Cognitive Psychology Lecture 9: Conceptual Knowledge 2023 PDF

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This document presents a lecture on conceptual knowledge in cognitive psychology from 2023. The lecture covers various aspects including different approaches to categorization.

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PSYC 5140
Cognitive Psychology

Lecture 9:
Conceptual Knowledge

2023
Instructor: Urs Maurer

Knowledge
• Conceptual knowledge: knowledge that enables us to recognize objects and
events and to make inferences about their properties

• Concept: mental representation used for a variety of cognitive functions
– Meaning of objects, events, and abstract ideas
– Mental representation of a class or individual

• Categorization is the process by which things are placed into groups called
categories
– A category includes all possible examples of a particular concept
– Our knowledge of the world is organized in categories

Why Categories Are Useful
Category “cat” includes: Siamese
cats, Persian cats, wild cats, …

Concepts provide the rules for
creating categories
(A cat is a furry animal that
meows, …)
➔ The mental representation for
“cat” would affect what animals
we place in the “cat” category

What is a cat?

Why Categories Are Useful
• Help to understand individual cases not previously encountered
• “Pointers to knowledge”
– Categories provide a wealth of general information about an item
– Allow us to identify the special characteristics of a particular item

• If there were no such things as categories, we would have a very hard
time dealing with the world

Structure of Lecture
• Basic properties of concepts and categories
• Network models of categorization
• How concepts are represented in the brain

Definitional Approach to Categorization
• Determine category membership
based on whether the object
meets the definition of the
category
• Does not work well
– Works well for some things, such as
geometric objects
– But not for natural objects and
human-made objects

• Not all members of everyday
categories have the same defining
features

Family resemblance

• Family resemblance
– Wittgenstein proposed the idea of family resemblance to deal with the
problem that definitions often do not include all members of a
category
– Things in a category resemble one another in a number of ways
– Allows for some variation within a category
➔ Categorization may be based on determining how similar an object is to
some standard representation of a category

The Prototype Approach
• Prototype = “typical”
– An average representation of the members of a category that are commonly encountered
– Characteristic features that describe what members of that concept are like
– An average of category members encountered in the past

• Prototype approach to categorization: membership in a category is
determined by comparing the object to a prototype that represents the
category

real birds

prototype

The Prototype Approach

The Prototype Approach

Variation in Typicality
• Rate the following example as to whether how well they represent the
category title
Category: «Bird»

Variation in Typicality

Owl

Variation in Typicality

Sparrow

Variation in Typicality

Penguin

Variation in Typicality

Bat

The Prototype Approach
• Not all birds are like robins, blue jays, or sparrows.
• Owls and penguins are also birds
• These variations represent
differences in typicality

• Rosch (1975): S saw a category title
(e.g. birds), and a list of about 50
members of the category
• S were asked to rate the extent to
which each member represented
the category title

The Prototype Approach
• High-prototypicality: category member closely resembles category
prototype
– “Typical” member

– For category “bird” = robin
• Low-prototypicality: category member does not closely resemble
category prototype
– For category “bird” = penguin

The Prototype Approach
• How well do good and poor examples of a category compare to other
items within the category?

• Strong positive relationship between prototypicality and family
resemblance
– Measuring family resemblance: list as many characteristics and attributes as
possible for category members

• When items have a large amount of overlap with characteristics of
other items in the category, the family resemblance of these items is
high
• Low overlap = low family resemblance

The Prototype Approach
• Typicality effect: prototypical objects are processed preferentially
– Highly prototypical objects judged more rapidly
• Sentence verification technique
• An apple is a fruit (yes/no)
• A pomegranate is a fruit (yes/no)

Prototypical objects are named more
rapidly

The Prototype Approach
• Prototypical objects are named first
– When asked to list as many objects in a category as possible, S
tend to list the most prototypical members first
• Prototypical category members are more affected by a priming
stimulus

• S heard the prime (e.g. “green”)
• Two seconds later: they saw a pair of colors side by side
• Were asked to press a key as quickly as possible if the two
were the same

The Prototype Approach

Hearing “green” primes a highly prototypical “green”

The Prototype Approach

The Exemplar Approach
• Concept is represented by multiple examples
– rather than a single averaged prototype

• Examples are actual category members
– not abstract averages

• To categorize, compare the new item to stored examples
• This approach can explain Rosch’s results
– e.g. objects that are like more of the exemplars are classified faster

• Similar to prototype view
– Representing a category is not defining it
• Different: representation is not abstract
– Descriptions of specific examples

The Exemplar Approach
• Explains typicality effect
• Easily takes into account atypical cases
– Rather than comparing a penguin to an “average” bird, we remember that there
are some birds that don’t fly

• Easily deals with variable categories
– e.g. games

• Which approach do we use? May use both
– Exemplars may work best for small categories
– Prototypes may work best for larger categories

A Hierarchical Organization
• Hierarchical organization: organization in which large more general
categories are divided into smaller, more specific categories

• Is there a “basic” level that is more psychologically important than
other levels?

A Hierarchical Organization
• Rosch’s research indicates that there are different levels of categories
– From general (“furniture”) to specific (“kitchen table”)

• When using categories, we use one of these levels
• Three levels of categories:
– Superordinate level (or global level): “furniture”
– Basic level: “table”
– Subordinate level (or specific level): “kitchen table”

Evidence that Basic-Level Is Special
• Rosch et al. (1976): S were asked to list as many features as they could
that would be common to all or most of the objects in the category
• Going above basic level results in a large loss of information
• Going below basic level results in little gain of information
• ➔ Basic level is psychologically special

Evidence that Basic-Level Is Special

• When S asked to name these objects,
they named them by their basic level
name
• Guitar, rather than electric guitar
(specific) or musical instrument (global)
• Fish, rather than trout or animal

Culture and Categorization
• Rosch’s experiments, were carried out on college under-graduates
– Results: there is a category level, which they called “basic”, that reflects
college undergraduates’ everyday experience
• Coley, Medin & Atran (1997): Asked both undergraduates & horticulturalists
to walk around (campus/Guatemala) and name as specifically as possible 44
different plants
– 75% of the undergrads used “trees”
– Horticulturalists (people who grow plants) used “specific” categories instead, such as “oak”
– Guatemalan Itzaj culture, call an oak tree an “oak” and not a tree

Evidence that Basic-Level Is Special

• Tanaka and Taylor (1991): asked bird
experts and non-experts to name
pictures of objects
• Experts responded by specifying the
birds’ species
• Experts had learned to pay attention
to features of birds that non-experts
were unaware of

People’s knowledge and properties of objects are both
important factors in categorization

Evidence that Basic-Level Is Special

What are you experts in?

Semantic Networks
• Concepts are arranged in
networks that represent the
way concepts are organized
in the mind
• Collins and Quillian (1969)
– Node = category/concept
– Concepts are linked
– Model for how concepts
and properties are
associated in the mind

– Hierarchical model, more
specific to more general

Semantic Networks
• Including “can fly” at every node is inefficient
– This property is placed at a higher level node

• Inheritance
– Lower-level items share properties of higher-level items

• Cognitive economy: shared properties are only stored at
higher-level nodes
• Exceptions are stored at lower nodes
– e.g. “ostrich” would have the property “can’t fly”

Semantic Networks
• Given the network’s hierarchical organization, general concepts are at the
top, and specific ones at the bottom
• Testable prediction: the time it
takes for a person to retrieve
information about a concept
should be determined by the
distance that must be traveled
through the network
• It takes longer to answer “yes” to
“A canary is an animal”
compared to “A canary is a bird”

Semantic Networks
• Spreading activation
– Activation is the arousal level of a node
– When a node is activated, activity spreads out along all connected
links
– Concepts that receive activation are primed and more easily accessed
from memory

Semantic Priming
• Lexical decision task
– Participants read stimuli and are asked to say as quickly as
possible whether the item is a word or not
•

Pair 1

•

Pair 2

•

Pair 3

•

Pair 4

– Fundt

– Bleem

– Chair

– Bread

– Glurb

– Dress

– Money

– Wheat

• Meyer and Schvaneveldt (1971)
– “Yes” if both strings are words; “no” if at
least one was a nonword
– Some pairs were closely associated
– Reaction time was faster for those pairs
• Spreading activation

Semantic Networks
• Criticism of Collins and Quillian
– Cannot explain typicality effects
• Typicality effect: reaction times for statements about an object are faster for
more typical members of a category
• The model instead predicts equal fast reaction times to both “canary” and
“ostrich”, as they are one node a way from “bird”

– Cognitive economy?
• Some evidence that people store specific properties of concepts right at the
node for the concept

– Some sentence-verification results are problematic for the model
• A pig is a mammal. RT= 1,476ms

• A pig is an animal. RT= 1,268ms

The Connectionist Approach
• New approach to networks:
– Criticism of semantic networks
– advances in understanding how information is represented in the brain

• Connectionism: an approach to creating computer models for
representing cognitive processes

• Also called Parallel distributed processing
– Knowledge represented in the distributed activity of many units

• Weights determine at each connection how strongly an incoming signal
will activate the next unit

The Connectionist Approach
• Output units: Receive input from
hidden units
• lines: connections
that transfer
information
between the units

• Units: inspired by
the neurons in
the brain

• Roughly
equivalent to
axons
• Connection
weight: how
signals sent from
one unit either
increase or
decrease the
activity in the next
unit

• Patterns of
activity in these
units represent
concepts and
their properties
• Input units: units activated by
stimuli from the environment

The Connectionist Approach
• High connection weights: result in a strong tendency to excite the next
unit

• Negative connection weights: can decrease excitation or inhibit activation
of the receiving unit
• Activation of units in a network depends on two things:
– The signal that originates in the input units
– The connection weights throughout the network

• A stimulus is represented by the pattern of activity that is distributed
across the other units

Concepts in Connectionist Networks

The Connectionist Approach
• For the network to operate properly, the connection weights have to
be adjusted ➔ learning process

• How learning occurs
– Network responds to stimulus
– Provided with correct response

– Modifies responding to match correct response

The Connectionist Approach
• Error signal
– Difference between actual activity of each output unit and the
correct activity
• Back-propagation: error signal transmitted back through the circuit
• Indicates how weights should be changed to allow the output signal
to match the correct signal
• The process repeats until the error signal is zero
– Initially weak and undifferentiated activation of property units, with many errors
– Error signals are then sent back
– Changes are made in connection weights
– Each learning experience causes only a small change in the connection weights

The Connectionist Approach

The Connectionist Approach
• In connectionist networks: information about each concept is
contained in the distributed pattern of activity across a number of
units
• The operation of connectionist networks is not totally disrupted by
damage
– Graceful degradation: disruption of performance occurs gradually
as parts of the system are damaged
• Connectionist networks can explain generalization of learning.

– Slow learning process that creates a network capable of handling
a wide range of inputs

Google and Connectionism
• At Google:
https://www.youtube.com/watch?v=Zwm2dUNm4Xo

• On Machine Learning:
https://www.youtube.com/watch?v=f_uwKZIAeM0

Categories in the Brain
• Different areas of the brain may be specialized to process information
about different categories
– Patients with category-specific memory impairment

– Poorer performance for “living things” than“nonliving things”
• Sensory-Functional hypothesis: our ability to
differentiate living things and artifacts
depends on a semantic memory system
that distinguishes sensory attributes (living
things) and a system that distinguishes
function (artifacts).
• Predicts: a patient who can’t identify
living things should have impaired
sensory abilities

Sensory-Functional hypothesis
• S-F hypothesis predicts: a patient who can’t identify living
things should have impaired sensory abilities
• Caramazza & Shelton (1998): reported a patient who couldn’t identify
living things, had impaired sensory memory, but who also had
impaired functional ability
• S-F wouldn’t predict this

• S-F hypothesis predicts: a person who can’t identify artifacts
should have impaired functional knowledge
• Ralphs et al. (1998): reported a patient who couldn’t recognize
artifacts but who had an impaired sensory ability

Multiple factors approach
• Search for more factors that divide up concepts within category
• (rather than identifying specific brain areas of networks for different
concepts)
– Mechanical devices (e.g. musical instruments) overlap with:
• artifacts (involve performing actions)
• animals (involve sound and motion)

➔ mechanical devices have a widely distributed semantic
representation:
• regions important for the representation of both living things and artifacts

➔ Patients may be able to identify mechanical devices even if they
perform poorly for other types of artifacts

Multiple factors approach
• Another differentiating factor between animals and artifacts is crowding
• Crowding: When different concepts within a category share many
properties
– e.g., “animals” all share “eyes,” “legs,” and “the ability to move”
– In contrasts, artifacts share fewer properties

• Patients with category-specific impairments, may not have a
category-impairment at all
– Patients may have difficulty recognizing living things because they
have difficulty distinguishing between items that share similar features

Semantic category approach
• Specific neural circuits in the brain for specific categories
– Distributed over a number of different cortical areas
• There may be a limited number of categories that are innately
determined because of their importance for survival
– E.g., faces, body parts, places

• Wilmer et al. (2010) tested this idea by measuring face recognition
ability in monozygotic (identical) and dizygotic (fraternal) twins
– Correlation of scores between identical twins was more than
twice as high as the other group
– There may be genetic basis for the mechanisms involved in face
recognition

The Embodied Approach
• Our knowledge of concepts is based on reactivation of sensory and motor
processes that occur when we interact with the object
– When we use a hammer:
– Different sensory areas are activated due to the hammer’s size, shape, …

– Motor areas are activated that are involved in carrying out actions involved in using a hammer
– When we see a hammer, or see “hammer”, the same areas get activated
– ➔ interaction between action and perception

Mirror Neurons
• Mirror neurons: Neurons that fire when we do a task or when we observe
another doing that same task

• https://www.youtube.com/watch?v=Xmx1qPyo8Ks
• What do mirror neurons have to do with concepts?
– Embodied approach: thinking about concepts causes activation of perceptual and motor
areas associated with the concepts
– Semantic somatotopy: Correspondence between words related to specific body parts
and the location of brain activation
– e.g. kicking, and reading the word “kick” activate the same brain areas

Categories in the Brain

Hauk et al. (2004)

Categories in the Brain
Foci of significant activations
across 13 studies

Carota et al. (2012)

Summary
• The three approaches agree: information about concepts is distributed
across many structures in the brain

• The approaches differ in their emphasis on the type of information that is
most important
– Category-specific approach: specialized areas of the brain and networks connecting
them
– Multiple-factor approach: the role of many different features and properties
– Embodied approach: activity caused by the sensory and motor properties of objects

Some Questions to Consider
• Why is it difficult to decide if a particular object belongs to a particular
category, such as “chair,” by looking up its definition?
• How are the properties of various objects “filed away” in the mind?
• How is information about different categories stored in the brain?