Title: Overview
1Overview
- 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
2Introduction 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
3Introduction Solving 1-D systems (II)
Outline
Laplace-Transformation
Differentiation theorem
Laplace transf. of ODE
Transfer function model (TFM)
4Derivation 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
5Derivation 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
6PDE 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
7Solving the PDE - Laplace transformation
Outline
Laplace transformation
- removes temporal derivatives
- includes initial conditions as additive terms
ODE
Boundary cond.
8Solving 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
9Solving the PDE - Transfer function model
TFM
Inverse Laplace transformation of the TFM
with
10Inverse 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
11Discretization 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)
12Realization with recursive systems
- structure contains only multipliers and delays
- can easily be implemented in real-time on DSPs
13Excitation models (I) Plucked
E-bass
guitar to xylophone
spinet
14Excitation 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
15Excitation models (III) Bowed
Finale
16Conclusions
- 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.