SPE1103 2024 Week 9 Lecture Notes - Language Processing Comprehension PDF

Summary

This is a lecture on language processing comprehension, covering key concepts, experimental methods in psycholinguistics, basic processes involved in speech perception, and the terminology and processes of the receptive side of the Levelt model.

Full Transcript

Language
Processing

Comprehension
 Learning Objectives

× Understand key concepts and experimental
methods in psycholinguistics
× Understand basic processes involved in the
perception and comprehension of the speech
signal.
× Understand the terminology and processes of
the receptive side of the Levelt model.

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 Language – but how?!

× Language comprehension is very fast and
automatic.
× We understand an utterance as fast as we hear
or read it.
× This is a great deal of work to be done in a very
short time!

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 Consciousness

× We are not conscious of the complicated
processes we use to understand speech any
more than we are conscious of the
complicated processes of digesting food and
utilising nutrients.
× Psycholinguistics – aims to describe the
processes people normally use in speaking and
understanding language.
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 How do we ‘understand’ language?

× Let’s remember what language is:
× Arbitrary – sounds need to be ‘de-coded’
× Rule-based – morphological and syntactic rules
can be used to organise and interpret incoming
information
× Discrete (made up of many ‘pieces’) need all the
pieces to make the whole
× Creative – meaning cannot be accessed as a whole
(e.g. whole sentences)
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 Activity

× Take the following steps to comprehension.
× Place them in order from start to finish (1-7)
× Its ok if you don’t know – have a go
× Check your order as we go through the lecture

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 Step 1

Ear detects the
incoming speech
stream.

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 Speech signal
× A sound = disturbance in the position of air molecules.
× Vocal fold vibration = small pulses/variations air pressure
× Speed of variations= the pitch (fundamental frequency)
× The magnitude of the variations = the loudness
(amplitude)
× Acoustic phonetics = speech sounds, all of which can be
heard by the normal human ear.

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 Auditory discrimination

× Detection of the incoming speech stream depends
upon:
× Adequate hearing mechanisms
× Intact auditory pathways of the brain
× Attention and habituation – focus on the speech
stream and ‘screening out’ of other incoming
stimuli

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 Step 2

Word segmentation

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 The Segmentation Problem

× Speech is a continuous signal.
× Sounds overlap and influence each other.

BUT WE THINK WE HEAR…
× discrete units, such as words, syllables and
phonemes.

Why? = ‘segmentation problem’
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 Normalisation

× When we hear speech we ‘normalise’ it.
× We account for differences in pitch, loudness and
speed.

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 Sound Perception
× People don’t perceive all sounds the same!
× Speakers of English can perceive the difference
between /l/ and /r/ = they affect meaning.
× Speakers of Japanese usually cannot. They are
allophones.

× These perceptual biases develop during the first year
× Prior to 9 months we can detect sounds of all
languages
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‘Finding’ words in the speech stream

× No clear pauses between words – so how do we
find them?
× You (consciously or unconsciously) conduct a
search of your mental lexicon for the
phonological strings you decide are possible
words.
× This process is known as ‘lexical access’ or ‘ word
recognition’.
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‘Finding’ words in the speech stream

× If you heard someone say
× “ The cat chased the rat” –
× You would do a lexical “ look-up” of ‘cat’, ‘rat’
‘chased’
× The segmentation and search of these ‘words’
relies on knowing the:
× phonology, grammatical morphemes and
syntax.
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Lexical access – top down or bottom-up?

× Remember how speech comprehension is fast?
× Its really fast. We can understand spoken language
at a rate of 20 phonemes per second.
× Is there a trick? Is this magic?
× Kind of… we have 2 different systems to help:
× Top-down processing
× Bottom-up processing

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 Bottom-Up Processing

× Comprehension is done step-by-step
× Hear sound = identify word= check
lexicon=interpret phrase.
× The speaker waits until he or she hears ‘the’ and
‘boy’ and then constructs an NP, and then waits for
the next word and so on.
× Allows you to interpret something unexpected, or
to decide that you don’t know something

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 Top-Down Processing

× We ‘predict’ what’s coming next
× Use morphological, semantic and syntactic
information to make an ‘educated guess’
× Makes processing a lot quicker – filters out the
mess and noise
× Evidence is shown by:
× Noise distraction
× Shadow tests
× Speech signal obstruction
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Evidence for Top-Down Processing

× People are asked to identify spoken words in a
noisy environment.
× More errors =
× isolated words vs sentences
× words given in nonsense sentences
× words given in ungrammatical sentences.

= Sentences ‘help’ us identify words
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Evidence for Top-Down Processing

× ‘Shadow’ sentences = people are asked to
repeat each word of a sentence immediately
as they hear it, as fast as they can.
× People often produce words BEFORE hearing
in anticipation of the input.
× Based on their knowledge of syntax and
semantics for the sentence so far…
× “ You walked up the beautiful X”
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Evidence for Top-Down Processing

× People were given sentences in which some
part of the signal is removed with a cough or
buzz
× People ‘think’ they hear the sentence as
complete
× They have difficulty saying exactly where in
the word the noise occurred.
× They ‘correct’ it when they are listening!
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 Video!

× https://www.youtube.com/watch?v=Cz
vgf-Xc-A4

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 Step 3

Lexical Activation

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 What is ‘lexical activation’?

× The process by which we obtain information
about a word from our mental lexicon.
× Theories often relate to how we think we
‘store’ word knowledge

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Review: What do we think is in our lexicons?

× We think each word is linked to:
× Its phonological form
× Its potential morphemes There may be more
× Its potential syntactic class than 1 of these!
× Its meaning or concept

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Review: What is stored for each word?

/r/

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 Review: How is our lexicon organised?

× Lexicon thought to be organised as a semantic network,
like a web of interconnected elements.
× The elements are concepts or nodes that are connected
through having relations with one another.

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How do we ‘access’ the right word?

× Thought to be through ‘spreading activation’
× We activate many words which might ‘fit’
× Activation begins with a single node and spreads
throughout the network.
× Eventually based on context we select only 1
× The ‘word’ which fits the:
× Sounds we hear
× Meaning of the sentence overall
× Meaning of the discourse overall
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 How do we ‘know’?

× We don’t…for sure.

× But we have an idea based on:
× Slips of the ear
× Lexical decision tasks
× Semantic priming

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 Slips of the Ear

× When someone makes an error of comprehension
× Tell us a lot about how language is processed
× “Mine is a long and sad tale!” said the Mouse,
turning to Alice, and sighing.
× “It is a long tail, certainly,”’ said Alice, looking
down with wonder at the Mouse’s tail; “but why
do you call it sad?”
× What does this example tell us?

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 Slips of the Ear

× When someone mishears a word, it is typically a
whole word. 85% of mishearings involve single
words.
× What does this tell us?
× Which one of these is right?
“Let the sky fall, when it “Make a trifle, make a
crumbles crumble
We will stand tall Build my cake tall
And face it all together” And we’ll eat it all together”
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 Lexical Decision Tasks

× Do you know this word? OR Is this a word?
(spoken orally)
× This can be timed (e.g. reaction times).
× Longer = more processing, less good ‘access’
to the word
× We are quicker for commonly used words –
spoken and written (e.g. car vs fig).

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 Semantic Priming

× When we ask someone to make a lexical
decision. E.g. ‘Palm’ is this a word?
× Having just previously asked them to make
a lexical decision about ‘hand’
= quicker reaction time to ‘palm’
Called ‘Semantic Priming’
× Tells us about how we store words – what
does it tell us?
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 Semantic Priming

× After you hear the sentence
× ‘“ The gypsy read the young man’s palm for only a
dollar”.
× ‘Palm’ – primes the word ‘hand’ but also ‘tree’ – why?
× What does this tell us about how words are retrieved?
× Evidence for bottom-up processing
× This priming for unrelated meanings only lasts around
250 milliseconds

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 Complexity of Meaning

× Meanings can be complex & individual - linked to
our world knowledge.
× Imagery and emotion are activated by auditory
information
× Words can also have different connotations to
their denotation (dictionary meaning)
Bossy -- Dominant Nag -- Remind
Cheap -- Inexpensive Nosy -- Inquisitive
Difficult -- Challenging Out of date -- Time-tested
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 Morphological Priming

× Measures of brain activity show priming to
pairs of verb forms such as teach/taught
during the early stages of lexical access.
× What does this tell us about the way we store
words?

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 Phonological Priming

× Significant priming effects were obtained
when the prime and target words shared
phonological information (word initial and
word final)
× What does this tell us about the way we store
words?

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Break!!
Step 4

Parsing

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 Parsing

× Parsing = figuring out the syntactic and
semantic relations among the words and
phrases in a sentence.
× Listeners ‘build’ a phrase structure
representation of the sentence as they hear it.
× Each incoming word is assigned a grammatical
category and ‘attached’ to the tree being
constructed in the mind.
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 Parsing

× Influenced by:
× The rules of grammar/syntax
× The linear presentation of a sentence. E.g.
what comes first
× Intonation and stress
× Word knowledge

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 But HOW do you know this?

× Again we don’t…for sure.

× But we have an idea based on experiments on:
× Shadowing
× Garden Path Sentences – eye gaze and
time
× Intonation hints
× Memory limitations
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 Shadowing Tasks

× Shadowing tasks = repeat what you hear as
rapidly as possible.
× Good shadowers:
× Very short delay of 0.3 of a second
× correct speech errors & missing morphemes
× don’t remember the errors they corrected
× corrections are more likely if they are
predictable

What does this tell us about language parsing?
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Processing Times & Eye Gaze Tracking

× Written sentences are given to subjects
× “ Read this sentence, tell me when you
understand it”
× Length of time taken, eye gaze = how we
process sentences
× ‘garden path’ sentences = show how we
process in real time

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 Garden Path Sentences

× We don’t wait to understand a sentence until it
is done
× We are predicting what comes next and
building structure as we hear or read it.

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 Garden Path Sentences
× The old man the boat *
*Not a typo!
× Sounds wrong huh? You probably read it a few times
and your eyes jumped back and started to read it again.
× You are using some assumptions (based on frequency):
× the subject comes first
× ‘old’ is an adjective, usually used with ‘man’
× ‘man’ is usually a noun, not a verb.

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 Activity – Garden Path Sentences

Read following garden path sentences and:
1. identify how the actual meaning is different to what you first assumed.
2. identify what assumptions you made.

Garden Path Sentences:
× The cotton clothing is made of grows in Mississippi.
× The sour drink from the ocean.
× The man who hunts ducks out on weekends.
× When Fred eats food gets thrown.
× Fat people eat accumulates.
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 Intonation and Stress
Helpful Hints

× Read the garden path sentences again - try to
use intonation to help make the meaning clear.
× Useful huh?! Stress and intonation provide
some clues to syntactic structure.
× E.g. ‘ He lives in the White house’ versus ‘He
lives in the White house’ – can be signalled by
differences in their stress patterns.

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 Parsing Hints
× We seem to interpret incoming speech using 2 ideas to help
us:
1. Minimal attachment – build the simplest structure
(usually not embedded) The horse raced past the barn
fell.
2. Late closure – attach incoming material to the immediate
phrase. The Dr said the patient will die yesterday. You
want to put ‘yesterday’ with ‘will die’ rather than ‘the
doctor said’
× These two hints help us process syntax quickly, but result in
garden pathing 49
 No Real-World Override

× Which of these sentences led you more down the
garden path?

1. The performer sent the flowers was very pleased
2. The florist sent the flowers was very pleased.

× Actually both! Our ‘real world’ knowledge doesn’t
help. Grammar overrides 50
it.
 Memory Limitation

This is the dog that worried the cat that killed the rat that
ate the malt that lay in the house that Jack built
Versus
Jack built the house that the malt that the rat that the cat
that the dog worried killed ate lay in

Embedding has limits!

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 Step 5

Avoid Ambiguity &
Comprehend

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 Lexical Ambiguity
× Example ‘pear/pair’.
× Both are activated, which one is selected?
× Frequency of the words (high vs low) and the context
(meaning of the utterance & discourse so far).
Example:
× Your friend says to you ‘I am hot’..
× Meaning of ‘hot’ activated first will depend on
which is most common for the individual & the
speaking context.
How would it vary across generations? How would
context influence the interpretation?
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Structural Ambiguity

Both meanings are
activated.

Selection against is based
on:
Syntactic frequency
Environmental context
Linguistic context
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 Structural Ambiguity

× Worksheet

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 Stage 6

Update the
discourse record.

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 What is discourse again?
× Discourse – communication, usually taking place
over more than 1 sentence.
× Examples – conversation, debate, speech,
argument, lecture, instructions, story-telling

× To comprehend discourse, you need to reflect on
and remember the whole transaction.

× For ongoing relationships you need to reflect on
and remember your entire discourse history
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Reflecting on the discourse
record

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 Example – debate rebuttal

× Rebuttal requires
debaters to listen to
what is being said by
the other side and
respond to their
arguments.
× Requires precise
comprehension and
memory
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Models of Receptive
Language

Levelt
Stackhouse &
Wells

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Review: What are models of language?

× Theoretical representations of how language is
processed by the brain
× Many different models – each with strengths and
weaknesses
× Two examples: Levelt and Stackhouse and Wells
(named for their authors)
× Allow us to hypothesize areas of impairment and
treatment

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Models of Language Processing

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 Levelt Model
Acoustic-Phonetic Processor
× Requires adequate hearing and
perception
× Identification of speech vs nonspeech
× The phonetic information (e.g. individual
phonemes) are held in working memory
while they are interpreted using the parser
× Prosodic information is used to organise
the incoming speech

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 Levelt Model
Parser
× Phonological decoding – i.e. of
words from the speech stream.
Activation of words in the lexicon
based on sounds
× Words are activated in the lexicon-
linking to phoneme, morpheme,
syntactic and conceptual info
× Grammatical decoding – hearing
each word activates a syntactic
structure – we jump ahead!
× Everything is bi-directional
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 Levelt Model
Conceptualiser
× Looks after the discourse record and
monitors your own speech
× The parsed message is then interpreted
in the context of the discourse record
× This is bi-directional – the discourse
record helps you work out the meaning
× Also allows you to work out the inferred
intention if its different to the literal
(e.g. sarcasm)

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 Stackhouse & Wells Activity

× Match the task for each stage to the model

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 What To Revise

Identify and describe the steps of auditory comprehension,
starting from auditory input to discourse comprehension
Identify the areas of the Levelt model, and what happens at
each area for receptive language – including the
acoustic/phonetic processor, the parser and the conceptualiser.
What evidence exists for how we store and process words using
our brains?

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