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A network model of processing in morphology

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Title: A network model of processing in morphology


1
A network model of processing in morphology
  • Dick Hudson
  • UCL
  • www.phon.ucl.ac.uk/home/dick/home.htm

2
Plan
  • The theoretical framework Word Grammar
  • A tiny challenge find a word
  • A small challenge take account of context
  • A theory of processing
  • A modest challenge do morphology
  • A fair challenge plan a word
  • A research strategy

3
Word Grammar
  • The whole of language is a network.
  • Links as well as nodes are classified by is-a
    links.
  • Is-a links allow default inheritance.
  • For example, the word CAT

4
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5
A tiny challenge
  • How do we work out that a word pronounced /kat/
    means Cat?
  • I.e. how do we use a network to connect /kat/ to
    Cat?
  • An uncontroversial answer by spreading
    activation
  • Spreading activation explains
  • Priming (e.g. doctor primes nurse)
  • Speech errors (e.g. doctor replaces nurse)

6
From /kat/ to Cat
  • Activation spreads blindly
  • from /kat/
  • via CAT
  • to Cat
  • Like this

7
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8
and back?
9
The research questions
  • Q1. Are comprehension and production different
    processes?
  • Q2. Is lexical processing different from
    morphology (and syntax and )?
  • Q3. Exactly how does spreading activation help?
  • Q4. How does context contribute?

10
Q4. Context a small challenge
  • How do we work out that /bat/ means winged
    mouse when were thinking of winged mice?
  • The winged-mouse concept is already active, so it
    becomes more active than cricket-bat.

11
What kind of bat?
12
So what?
  • A model of processing must be
  • Interactive, allowing information to interact
    freely
  • NOT modular, limiting flow of information
  • A model of knowledge must be
  • Integrated, with many links between language and
  • general knowledge
  • contextual knowledge

13
Q3. How spreading activation helps
  • Spreading activation is necessary.
  • But not sufficient. Processing also requires
  • Creation of new nodes.
  • Guidance provided by the new nodes.

14
New nodes for tokens
  • Every token needs a new node because
  • Its a distinct concept which we monitor and may
    remember.
  • It may even be deviant, e.g. mispronounced.
  • So we create a new node for each token.
  • E.g. we hear /kat/ and create X.

15
What we know about tokens
  • A token is partially known.
  • E.g. For X we know
  • X has /k/ /a/ /t/ as its parts.
  • X is-a Y (not known).
  • Y is-a form.
  • The known properties are the source of the
    processing.
  • Theyre highly active because recent.

16
What we dont know about tokens
  • We dont know some properties.
  • Hearing we dont know unobservable properties
    (meaning, etc).
  • Speaking we dont know observables.
  • We want to know some of these properties.
  • So these nodes are also highly active.
  • These properties are the target.

17
Activation is guided
  • Therefore activation always spreads from at least
    two nodes.
  • The source
  • already enriched and active.
  • The target
  • Needs enrichment.
  • These two nodes guide activation intrinsically.
  • So we dont need extrinsic control.

18
How to get rich.
  • Impoverished nodes need to become rich.
  • How?
  • By marrying a rich node.
  • This is binding poor node rich node
  • An active token variable binds to its most active
    sister.
  • For example, Y binds to cat.

19
From /kat/ to cat
20
The best fit principle
  • An impoverished node binds to its most active
    sister.
  • NB spreading activation is global,
  • activation may come from any part of the network
  • This guarantees the best global fit.
  • So context can override form
  • We recognise ltthatgt as a wrong ltthangt.

21
Inheritance
  • Active token nodes
  • Bind to the most active sister(s).
  • Inherit from their mother(s)
  • So

22
After the wedding .
23
The inheritance!
24
An algorithm for processing
  • Add active nodes for tokens.
  • Spread activation.
  • Bind active token variables to constants.
  • Inherit to active tokens.
  • And do it all again.

25
So what?
  • Spreading activation has to interact with
    node-creation
  • not found in most other models.
  • Processing in a network changes the network nodes
  • Not just their activity levels

26
Selective binding
  • When we hear a word, we look for
  • its sense
  • NOT its etymology or its French translation
  • Unless were discussing etymology.
  • Why?
  • Because the sense link is usually more active.
  • Why?

27
Why not etymology?
28
Links between links
  • Every link is-a some more general link.
  • So activation can flow from link to link.
  • So some links start more active than others.
  • So we concentrate processing resources on
    interesting properties.

29
Q2. How about morphology (etc)?
  • How do we recognise /kats/?
  • Just the same procedure.
  • But the processor activates two models
  • CAT, via /kat/ and cat
  • Plural, via /s/ and s
  • This requires multiple default inheritance.

30
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31
So what?
  • Complex combinatory patterns can be
  • inherited.
  • bound.
  • If it works for morphology, maybe it will work
    for syntax too?

32
Q1. Is production the same?
  • Yes.
  • But the target and source are reversed.
  • E.g.
  • Source Cat
  • Target ? ( /kat/)
  • The direction of processing is decided by the
    choice of target, not by the structure of the
    system.

33
A research strategy
  • How to go beyond hopes, promises and faith?
  • Build a computer model of a processor.
  • Add a database for a linguistic network.
  • See if it works.

34
Meet WGNet
35
The team
  • The programmer Geoff Williams
  • The consultant Sean Wallis
  • The linguist Jasper Holmes
  • The sponsor ESRC

36
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37
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38
Morphology
39
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40
Inheritance
41
Conclusion
  • Maybe all mental interaction with the world
    follows the same principles
  • Spreading activation.
  • Default inheritance.
  • Binding according to the Best Fit principle.

42
Thank you
  • www.phon.ucl.ac.uk/home/dick/home.htm
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