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Continuous System Modeling

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Object-oriented Modeling in the Service of Medicine Fran ois E. Cellier, ETH Z rich ngela Nebot, Universitat Polit cnica de Catalunya – PowerPoint PPT presentation

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Title: Continuous System Modeling


1
Object-oriented Modeling in the Service of
Medicine
François E. Cellier, ETH Zürich
Àngela Nebot, Universitat Politècnica de Catalunya
2
System Complexity and theUnderstandability of
Models
  • As the systems that are being analyzed by
    mathematical models have grown in complexity over
    the years, they have become increasingly
    difficult to interpret and maintain.
  • Modelers need to concern themselves with the
    understandability and maintainability of their
    models.
  • Tools need to be developed that support them in
    this endeavor.

3
Object-oriented Modeling
  • The object-oriented modeling paradigm enables the
    modeler to encapsulate knowledge in such a way
    that snippets of knowledge can be translated to a
    language familiar to the domain expert.
  • The complexity of the models is locally contained
    by encapsulation and hierarchical composition of
    models.
  • Models are being made more easily understandable
    by exploiting the two-dimensional nature of
    planar graphics.

4
Graphical Modeling
  • Models of subsystems can be encapsulated as
    graphical objects, called icons.
  • The icons can be topologically interconnected to
    form a two-dimensional network.
  • Sub-networks of graphical objects can be grouped
    together to form new objects, for which icons can
    be designed. In this way, systems can be
    hierarchically composed from sub-systems forming
    a tree.
  • The leaves of the tree must be described by
    equations.

5
Bond Graph Modeling
  • Bond graphs are one type of graphical
    object-oriented models.
  • They describe the power flow through a physical
    system.
  • Since energy and power flow are common to all
    types of physical systems, bond graphs are domain
    independent.
  • The equation-based leaf models of bond graphs can
    be pre-coded for all domains.

6
The Bond Model
  • The modeling of physical systems by means of bond
    graphs operates on a graphical description of
    energy flows.
  • The energy flows are represented as directed
    harpoons. The two adjugate variables, which are
    responsible for the energy flow, are annotated
    above (intensive potential variable, e) and
    below (extensive flow variable, f) the
    harpoon.
  • The hook of the harpoon always points to the
    left, and the term above refers to the side
    with the hook.

7
Sources in Bond Graph Representation
?
?
8
Passive Electrical Elements in Bond Graph
Representation
?
?
?
9
Junctions
?
?
10
An Example I
11
An Example II
12
An Example III
13
Causal Bond Graphs
  • Every bond defines two separate variables, the
    effort e and the flow f.
  • Consequently, we need two equations to compute
    values for these two variables.
  • It turns out that it is always possible to
    compute one of the two variables at each side of
    the bond.
  • A vertical bar symbolizes the side where the flow
    is being computed.

14
Causalization of the Sources
U0 f(t)
I0 f(t)
15
Causalization of the Passive Elements
16
Causalization of the Junctions
Junctions of type 0 have only one flow equation,
and therefore, they must have exactly one
causality bar.
Junctions of type 1 have only one effort
equation, and therefore, they must have exactly
(n-1) causality bars.
17
Causalization of the Bond Graph
e
18
The Four Base Variables of the Bond Graph
Methodology
  • Beside from the two adjugate variables e and f,
    there are two additional physical quantities that
    play an important role in the bond graph
    methodology

Generalized Momentum
q ? f dt
Generalized Position
19
Relations Between the Base Variables
20
Effort Flow Generalized Momentum Generalized Position
e f p q
Electrical Circuits Voltage u (V) Current i (A) Magnetic Flux ? (Vsec) Charge q (Asec)
Translational Systems Force F (N) Velocity v (m / sec) Momentum M (Nsec) Position x (m)
Rotational Systems Torque T (Nm) Angular Velocity ? (rad / sec) Torsion T (Nmsec) Angle ? (rad)
Hydraulic Systems Pressure p (N / m2) Volume Flow q (m3 / sec) Pressure Momentum G (Nsec / m2) Volume V (m3)
Chemical Systems Chem. Potential ? (J / mol) Molar Flow ? (mol/sec) - Number of Moles n (mol)
Thermodynamic Systems Temperature T (K) Entropy Flow S (W / K) - Entropy S (J / K )
21
Hemodynamics
  • The hemodynamics describe the flow of blood
    through the heart and the blood vessels, i.e.,
    the flow of blood through the cardiovascular
    system.
  • The hemodynamics of the human body can be
    interpreted as a hydromechanical system. Blood
    is similar to water, blood vessels can be
    inerpreted as pipes, and the heart chambers act
    as hydraulic pumps.
  • Some of the chambers and vessels contain valves
    that act like check valves, preventing a backflow.

22
Transporter Model I
Icon Window
Diagram Window
23
Transporter Model II
Equation window
Documentation window
24
Container Model
Icon Window
Diagram Window
25
Valve Model (Transporter)
Diagram Window
26
Heart Chamber (Container)
Icon Window
Diagram Window
27
Left Ventricle (Heart Chamber)
Diagram Window
28
The Heart
Icon Window
Diagram Window
29
The Thorax
Diagram Window
30
The Cardiovascular System
Icon Window
31
The Cardiovascular System
32
Simulation Results (Valsalva Maneuver)
33
Summary
  • Object-oriented graphical modeling has helped us
    translate a hydro-mechanical model of the
    cardiovascular system into a representation that
    medical personnel can interpret and deal with.
  • The knowledge at each layer was suitably
    encapsulated for limiting the local complexity to
    a level that can be represented on a single
    screen.
  • No manual translation from the high-level
    representation to executable simulation code is
    needed. The graphical model at each level
    contains all of the model equations at that level
    and underneath it. Hence the model can be
    compiled in a fully automated fashion and
    simulated thereafter.
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