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Rescorla-Wagner Model

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Title: Rescorla-Wagner Model Author: Skinner Last modified by: Skinner Created Date: 2/2/2005 6:29:45 PM Document presentation format: On-screen Show – PowerPoint PPT presentation

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Title: Rescorla-Wagner Model


1
Rescorla-Wagner Model
  • US-processing model
  • Can account for some Pavlovian Conditioning
  • phenomena
  • acquisition
  • blocking
  • unblocking with an upshift
  • conditioned inhibition
  • US-pre-exposure effect
  • Cannot account for some Pavlovian Conditioning
  • phenomena
  • extinction (i.e., spontaneous recovery)
  • unblocking with a downshift
  • latent inhibition
  • temporal factors (i.e., CS-US interval)

2
Pearce-Hall Model
  • attention model of conditioning
  • a CS-processing model
  • according to the model, it is highly adaptive to
    pay
  • pay attention to, or process, CSs that could
    become
  • valid predictors of important outcomes (i.e., USs)
  • it is also adaptive not to pay attention to, or
    process,
  • CSs when the important event is already predicted
    by
  • something else

3
Pearce-Hall Model
  • also based on the concept of surprise
  • when the subject is surprised, attention to, or
  • processing of the CS occurs
  • as the US becomes predicted by a CS, and is less
  • surprising, processing of the CS declines
  • The amount of processing, that is associability
    of a CS,
  • changes on each trial depending on whether the US
    was
  • predicted (on the previous trial)
  • If the US was predicted, then attention to the
    CS
  • declines
  • If the US was not predicted, then attention to
    the CS
  • increases

4
Pearce-Hall Model
?VA k(? VT)
Recall from the RW Model,
k constant salience or associability of the CS
With the PH Model, k changes across trials (CS
processing model, not a US processing model)
5
Pearce-Hall Model
kAN ?N-1 VAN-1
kAN associative strength or associability of
CSA on trial N
?N-1 strength of the US on previous trial
VAN-1 strength of CSA on previous trial (could
become VT if more than one CS)
Important point k depends on what happened on
the previous trial on first exposure, novelty
causes some attention
6
Pearce-Hall Model
kAN ?N-1 VAN-1
Early in training, when the strength of the CS is
low (i.e., ? V is high) see high k value and
thus, more attention to the CS
When the CS is strong in later trials (i.e., ?
V is small) attention to the CS is low
The important point is that attention to the CS
changes across trials
7
Pearce-Hall Model
Attention to, or processing of, the CS can be
measured in terms of an OR (i.e., looking at a L)
This is different than the CR
Support for the PH Model comes from the finding
that subjects orient towards novel stimuli and
maintain their orientation, provided the
stimulus is a poor predictor of the US
8
Kaye Pearce compared the OR in 3 groups of rats
Group 1
L alone
Group 2
L
condensed milk
Group 3
L
milk/no milk (inconsistent/random)
Looked at OR to L
Attention (OR) was high on the first trial since
the L is novel
9
(No Transcript)
10
kAN ?N-1 VAN-1
Group 1 L alone
k stays low (decrease attention)
Group 2 L milk
VA gets bigger over time which makes the total
term smaller (this means small k and decrease in
attention)
Group 3 L milk/no milk
Attention remains high since VA is low
11
When the CS is not a good predictor, rats
maintained their attention to the cue If the CS
is a good predictor (of the US or no US), then
attention decreases
12
Pearce-Hall Model and Blocking
  • like the RW Model, all CSs combine to predict
    the US
  • if one CS already predicts the US, then pay less
  • attention to all CSs on that trial
  • when a new CS is added, should pay attention to
    it
  • because it is novel
  • therefore, should see some conditioning to the
    new cue
  • on the first trial based on the salience of the CS

13
Pearce-Hall Model and Blocking
  • only after first trial is over would the animal
    know that
  • nothing new had happened
  • according to the model, should see blocking from
    trial
  • 2 and onwards
  • however, in most cases see blocking right from
    the start

14
Pearce-Hall Model and Unblocking
kAN ?N-1 VAN-1
  • when subjects encounter a US that is not well
    predicted,
  • or is surprising (either bigger or smaller), then
    subjects
  • should pay attention to all CSs on that trial and
    get
  • unblocking
  • because the formula includes the absolute value
    of
  • ?N-1 VAN-1 it doesnt matter if the US is
    bigger or smaller
  • if the US changes well see increase in
    attention and
  • thus, learning

15
Pearce-Hall Model and latent inhibition
When the CS is given by itself, see decrease in
attention to the CS over trials (? 0)
However, a problem with the model is that it
cannot explain the context-specificity of LI
If CS pre-exposures are given in one context, and
conditioning occurs in a second context, there
is no retardation of learning
According to the model, k should be low
regardless of context
16
The Comparator Hypothesis
  • developed by Ralph Miller
  • this is a model of performance, not learning
  • according to Miller, all CSs have excitatory
    power
  • there is no separate inhibitory process
  • the strength of performance (or CR) depends on
    the
  • relative strength of the various excitatory
    associations
  • a subject compares the excitatory strength of
    the
  • explicit CS to the strength of other cues present
    in the
  • situation, such as apparatus cues

17
The Comparator Hypothesis
  • when the strength of a CS is relatively greater
    than
  • the background cues, get a measurable CR
  • when the strength of a CS is weaker than the
  • background cues, get weakened level of excitation
    (what
  • others might call inhibition)
  • according to the theory, the competition between
    two
  • excitatory reactions controls performance

18
The Comparator Hypothesis
  • during normal excitatory, get CS-US pairings
    but
  • the US is also paired with background cues and
    these
  • background cues are the comparator stimuli
  • because these background cues are also present
    during
  • the no-US condition, they are typically weaker
    than
  • the explicit CS
  • so, under normal conditioning procedures, the CS
    has
  • stronger excitatory strength than the comparator
    cues

19
The Comparator Hypothesis
  • during inhibitory conditioning, the CS is weak
    relative
  • to the background cues
  • during inhibitory conditioning, have CS no US
  • pairings but the background cues are paired with
    the US
  • and the absence of the US
  • thus, the CS is weaker than the background cues
    and
  • see little CR to the CS

20
The Comparator Hypothesis
  • Prediction After training one can manipulate
    the excitatory value of the context and this will
    affect the excitatory value of the CS
  • E.g. After conditioning, give repeated exposure
    to the context alone followed by exposure to CS
  • One will see greater responding to CS

21
Temporal Factor Models
  • designed to explain the effects of time in
    conditioning
  • effects of time not considered in US-processing
    models
  • like the RW model nor in CS-processing models
    like the
  • PH model
  • CS-US interval is one important temporal variable
  • a more critical temporal variable appears to be
    the
  • ratio of the ISI to ITI

22
Midterm Exam Thursday, Feb. 17, 2005
  • covers everything up to and including todays
    lecture
  • in the case of a storm, the exam will take place
    during
  • the very next class
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