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MATHEMATICAL FOUNDATIONS OF QUALITATIVE REASONING

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... OF QUALITATIVE REASONING. Louise-Trav -Massuy s, Liliana Ironi, Philippe Dague ... Different formalisms for modeling physical systems ... – PowerPoint PPT presentation

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Title: MATHEMATICAL FOUNDATIONS OF QUALITATIVE REASONING


1
MATHEMATICAL FOUNDATIONS OF QUALITATIVE REASONING
  • Louise-Travé-Massuyès, Liliana Ironi, Philippe
    Dague
  • Presented by Nuri Tasdemir

2
Overview
  • Different formalisms for modeling physical
    systems
  • Mathematical aspects of processes, potential and
    limitations
  • Benefits of QR in system identification
  • Open research issues

3
QR as a good alternative for modeling
  • cope with uncertain and incomplete knowledge
  • qualitative output corresponds to infinitely many
    quantitative output
  • qualitative predictions provide qualitative
    distinction in systems behaviour
  • more intuitive interpretation

4
QR
  • Combine discrete states-continous dynamics
  • Finite no. of states transitions obeying
    continuity constraints
  • Behaviour sequence of states
  • Domain abstraction
  • Function abstraction

5
Domain Abstraction and Computation of Qualitative
States
  • Real numbers ? finite no. of ordered symbols
  • quantity space totally ordered set of all
    possible qualitative values
  • Qualititativization of quantitave operators
  • a Q-op b Q(x op y) Q(x) a and Q(y) b
  • C set of real valued constraints
  • Sol(C) real solutions to C
  • Q(C) set of qualitative constraints obtained
    from C
  • Soundness ? C, Q(Sol(C)) ? Q-Sol(Q(C))
  • Completeness ?Q-C, Q-Sol(Q-C) ?
    Q(Sol(C))

6
Reasoning about Signs
  • Direction of change
  • S-,0,,?
  • Qualitative equality ()
  • ?a,b S, (a b iff (a b or a ? or b
    ?))

7
Reasoning about Signs
  • Quasi-transitivity
  • If a b and b c and b ? ? then a c
  • Compatibility of addition
  • a b c iff a c - b
  • Qualitative resolution rule
  • If x y a and x z b and x ? ?
  • then y z a b

8
Absolute Orders of Magnitude
  • S1 NL,NM,NS,0,PS,PM,PL
  • S S1 ? X,Y ? S1-0 and XltY, where X lt Y
    means ? x ? X and ? y ? Y, x lt y
  • S is semilattice under ordering ?
  • define q-sum and q-product in lattice
  • commutative, associative, is distributive
    over
  • (S, , , ) is defined as Q-Algebra

9
Semi-Lattice Structure
10
Relative Order of Magnitude
  • Invariant by translation
  • Invariant by homothety (proportional transf.)
  • A Vo B A is close to B
  • A Co B A is comparable to B
  • A Ne B A is negligible with respect to B
  • x Vo y ? y Vo x
  • x Co y ? y Co x
  • x Co y, y Vo z ? x Co z
  • x Ne y ? (x y) Vo y

11
Qualitative Simulation
  • Three approaches
  • 1-the component-centered approach of ENVISION by
    de Kleer and Brown
  • 2-the process-centered approach of QPT by Forbus
  • 3-the constraint-centered approach of QSIM by
    Kuipers

12
Q-SIM
  • Variables in form ltx,dx/dtgt
  • transitions obtained by MVT and IVT
  • P-transitions one time point ? time interval
  • I-transitionstime interval ? one time point
  • Temporal branching
  • Allens algebra does not fit to qualitative
    simulation

13
(No Transcript)
14
Allens Algebra
The Allen Calculus specifies the results of
combining intervals. There are precisely 13
possible combinations including symmetries (6 2
1)
15
Time Representation
  • Should time be abstracted qualitatively?
  • State-based approach(Struss) sensors give
    information at sampled time points
  • Use continuity and differentiability to constrain
    variables
  • Use linear interpolation to combine x(t), dx/dt,
    x(t1)
  • uncertainty in x causes more uncertainty in dx/dt
    so use sign algebra for dx/dt

16
System Identification
  • Aim deriving quantitative model looking at input
    and output
  • involves experimental data and a model space
  • underlying physics of system (gray box)
  • incomplete knowledge about internal system
    structure ( black box)
  • Two steps
  • (1) structural identification(selection within
    the model space of the equation form)
  • (2) parameter estimation(evaluation of the
    numeric values of the equation unknown parameters
    from the observations)

17
Gray-Box Sytems
  • RHEOLO ? specific domain behaviour of
    viscoelastic materials
  • instantaneous and delayed elasticity is modeled
    with same ODE
  • Either
  • (1)the experimental assesment of material (high
    costs and poor informative content) or
  • (2) a blind search over a possibly incomplete
    model space (might fail to capture material
    complexity andmaterial features
  • QR ? brings generality to model space M (model
    classes)
  • S structure of material
  • Compare QB(S) with Q(S)
  • QRAqualitative response abstraction

18
Gray-Box Sytems
19
Black-Box Sytems
  • given input and output find f
  • difficult when inadequate input
  • Alternative to NNs, multi-variate splines, fuzzy
    systems
  • used successfully in construction of fuzzy rule
    base

20
Conclusion and Open Issues
  • QR as a significant modeling methodology
  • limitations due to weakness of qualitative
    information
  • Open issues
  • - Automation of modeling process
  • - determining landmarks
  • - Compositional Modeling

21
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