F24 Midterm 2 Study Guide PDF

Summary

This study guide details the content for a midterm exam on memory. The exam covers theories, models, and concepts related to memory functions.

Full Transcript

Midterm 2 - Study Guide
Exam details - Date: 11.12.24 | Time: 3:30pm to 4:45pm | Location: IV Theater 1

There will be 35 multiple-questions on the midterm. No notes are allowed while taking the
exam. Approximately 1/3 of the material will be just from the book, the rest will be a
combination of the book and the lectures.

Chapters 4-7

Attention and Consciousness (Contd.)
Meta-awareness, mind wandering, and alcohol
○
Mindfulness and mind wandering
○
Model of meta-awareness and its relationship with consciousness
○ Components
○ Characteristics of meta-awareness
Big picture

Sensory and Working Memory
Defining and contrasting short-term and long-term memory
○ Short-term memory (STM):
Holds a small amount of recent information briefly.
Limited to about 7 "chunks" of information.
Easily forgotten if not processed further.
○ Long-term memory (LTM):
Stores vast amounts of information for a lifetime.
Retains experiences and knowledge indefinitely.
Limits of short-term memory
○ Brown/Peterson & Peterson technique
Participants memorize items and then perform a distracting task to prevent
rehearsal.
Findings:

Memory is fragile when stored for only a few seconds.
Interference from previous items reduces recall accuracy.
○ Serial position effect
Describes a U-shaped recall pattern in a list.
Recency Effect: Better recall for items at the end of a list (likely still in
STM).
Primacy Effect: Better recall for items at the beginning due to rehearsal.
Used to measure STM capacity (3-7 items).
 ○ Primacy and recency effects
Primacy Effect:
Early items in a list are remembered better.
Due to increased rehearsal and less competition from other items.
Recency Effect:
Items at the end of a list are also remembered well.
Likely still active in short-term memory at recall, making them
easier to retrieve.
○ Proactive interference
Definition: Occurs when earlier learning disrupts memory of new
information.
Example: Previously learned items interfere with recalling similar, newly
learned items.
Release from Proactive Interference: If new material differs in content or
category, PI is reduced. / Recall for the new category improves due to the
"release" effect.
Atkinson-Shiffrin model of information processing (definition of information processing)
○ Definition of Information Processing:
A model explaining how information flows through three main stages of
memory: sensory, short-term, and long-term.
Often compared to a computer, with data entering, being processed,
stored, and later retrieved.
○ Sensory memory
Function:
Acts as an initial stage that briefly holds sensory information from
the environment.
Duration is very short, typically lasting a fraction of a second.
Characteristics:
Allows only a brief retention of sensory information (visual,
auditory, etc.) before it fades.
Enables quick transfer to short-term memory if attention is given
to the information.
○ Their conceptualization of short-term memory
Function:
Temporarily holds information for immediate use or processing.
Often considered the "working" memory stage in this model.
Capacity:
Limited to about 7±2 items or chunks of information.
Duration:
Information typically lasts for 15-30 seconds without rehearsal.
Role in Model:
Information is either transferred to long-term memory through
rehearsal or is lost.
○ Long-term memory
 Function: Stores information over extended periods, potentially a lifetime.
Capacity: Believed to be unlimited.
Characteristics: Information in LTM is stored based on meaning and
organized for retrieval. / Items in LTM are relatively permanent, especially
if frequently retrieved or highly meaningful.
○ Control processes
Definition:
Techniques used to manage the flow of information between
memory stages.
Examples:
Rehearsal: Repeating information to keep it in short-term memory
longer or encode it into long-term memory.
Encoding: Converting information into a form that can be stored in
long-term memory.
Retrieval: Bringing information back from long-term memory to
short-term memory for use.
Attention: Focusing on sensory input to transfer information to
short-term memory.
○ Shortcomings/concerns about this model?
Oversimplification: The model is linear and doesn’t account for complex
interactions between memory stages.
Limited View of Short-Term Memory: Doesn’t fully encompass the "working
memory" concept, where manipulation and processing occur.
Lack of Detail on Long-Term Memory Types: The model does not
differentiate between various types of long-term memory (e.g.,
procedural, semantic, episodic).
Neglects Parallel Processing: Fails to account for the brain’s ability to process
multiple pieces of information simultaneously.
Control Processes Vary by Individual: Assumes control processes are the
same for everyone, without accounting for individual differences in
memory strategies.
The working-memory approach
○ Definition of working memory
Working memory refers to the cognitive system responsible for
temporarily holding and manipulating information needed for complex
tasks such as learning, reasoning, and comprehension.
It’s an active system that allows us to store, update, and work with
information over short periods of time.
Working memory is involved in tasks like problem-solving,
decision-making, and language comprehension.
○ Characteristics of the main components of the working memory approach
(phonological loop, visuospatial sketchpad, central executive and episodic buffer)
and research supporting each component
Don’t focus too much on the neuroscience of each component
 Also know the three important points related to limited working memory
capacity

Phonological Loop

Processes and stores verbal/auditory information.
Includes a phonological store (stores sounds briefly) and articulatory rehearsal system
(repeats information).
Research: Word length effect and phonological similarity effect show the loop's role in
verbal processing.

Visuospatial Sketchpad

Processes visual and spatial information (e.g., navigating space, visualizing objects).
Research: Dual-task studies support its independence from the phonological loop.

Central Executive

Controls attention, task switching, and integrates info from other components.
Research: Damage to the frontal lobes affects multitasking and cognitive flexibility.

Episodic Buffer

Integrates information from other components and long-term memory into coherent
episodes.
Helps form meaningful chunks of information.
○ Applications of working memory
Capacity Limitations: Holds a limited amount of info (7 ± 2 items).
Individual Differences: Some people have larger working memory
capacities, aiding in complex tasks.
Cognitive Load: High cognitive load can overwhelm working memory.
Academic performance
High working memory capacity correlates with better academic
performance, especially in reasoning, reading, and math.
In clinical populations
ADHD, dyslexia, brain injury: Working memory deficits are common
in these populations, affecting attention, reading, and daily tasks.
Cognitive training: Some interventions show success in improving
working memory in clinical settings.

Lecture Material:
Sensory memory definition according to the modal model
○ Sensory memory: large capacity, same modality as experience, very fast decay
What do the following methods tell us about sensory memory? How do they differ from
each other?
○ Span of apprehension
How much could a person see in a brief instant?
Whipple (1914)
○ Assessed memory for firefly flashed letter arrays
Perfect up to 4-5 letters
Persisted for some time
Could rarely report more than 4 letters
○ Sperling partial report paradigm
Briefly presented array
Brief delay
Report
Full report – recall all the items
Partial report – recall cued items
○ Auditory cued row
High-tone = recall top row
Medium tone = recall middle row
Low tone = recall bottom row
Advantage of partial report = provides test of knowledge of all of
the rows while only testing one row
Why? People don’t know which row they will be tested
Findings
Estimate of total recall performance
○ 4 letters using full report
○ 9 letters using partial report
How do you estimate total recall performance from partial
reports?
○ Proportion correct of partial report provides estimate of
total items remembered
Average 3 out of 4 on row = 75%
75% of 12 items provide an estimate of 9
Why was performance so much better with partial report?
○ With full report participants forgot the items before they
could report them all
Decay rate
○ Decayed from 9-4 letters in 1 second
○ Suggests brief detailed sensory memory
○ Dillolo missing dot technique
Purely perceptual (not verbally mediated)
 Present 24/25 dots
Three phases
○ First 12 dots
○ Pause
○ Second 12 dots
If sensory memory for first 12 dots lasts longer than the pause, then can
determine missing dot
How long can the pause last?
Approximately 100ms
Which produces longer sensory memory
First 12 dots for 10ms or 80ms?
Answer – shorter presentation = longer sensory memory
○ Sensory memory triggered by onset of stimulus
○ Sensory memory runs out of stimulus persists too long
Some concerns/challenges to sensory memory
○ Haber: limited functionality of sensory memory
Only occurs when followed by a dark blank screen
Otherwise new scene masks old one
Only clear application is reading in a lightning storm
○ Function of sensory memory
Allows for integration of briefly presented info
Provides a short-term buffer
Manifestation of processes that typically go on at the subliminal level
Short term memory and long term memory distinctions
○ Neurocognitive evidence
HM
(Milner) – not transfer to LTM
Clive Wearing
No transfer to LTM
JB
(Shallice and Warrington) – impaired STM – otherwise normal
○ Behavioral evidence
Brown/Peterson paradigm
Trigrams presented
○ SJW
Count backward by 3’s (5-30 seconds)
Attempt to recall trigram
Precipitous forgetting in 18 seconds
 Serial position curve
Recall advantage for first and last items of a word list
Dissociations
○ Logic – some manipulations influence one section of curve
but not the other
Suggests distinct system
○ Primary and asymptote
LTM
○ Recency
STM

Speed of presentation
Delay

○
Interference

○
 ○ Neuroimaging evidence relation to primacy and recency effects?
Retrieval from long-term memory specifically activates the hippocampus
Retrieval from working memory specifically activates the perirhinal cortex
Atkinson and Shiffrin’s explanation
○ Transfer to LTM due to time in the limited buffer
○ As new information enters the buffer, old items randomly eliminated
○ The longer in the buffer, the more likely to transfer to occur
○ Evidence - Rundus
Rehearsal technique
Presented list of words one at a time
Had people rehearse as many words as they could remember
between each word
Number of times each word was rehearsed predicted
○ Primacy and asymptote
Because time in buffer influences transfer to LTM
○ But not recency
Because recent terms still in buffer
○ Limitations
○ Know the main “problems” and research evidence that counters the modal
model
Impaired STM does not necessarily hurt learning
Possible to access LTM without going through STM
Subliminal perception of word meanings
Coding not always acoustic
Evidence for visual working memory
Rehearsal does not always lead to better memory
Craik and Watkins incidental learning task
○ Hear list of words and repeat words beginning with specific
letter
○ Number of repetitions did not alter memory
What is depth of processing and how does it relate to findings regarding maintenance
rehearsal?
○ Effects of rehearsal depend on the depth of processing
Shallow processing
Focus on appearance
Focus on sound
Poorly remembered
Deep processing
 Focus on the meaning
Better remembered
○ Shallow vs deep processing
Experimental evidence for benefits of deep processing on memory recall
Why does deep processing improve later memory recall?
○ Craik and Watkins lack of benefit of maintenance rehearsal
○ Craik and Tulving
Incidental learning – read words without knowing
they would be tested
Alternative tasks
Appearance
○ Upper or lower-case
Auditory (rhyming)
○ Does this word rhyme with ____
Semantic
○ Fits in the sentence
Surprise memory recall test
Semantic performance superior
What are problems with the depth of processing approach?
Transfer appropriate processing
○ Transfer appropriate processing
Quality of retrieval depends not on depth of
processing but match between encoding and
retrieval conditions
Morris, Bransford, and Franks 1978
Encoded words semantically or
phonologically
Tested words semantically or phonologically
○ Prediction depth of processing

○
○ Predictions transfer appropriate processing
 ○
○ Transfer appropriate processing results

○
Implies not depth of processing that is important so
much as match between encoding retrieval
conditions
Subsequent research suggests both depth of
encoding and match between encoding and
retrieval are important
Working memory approach
○ Model

○
○ Central executive
Provides the basic area in which calculations are made
Characteristics
Plans and coordinates, but does not store information
Executive supervisor
Decides which issues deserve attention
Selects a strategy
Decides how to tackle a problem
Limited ability to perform simultaneous tasks
 Evidence
Load (rehearsing digits)
○ Learning (primacy but not recency)
○ Recall
○ Sentence verification
○ Categorization
○ Reasoning
○ Everything but recognition
Damage to frontal cortex leads to
○ Difficulty planning
○ Difficulty reasoning
○
Evidence for the central executive: effects of cognitive load
○ Task: hold “X” digits in mind while generating random
number sequences
○ Randomness of digit generation (greater redundancy) as
function of concurrent digit memory load
○ Phonological store
Slave system for audition (auditory)
Phonological similarity effects
“pgtvcd” harder to remember than “rhxkwy”
Why?
Letters sound similar so more easily considered in phonological
store
Unattended speech effects
Hear nine digits accompanied with:
○ Silence
○ Spoken words
○ Nonsense words
Recall impaired by sounds regardless of meaning
Why?
○ Phonological store holds sounds regardless of meaning
Word length effects
Long words are less remembered
Welsh speaking children have shorter digit spans than English
speaking
Why?
○ Phonological store holds limited number of syllables
 Articulatory suppression
Repeating syllables (ie “tah-tah-tah”) while completing a verbal
span test reduces WM capacity
Eliminates “sound-alike” errors (ie misremembering “F” as “S”)
○ Visual-spatial sketch pad
Slave system for vision
Brooks
Visualized block F and tried to decide which corners were pointing
outward
Two ways to respond
○ Spatial
Point to a yes or a no
○ Verbal
Speak yes or no
Result
Verbal response more efficient than spatial response
Implications
Visual imagery draws on visual-spatial sketch pad
Pointing but not speaking also draws on visual-spatial sketch pad
More difficult when task and response both draw on the same
system
○ Analogy of circuit breakers (more likely to short if multiple
heavy appliances are on the same circuit)
○ Episodic buffer
Integrates information from different modalities
Episodic buffer
Temporary storehouse that can hold and combine information
from the phonological loop, the visuospatial sketchpad, and
long-term memory
Integrates information from different modalities
Evidence
People remember words in a sentence better than words
presented out of the context of a sentence
○ Suggests words are stored in a meaningful representation
in working memory
Cannot be accommodated by other systems
○ Central executive –
No storage capacities
 ○ Phonological store
No capacity for meaningful analysis
○ Visual spatial sketch pad
Sentence advantage works with auditory
information
○ Big picture conclusions
What we remember quickly whittles down
Most info in sensory memory does not make it into STM
Most info in STM does not make it into LTM
Working memory is like
RAM on a computer
A desktop where all the work gets done
Both sensory and working memory involve multiple types that are
distinguished by sensory modality
Sensory memory
○ Visual sensory memory
○ Echoci sensory memory
Working memory
○ Visual-spatial sketch pad
○ Phonological store

Long Term Memory
Definition of long-term memory
○ Definition: Long-term memory (LTM) refers to the storage of information over
extended periods of time, from hours to a lifetime.
Episodic memory, Semantic memory and Procedural memory (definition and examples)
○ Similarities and differences between these types of long-term memory
Episodic Memory: Memory of personal experiences (e.g., your first day of school).
Semantic Memory: General knowledge and facts (e.g., the capital of France).
Procedural Memory: Memory for skills and tasks (e.g., riding a bike).
Similarities: All are types of declarative memory (episodic and semantic) or
non-declarative memory (procedural).
Differences: Episodic is event-based, semantic is fact-based, and procedural is
skill-based.
Definition of encoding
○ Levels/depth of processing
Why does deeper processing during encoding lead to better recall?
Definition: Encoding is the process of converting sensory input
into a form that can be stored in long-term memory.
 Levels/Depth of Processing: Refers to the depth at which
information is processed; shallow processing involves simple
repetition, while deep processing involves meaning and
connections.
Why Deeper Processing Leads to Better Recall: Deeper processing
(e.g., making connections to prior knowledge) creates more
elaborate and distinct memory traces, making recall easier.
Elaboration and Distinctiveness
○ Elaboration: Adding meaning or connections to new
information.
○ Distinctiveness: Making the memory unique or different
from other experiences to enhance recall.
Self-reference effect
○ The phenomenon where people tend to remember
information better if it is related to themselves.
○ Encoding specificity principle
Research supporting the principle
Definition: Memory is more likely to be recalled if the context
during encoding matches the context during retrieval.
Research Supporting the Principle: Studies like Godden &
Baddeley (1975) show that recall is better when environmental
conditions during learning and retrieval are similar (e.g., learning
underwater vs. on land).
Recall and recognition tasks – how do they differ?
○ Recall: Retrieving information without cues (e.g., essay
exam).
○ Recognition: Identifying previously learned information
from a set of options (e.g., multiple-choice exam).
Emotion and memory – what does the research say?
○ Research: Emotional events are remembered better than neutral events due to
the involvement of the amygdala in processing emotional information, which
strengthens memory encoding.
○ Pollyanna principle
Tendency to remember positive events more easily than negative ones.
Positivity effect
People tend to recall positive information more than negative,
especially in older adults, due to a preference for positive
experiences.
Definition of retrieval
○ Examples of explicit and implicit memory tasks
Definition: The process of accessing stored information from long-term
memory.
Explicit Memory Tasks: Involve conscious recall (e.g., naming all U.S.
presidents).
 Implicit Memory Tasks: Involve unconscious retrieval (e.g., word
completion tasks, like filling in "co_ _" as "coffee").
How are explicit and implicit memory related to anxiety disorders?
Explicit: May be negatively impacted by anxiety disorders, as they
can interfere with conscious retrieval of information.
Implicit: Anxiety can influence automatic, unconscious memory
processes, such as biases toward fearful stimuli.
Amnesia – what is it and what type of memory is impacted?
○ Retrograde amnesia
○ Anterograde amnesia
Definition: A condition characterized by memory loss, often due to brain
injury or trauma.
Retrograde Amnesia: Inability to recall past memories before the onset of
amnesia.
Anterograde Amnesia: Inability to form new memories after the onset of
amnesia.
How do novices and experts differ?
Differences: Experts have more organized, efficient, and detailed knowledge
structures, allowing them to process information more quickly and accurately
than novices.
Autobiographical memory
○ Memory of life events, including both episodic and semantic information about
oneself
Source monitoring vs reality monitoring
○ Source Monitoring: The process of determining the source of a memory (e.g.,
whether it was seen on TV or experienced personally).
○ Reality Monitoring: Differentiating between memories of real events and
imagined events.
Definition, example and research studies related to flashbulb memory and eyewitness
testimony
○ Flashbulb Memory: A highly detailed, vivid memory of an emotionally significant
event (e.g., 9/11).
○ Eyewitness Testimony: Memory recall of an event by a person who witnessed it.
Often influenced by factors like stress, misinformation, and feedback.
○ Research: Flashbulb memories are often distorted despite high confidence in
their accuracy (e.g., Talarico & Rubin, 2003).
○ What factors influence eyewitness testimony accuracy
Stress, Delay, Plausibility of Misinformation, Social Pressure, and
Positive Feedback: All increase the likelihood of errors in eyewitness
testimony (Kovera & Borgida, 2010; Wells et al., 2000).
Post-misinformation effect and its relation to errors in eyewitness testimony
○ The tendency for people to incorporate misleading information into their
memory after an event, which can lead to errors in eyewitness testimony (Loftus,
1978).
 ○ Constructivist approach
Memory is viewed as an active process where past experiences and
external information shape the way memories are constructed.
Recovered memory/false memory controversy (see lecture notes too)
○ Recovered Memory: Suggests that some people can forget traumatic
experiences (e.g., sexual abuse) and later "recover" these memories (Freyd,
2005).
○ False Memory: Suggests that many recovered memories may be inaccurate,
possibly influenced by suggestion or external cues (Bernstein & Loftus, 2009).
Understand the debate regarding recovered memories of abuse as it
relates to memory
Some researchers argue that repressed memories of abuse can be
recovered, while others believe that most "recovered" memories
are false and are the result of suggestive therapy or external
influences.
How are case analyses used?
○ Usage: Case analyses involve examining individual cases of
memory to understand the mechanisms of memory
formation, retrieval, and distortion, especially in cases of
recovered or false memories. They help researchers
explore the complex nature of autobiographical memory
and its susceptibility to external influences.

Lecture material:
Three aspects of long-term memory (provide definition of each)
○ Encoding (provide examples and research findings related to the following)
Encoding: Processes that enable information to be transferred from STM
to LTM
Self-reference effect
Encode words with respect to:
○ Structure (upper or lower case)
○ Sound (rhymed with another word)
○ Semantics (was synonym with another word)
○ Relation to self (was this true of the self?)
Reason for advantage: the self is highly meaningful (maximum
depth of processing)
Generation effect
Encode items in two ways
○ Read: hot-cold
○ Generate: hot-c_ _ _
Free recall
 Result: generate leads to better recall than reading
Reason for advantage: generated items are more self-relevant and
meaningful, and they’re more deeply processed
Schemas
Memory tends to be schematic
Schema: general knowledge or expectations based on past
experiences (essentially a pattern of thought that organizes
categories of info)
○ Schemas influence what we encode
Relationship between expertise, schemas and encoding
Bransford and Johnson
○ Expertise can markedly enhance encoding of information
relevant to one’s domain of expertise
○ Effects on encoding: experts can transfer more
expertise-relevant info to LTM
○ Memory for random numbers
Undergrad learned to remember 50 numbers after
hearing them just once by relating to them to
known track times (ie schematic information)
○ Expertise: memory for chess configurations
○ Results:
Chess experts remember board configurations
better
But only for playable configurations
○ Expertise: memory for food orders
Results:
Waiters are much better at remembering
orders
Limited to domain of expertise
Non-schematic information
Although encoding is often schematic, it is not always so
○ Sometimes people maintain non-schematic information
Ex
○ Remembering the location of text on a page
Dual code theory
Theory: two codes for concentrate things (verbal and picture)
○ Ex: the word “dog” and a picture of a dog
Two retrieval codes for the information
○ Retention interval (how do each of the following impact people’s memory for
experiences after they have been encoded?)
Retention interval: Processes that occur after encoding that may
influence whether the material is later available
Retention interval: the period of time AFTER a memory has been
encoded, but BEFORE it has been retrieved
Various factors influence people’s memory for experiences after
they have already been encoded
Spacing effect
Better memory for information studied a few times over a long
period of time vs. studied repeatedly in a single interval
Suggests cramming is bad
○ Although effects are more pronounced with delay
Why is spacing helpful?
○ It increases the number of separate traces
What is I MUST cram?
○ Study in different locations
Passage of time
Ebbinghaus forgetting over time
○ Initially dramatic forgetting, then plateau
Sleep
Sleep enables memory consolidation
Enhances memory (especially for emotional material)
Post-event information
Loftus misinformation study
○ Saw a video of a car at a stop sign
○ Later, some participants heard questions referring to a
yield sign
○ Tested on stop sign vs. yield sign
○ Result
Participants who heard mention of yield sign were
more likely to falsely recognize it
Suggested autobiographical memories
○ Memory of our personal experiences
Misinformation can produce false memories of
entire events
Relevant to court cases involving reports of child
abuse
 Loftus (and others) suggests some cases could be
the result of planted memories
Initial speculation was based off research we just
saw (yield sign)
Question: Can you plant memories of entire
personal experiences?
○ Misinformation can produce false memories of entire
events
○ Creating memories with pictures
○ Retrieval (how do the following factors maximize memory retrieval?)
Retrieval: Processes that influence the ability to recall or recognize the
previously encoded information
Performance is maximized when encoding factors resemble
retrieval conditions (transfer-appropriate processing; TAP)
TAP has been studied in numerous fun contexts
State dependent memory
Definition: if you study in one state, your memory will be better if
you’re also tested in that state
Mood dependent memory
Generate autobiographical memories in one mood or another
(Eich)
Recall previously generated events in the same, different, or
neutral mood
○ Same mood → best recall
○ Different mood → worse recall
Context dependent memory
Participants studied either on land or under water
○ Tested on land or under water
○ Recognition and recall tests
○ State dependent effect for recall
○ General advantage for on land for recognition
How can we use context dependent memory in a real-world
setting? (Guiselman study)
○ Guiselman
Participants witnessed crime with car having a
visible license plate
Gave participants either free recall or license plates
with blanks to fill in
 Results: fill-in-the-blank approach increases
performance by 1.5x
Impact of schemas on long-term memory retrieval?
Deese Roediger Mcdermott paradigm
○ Study word list of related items
Jenkins Demo
○ People falsely remember seeing sentences corresponding
to the gist of the sentences they studied
○ Conclusion: people retrieve the gist of what they studied
Big picture conclusions
○ Memory involves three key strategies
Encoding
Retention interval
Retrieval
○ All three stages influenced by 2 key factors
Memory tends to be schematic
We remember the gist of experiences rather than the entire
experience
Memory is maximized when retrieval conditions correspond to encoding
condition
○ Relevant to real-world topics
Context reinstatement enhances memory for license plates
Memory suggestions can potentially cause false memories of abuse

Mental Imagery and Cognitive Maps
Definition of mental imagery
○ Definition of mental imagery: The ability to create and manipulate images in the
mind without direct sensory input.
○ What are some examples of what we use mental imagery for?
Examples of mental imagery use: Visualizing a map to navigate,
imagining a scene, recalling memories of a place.
○ How does mental imagery differ from perception?
Difference from perception: Perception is direct sensory input, while
mental imagery is internally generated and can be manipulated.
Use of mental rotation tasks in measuring mental imagery
○ Use of mental rotation tasks: Tasks where participants mentally rotate objects to
compare them to other objects to measure mental imagery ability.
○ Research findings related to mental rotation
 People perform better with simple shapes; rotation time increases with
greater angles.
○ Cognitive neuroscience and mental rotation
Activation in brain regions like the parietal cortex during mental rotation
tasks.
What is the “imagery debate”?
○ Discussion on whether mental imagery is based on analog codes (visual) or
propositional codes (abstract).
○ Analog code vs propositional code
Analog code: Imagery is like a mental picture (visual).
Propositional code: Imagery is symbolic and abstract.
Research supporting each side of the debate
Analog: People respond similarly to real images and mental
images.
Propositional: Imagery is influenced by language and abstract
representations.
○ What do people with prosopagnosia tell us about the debate?
People with prosopagnosia (difficulty recognizing faces) still have vivid
imagery, suggesting a separate system for visual imagery
○ Ambiguous stimuli
Images or objects that can be interpreted in multiple ways; used to study
imagery and perception.
○ Visualizers vs verbalizers
Factors that influence visual imagery
○ Visualizers: People who think in images.
○ Verbalizers: People who think in words.
○ Distance and shape effects
Distance effects (mental images appear larger the closer they are).
Shape effects (more complex shapes take longer to rotate).
Research on how imagery interferes with physical stimuli
○ Imagery can distract from processing actual sensory input (e.g., visual imagery
affects visual perception).
Gender differences in spatial ability
○ How do they compare to gender comparisons of other cognitive abilities?
Gender similarities
○ Are gender differences in spatial ability large?
Men typically perform better on spatial tasks.
Gender differences are small, especially in non-spatial cognitive abilities.

Gender similarities: More similarities than differences across most cognitive
abilities.
Are gender differences in spatial ability large?: No, they are relatively small.
Definition and examples of auditory imagery
○ Mental representation of sounds (e.g., imagining a song).
 ○ Is auditory imagery as vivid as visual imagery?
Generally less vivid, but can be strong in some individuals.
○ Auditory imagery and pitch
Ability to imagine variations in sound frequency (high/low tones).
○ Auditory imagery and timbre
Ability to imagine the quality of sounds (e.g., the difference between
instruments).
Definition of cognitive maps
○ Mental representations of spatial layouts (e.g., maps, directions).
○ How are cognitive maps related to spatial cognition? What is spatial cognition?
Relation to spatial cognition: Cognitive maps are part of spatial cognition,
which is how we process and represent spatial information.
○ Distance and shape effects on cognitive maps
Distances between landmarks are often estimated as shorter or longer
than they are.
Shapes can be distorted in mental maps (e.g., straight roads appear
curvier).
Border bias
Tendency to estimate distances as greater when crossing a border
or boundary.
Landmark effect
Landmarks make it easier to remember locations and navigate
90-degree-angle-heuristic
Tendency to assume streets and intersections are at right angles.
○ Position effects on cognitive maps (see examples from lecture)
Perceptions are influenced by the relative positions of landmarks (e.g.,
objects in the center are easier to remember).
Rotation heuristic
Tendency to mentally rotate maps or scenes into a more familiar
orientation (e.g., turning a map upright).
Alignment heuristic
Tendency to align objects or landmarks in a more organized
pattern (e.g., assuming cities are aligned on a north-south axis).
How are cognitive maps formed?
○ We integrate information from different sources and actively construct mental
representations.
○ What does the spatial framework model suggest?
Above-below dimension: Most prominent due to gravity and body
orientation.
Front-back dimension: Next most important due to body asymmetry.
Right-left dimension: Least important, as the body is symmetrical.
○ What does the situated cognition approach suggest?
Our cognitive abilities, including spatial thinking, are influenced by the
physical environment and the situation we're in (context-dependent).
Lecture material:
Imagery demos
o How many windows are there in the home where you grew up?
o Which is darker, the green of pine trees or the green of grass?
o Is the 3rd note of “three blind mice” higher or lower than the 1st note?
o Imagine a capital letter B
▪ Rotate it 90 degrees counterclockwise
▪ Put a triangle below it having the same width and pointing down
▪ What do you see?
What is mental imagery?
o Experience of seeing, hearing, and touching without the presence of an external
perceptual source
o Seeing in the “mind’s eye”
Controversy: What is imagery based on?
o Propositions (Descriptions) vs Depictions
▪ Propositions (descriptions)
Essential meaning
Do not resemble what they stand for
Abstract code
A canary is a bird
A canary has wings
A canary can sing
▪ Depictions
Resemble what they stand for (analog code)
▪ Example
Descriptive (propositional)
o F is above E
o D is to the left of E
o E is above B
o D is above A
Depictive
 o
o Dual Code Theory (Paivio)
▪ Theory: two codes for concentrate things (verbal and picture)
Ex: the word “dog” and a picture of a dog
o Analog view (Kosslyn)
▪ Store some information as images
▪ Images are functional in thinking
o Propositional view (Pylyshyn)
▪ All information stored as propositions
▪ Images are “epiphenomenal”
Early studies of imagery
o Early studies (Galton)
▪ Imagine and describe your breakfast table
▪ People reported more and less vivid images
o But based on introspection – no way of verifying what they actually imagined!
o Need more objective method of studying!
Evidence for imagery
o Time to answer
▪ “Imagine a cat” vs. “think about a cat”
▪ Does a cat have a head?
▪ Does a cat have paws?
▪ Imagined cat: faster to confirm that cats have heads and than they have
paws
▪ Think about a cat: the reverse was true!
o Time to zoom
▪ Imagine a rabbit next to an elephant/fly
▪ Does the rabbit have eyelashes?
▪ Reaction time longer if rabbit was next to an elephant
o Image scanning
▪ It takes longer to scan between objects that are further apart
▪ Same for mental images?
 ▪ Kosslyn (1978)
Subjects form accurate mental image of an island
Task: answer questions by scanning between different landmarks
on the map image
▪ Criticisms
Were told to scan!
“Demand” character: subjects act like they think you want them
to act
Experimenter expectancy: subtle cues from the experimenter
Experimenters were told a false theory about scanning
Got the same results
o Time to rotate
▪ When an object moves or rates in space, it takes more time, te greater
the displacement or rotation
▪ It also goes through all intermediate positions
▪ Do images behave similarly?
▪ Time to say whether two objects have same shape increases with theri
angular disparity
▪ True for rotations in the picture plane and in depth
▪ Later experiments:
Estimated people’s speed of rotation
Indicated that their rotation went through all intermediate
positions
▪ This is called an analog transformation
Evidence against imagery
o Limited detail
▪ Not completely picture-like
o Reinterpretation of images
▪ Images cannot always be reinterpreted
Chambers and Riesberg (1985)
Task: create mental imge of this rabbit
o Can you see anything else in your image?
 o
0/15 could interpret the image as a duck
15/15 could interpret the figure after they drew it from memory
Suggests that proposition (meaning) can dominate over analog
code
Best to think of propositions as complementary modes of
representation
Imagery and the brain
o Same area (occipital lobe) active when viewing and imagining letters
▪ Earlier visual areas (V1,V2 active when maintaining highly detailed
images)
o Visual areas of brain also active during:
▪ Imagined walk
▪ Questions that require imagery
o Motor cortex active during mental rotation of hands
o Neural evidence
▪ Mental rotation: more brain activation for larger angles (Carpenter, Just
and Keller)

▪
o Bissiach and Luzzati study
▪ Brain damage that affects vision also affects imagery
 Neglect patient (Milan) imagined the view of the Piazza del
Duomo from different perspectives
Ignored landmarks on imagined left side of space from each
perspective
Individual differences in imagery
o Different dimensions
▪ Vividness vs accuracy
Vividness (visual imagery)
o Galton’s classic studies
o Vividness of visual imagery questionnaire
Accuracy of image population manipulation (spatial
transformations)
o Measures of spatial visualization ability
Spatial Cognition
o Cognitive maps
▪ Cognitive maps as internal representations of enviroments
▪ Learned from
Durect experience in environment
Maps
▪ Uses in
Navigation, wayfinding, staying oriented
▪ How accurate are our cognitive maps (demos)?
Which is further west: Reno, NV or San Diego, CA
Which is further south: Philadelphia, PN or Rome, Italy
Individual differences in navigation ability
o Abilities vs. strategies
▪ Abilities
Individual differences are large
Self reports of “sense of direction” are pretty predictive of these
individual differences
Not the same as individual differences in small-scale spatial
abilities
Individual differences include strategy differences
▪ Strategies
Orientation strategy
o I kept track of the direction (north, south, east, west) in
which I was going
 o I kept track of where I was in relation to the sun or moon)
in the sky as I went
o I kept track of the relationship between where I was and
the center of town
Route strategy
o Before starting, I asked for directions telling me whether to
turn left or right at a particular street or landmark
o As I drove, I made a mental note of the number of streets I
passed before making each turn
o I made a mental note of landmarks, such as buldings or
natural features, that I passed along the way
Summary
o Imagery is a special of mental representation:
▪ Images are not completely picture-like
Cannot always be reinterpreted
▪ Imagery shares brain regions with perception
▪ Vivdness and accuracy are separate aspects of individual differences in
imagery
▪ Cognitive maps are internal representations of environments that help us
find our way and stay oriented

Metacognition and Memory Strategies
What are memory strategies?
○ Techniques to improve encoding, storage, and retrieval of information.
Memory strategies related to practice
○ Total-time hypothesis
More time spent learning leads to better memory retention.
Distributed-practice effect
Spacing study sessions improves retention over massed
(crammed) learning.
Spaced learning
Intervals between study sessions enhance learning.
Massed learning
Cramming leads to less effective long-term retention.
Desirable difficulties
Introducing challenges in learning (e.g., spaced practice) can
improve long-term memory.
○ Testing effect
Testing yourself on material enhances memory more than repeated study.
Mnemonics – what are they?
 ○ Memory aids that help in encoding and recalling information.
○ Two types of mnemonics
Mnemonics using mental imagery
Keyword Method
○ Mnemonics using mental imagery: Creating vivid images
to associate with the material (e.g., Keyword Method).
○ Mnemonics using organization: Organizing information
into chunks or structures.
Mnemonics using organization
Chunking
○ Grouping information into manageable units.
Hierarchy
○ Organizing information from general to specific.
First-letter technique
○ Using the first letter of each word to form a memorable
phrase.
Narrative technique
○ Creating a story that links pieces of information together.
Retrospective vs prospective memory – examples and definitions
○ How do they differ? What are some similarities?
Retrospective memory: Remembering past events (e.g., recalling what
you did last week).
Prospective memory: Remembering to perform future actions (e.g.,
remembering to attend a meeting).
Differences: Retrospective memory is about the past, while prospective
memory concerns the future.
Similarities: Both involve the retrieval of information from memory at the
appropriate time.
Memory aides and prospective memory
○ Memory aids (e.g., reminders, alarms) can improve prospective memory, helping
to remember future tasks.
Definition of metacognition
○ Awareness and regulation of one’s own cognitive processes, such as memory and
learning.
○ What is metamemory?
Foresight bias
Immediate metamemory compared to metamemory after a delay?
Research on metamemory (in relation to factors that influence
metamemory, and regulation of study strategies)
Metamemory: Awareness of one’s own memory abilities and
strategies.

Foresight bias: Overestimating one's ability to recall information
in the future.
 Immediate metamemory: Self-assessment of memory during or
shortly after learning.
Metamemory after a delay: Self-assessment of memory after a
period of time has passed.
Factors influencing metamemory: Experience, confidence, and
type of material affect how well individuals judge their memory.
Tip-of-the-tongue effect
○ The feeling that you know something but cannot retrieve it at the moment.
Feeling-of-knowing effect
○ The sense that you could recognize the correct answer if you were given options.
Metacomprehension
○ Definition
○ How accurate is it?
○ How can we improve it?
Metacomprehension: Awareness of how well you understand
information.
Accuracy: College students often overestimate their
comprehension abilities.
Improvement: To improve metacomprehension, strategies like
summarizing material or explaining it in your own words can be
helpful.

Lecture material:
What is meta-cognition?
○ One’s knowledge about what he or she knows
○ Meta-cognitive knowledge
General knowledge about what one knows
○ Meta-cognitive experience
Conscious cognitive or affective experiences that accompany and pertain
to any intellectual enterprise
What is meta-memory?
○ One’s knowledge about their own memory
○ Types of metamemory judgments
Predicting future memory performance
At encoding (judgments of learning)
○ Judgments of learning (JOL): predictions of how well one
will remember something
○ Ease of learning
How much study will be required to learn
something?
Predict learning rates fairly well
 ○ Paired associative judgements
Predict subsequent performance on
paired-associate test
Introducing brief delay between cue and associate
enhances prediction
People are abe to use initial retrieval to gauge
subsequent ability
At retrieval (tip of the tongue)
○ Tip of the tongue: inability to recall something combined
with subjective feeling that recall is imminent
○ Brown and McNeil studies
Gave participants definitions and asked
them to recall the word
Compared performance for those reporting
TOT and those not reporting it
Results
Those experiencing TOT
○ More accurate with first letter
○ More accurate with number of
syllables
○ More likely to eventually recall full
word
Assessing the source of one’s memory
Source monitoring judgments
○ Reality monitoring
Challenge: determine whether memory is internally
or externally generated
Failures occur with memories with overlapping
attributes
External vs internal memories
External
○ Characterized by sensory details
Internal
○ Characterized by cognitive
operations
Roommate study
Keep track of and share dreams for a month
 At the end of the month, indicate which
dreams were yours and which were theirs
Results: people confuse their own dreams
with that of theri roommates
Schooler stop/yield sign study
½ participants have false memory planted
of yield sign
½ participants actually see a yield sign
Compare the memories across these two
groups
Results: internal and external memories
differ in properties
Real memories have more sensory details
False memories have more cognitive
operations
False memories described with more words
Fruit study
Greater confusion when properties overlap

Mnemonics
○ Applying specific techniques for memory improvement (be able to define,
understand the basic principle/goal and provide an example of each)
Keyword method
Basic principle: give meaning to meaningless information (youtube
link in slides)
Link/story method
Basic goal: associate items in a manner that preserves order
Basic principle: establish a chain of associations, with each item
associated with the next (youtube link in slides)
Method of Loci
 Basic goal: memorize material (often a speech) by mentally
placing items around a familiar location
Basic principle: familiar location provides pre-established memory
cues to associate information (youtube link on slides)
Rhymes
Basic goal: use rhyming phrase to stand for items you need to
remember
Examples
○ I before E except after C or when sounded “A” as in
neighbor or weigh
○ 30 days have September, April, June, and November (all
the rest have 31 except feb)
Catch phrases
Basic goal: clever expressions to remember associations
Example
○ Spring forward, fall back
Acronym
Basic principle: abbreviating the first letter of to-be-remembered
words
Order in the rainbow, or visual spectrum
○ Red, orange, yellow, green, blue, indigo, violet
ROY G BIV
○ Prospective memory
Prospective memory: our ability to make plans, to retain and recollect
them, and to carry out at the appropriate time or in the appropriate
context
Everyday examples
Remembering to attend a 2pm meeting
Remembering to take a medication
Remembering to buy eggs after work
How can we improve prospective memory?
Implementation intentions
○ Implementation intentions: specific about where and
when you will do something
○ Experimental study
Participants were asked to write a report on how
they spent Xmas eve, no more than 48 hours after
Half requested to form implementation intentions
 When and where they would complete the
report
Results
¾ completed with intentions
⅓ without
Big picture conclusions
○ Meta-cognition
There is an important difference between memory ability and what we
know about our memory ability
○ Memory improvement
Basic knowledge of encoding, retention interval, and retrieval very useful
for enhancing memory
Memory improvement strategies can be useful but demanding and have
to remember to use them
Best memory strategy is understanding
○ Prospective memory
Best strategy for remembering to carry out future acts is to be very
specific about where and when the action will be carried out