivation of PDEs for MD systems
  • Solving MD systems on the example of a vibrating
    string
  • Laplace transformation
  • Sturm-Liouville transformation
  • Transfer function model
  • Inverse transformations
  • Realization with recursive systems
  • Different string excitations
  • Conclusions

2
Introduction Solving 1-D systems (I)
Example 1-D system only dependent on time t
Electrical network with lumped parameters
Ordinary differential equation (ODE)
R
L
u
(t)
(t)
C
u
c
  • ODE cannot be implemented directly in the
    computer
  • Direct discretization ? computational
    ineffective
  • Laplace transformation and discretization ?
    comp. effective

3
Introduction Solving 1-D systems (II)
Outline
Laplace-Transformation
Differentiation theorem
Laplace transf. of ODE
Transfer function model (TFM)
4
Derivation of PDEs for MD systems (I)
  • Physical based MD systems are often time and
    space dependent
  • they can be described by partial differential
    equations (PDEs)
  • derivation of the PDEs by basic laws of physics
  • here example of a longitudinal vibrating string
  • String with
  • A cross section area
  • E Youngs modulus
  • ? density
  • F force on string element

String element of length dx
5
Derivation of PDEs for MD systems (II)
Strain on string element
Stress on string element
Hookes law
Force on string element
Fundamental law of dynamics
PDE after force elimination
with
? PDE describing longitudinal string vibrations
6
PDE of a transversal vibrating string
Now PDE for a transversal vibrating string with
dispersion and losses
? density A cross section area E Youngs
modulus I moment of inertia tension on the
string damping
PDE
Initial conditions
Boundary conditions
? will be solved in the temporal and spatial
frequency domain
7
Solving the PDE - Laplace transformation
Outline
Laplace transformation
  • removes temporal derivatives
  • includes initial conditions as additive terms

ODE
Boundary cond.
8
Solving the PDE - Sturm-Liouville (SL)
transformation
SL transformation
Differentiation theorem
Eigenvalue problem
?
SL transformation on ODE
  • removes spatial derivatives
  • includes boundary conditions as additive terms

9
Solving the PDE - Transfer function model
TFM
Inverse Laplace transformation of the TFM
with
10
Inverse transformation with respect to space
with
  • inverse spatial transformation only a sum over
    discrete frequencies ยต

? a discretization with respect to time must be
done for computer implementation
11
Discretization with respect to time
  • discretization of time tkt
  • impulse invariant transformation (e.g.
    z-transformation)
  • ? discrete transfer function model

z discrete frequency variable
  • inverse Z transformation by applying the
    shifting theorem
  • ? leads to a recursive system
  • ? summation for inverse spatial transformation
  • N recursive systems in parallel (not infinity to
    avoid aliasing)

12
Realization with recursive systems
  • structure contains only multipliers and delays
  • can easily be implemented in real-time on DSPs

13
Excitation models (I) Plucked
E-bass
guitar to xylophone
spinet
14
Excitation models (II) Struck
(0)
v
y
(0)
h
h
Rec. System
(Hammer)
h
(
)
y
,k
x
a
-
NL
a
(0)
a
(N)
...
...
(0)
b
(N)
b
Rec. Systems
S
....
d
(string)
)
(
y
,k
x
a
Lowest piano note
15
Excitation models (III) Bowed
Finale
16
Conclusions
  • Solution of 1-D systems with transfer function
    models
  • Description of MD systems by PDEs
  • Derivation of a MD system of a vibrating string
    by basic physical laws
  • PDE of a transversal vibrating string was solved
    by
  • Laplace transformation
  • Sturm-Liouville transformation
  • Transfer function model
  • Inverse transformations
  • Discretization
  • Examples of excitation functions (plucked,
    struck, bowed)
  • ? System can be implemented on a DSP for real
    time sound synthesis
  • It is realized on a SHARC DSP (60MHz) with two
    voices
  • and 100 harmonics per voice.
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