Long-Term Memory PDF

Summary

This document provides a detailed overview of long-term memory, including its structure, types, and processes, and how different types of memory interact. It also discusses various related phenomena like encoding, retrieval, and priming.

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LONG-TERM MEMORY STRUCTURE
All information encoded in LTM is semantic in nature
Semantic codes combine to form proposition
Long capacity in terms of space and duration of memory representations
Well organized

Korsakoff’s syndrome: condition causing the destruction of areas in the frontal
and temporal lobes, which causes severe and permanent impairments in memory
caused by a prolonged deficiency of vitamin B1, from chronic alcoholism

Amnesia: loss of memory and/or ability to learn
Retrograde: loss of memory of more recent memory before trauma but able to
remember memories more distant and form new memories
Anterograde: inability to form new memories

Distinguishing Between Long-Term Memory and Short-Term Memory
Long-term memory (LTM) is the system that is responsible for storing
information for long periods of time
Archive of information about past events

SERIAL POSITION CURVE
Primacy effect: superior memory for stimuli presented at the beginning of a
sequence
memory is better for words at the beginning and at the end of the list than for
words in the middle
because participants have more time to rehearse earlier words

Recency effect: superior memory for stimuli presented at the end of a sequence
most recently presented words are still in STM

CODING IN LONG-TERM MEMORY
Although all three types of coding (visual, auditory, semantic) can occur in LTM,
semantic coding is the predominant type of coding in LTM
illustrated by the kinds of errors that people make in tasks that involve LTM
misremembering the word tree as bush would indicate that the meaning of
the word tree (rather than its visual appearance or the sound of saying “tree”)
is what was registered in LTM

Recognition Memory
Recognition memory: the identification of a stimulus that was encountered earlier
Pre-training: present a stimulus
Test: present the same stimulus plus others that were not presented

LOCATING SHORT- AND LONG-TERM MEMORY IN THE BRAIN
STM and LTM are separated in the brain, but there is some evidence for overlap
Neuropsychological Studies
Single dissociation: when a lesion to brain area X impairs the ability of a patient
to do task A but not task B
brain area X and task A are associated
brain area X and task B are dissociated

Double dissociation: when damage to area X impairs the ability to do task A but
not task B, and damage to area Y impairs the ability to do task B but not task A
2 areas have complementary processing
some patients with functioning STM can’t form new LTMs (H.M.)
Some patients who have poor STM but functioning LTM (K.F.)
Very low digit span & reduced recency effect

Brain Imaging
activation of different areas for STM and LTM

TYPES OF LONG-TERM MEMORY

TYPES OF LTM:
Explicit memory: declarative memory (conscious)
Episodic memories: for personal experiences
Semantic memories: for knowledge or facts

Implicit memories: non-declarative (unconscious)
Procedural memory: how to do things
Priming: a change in response to a stimulus caused by the previous
presentation of the same or a similar stimulus
Classical conditioning: stimulus-response associations

Episodic and Semantic Memory (Explicit)
DISTINGUISHING BETWEEN EPISODIC AND SEMANTIC MEMORY

Episodic memory:
involves mental time travel: the experience of traveling back in time to
reconnect with events that happened in the past
Involves what/when/where

Semantic memory:
involves accessing knowledge about the world without remembering a personal
experience

THE SEPARATION OF EPISODIC AND SEMANTIC MEMORIES

Neuropsychological Evidence
K.C.: suffered severe damage to his hippocampus and surrounding structures
lost his episodic memory
 semantic memory is largely intact
Italian woman: damage caused by encephalitis
Loss of semantic memory
Intact episodic memory

Brain Imaging Evidence
while there is overlap between activation caused by episodic and semantic
memories, there are major differences

CONNECTIONS BETWEEN EPISODIC AND SEMANTIC MEMORIES
when we are learning facts (potential semantic memories), we are usually
simultaneously having a personal experience (episodic memory)

EPISODIC MEMORIES CAN BE LOST, LEAVING ONLY SEMANTIC
MEMORIES
When memory is recent, both episodic and semantic memory are present
When memory is far, episodic memory fades, leaving only semantic memories to
be remembered

SEMANTIC MEMORY CAN BE ENHANCED IF ASSOCIATED WITH
EPISODIC MEMORY
semantic memories that have personal significance are easier to remember

SEMANTIC MEMORY CAN INFLUENCE OUR EXPERIENCE BY
INFLUENCING ATTENTION
Chess Experiment
semantic memory can influence how people allocate their attention

Priming, Procedural Memory, and Conditioning (Implicit)
PRIMING

Priming: when the presentation of one stimulus (the priming stimulus) changes
the response to a subsequent test stimulus (the test stimulus)
Negative priming: causes a decrease in the speed or accuracy of response to
the test stimulus)
Positive priming: which causes an increase in speed or accuracy of the
response to the test stimulus
Repetition priming: when the test stimulus is the same as or resembles the
priming stimulus
Conceptual priming: when the enhancement caused by the priming stimulus
is based on the meaning of the stimulus

Graff’s Implicit memory experiment
Compared: Amnesic patients, Korsakoff patients, and control
Results:
 Recall experiment: amnesia patients had poor recall compared to the two
control groups (confirms the poor explicit memory)
Implicit memory test: the amnesia patient performed just as well as the
controls

Warrington & Weiskrantz’s experiment
Tested Korsakoff patients
Results:
improvement of performance represents an effect of implicit memory because
the patients learned from experience even though they couldn’t remember
having had the experience

Propaganda effect: participants are more likely to rate statements they have read
or heard before as being true, simply because they have been exposed to them
before

PROCEDURAL MEMORY

Procedural memory (skill memory): memory for doing things that usually require
action
We do not remember where or when we learned many of our basic skills
No consciousness of how we do them

H.M. Mirror drawing experiment
Gradual improvement of a practiced skill without remembering any of the
practice that led to this mastery

LTM: ENCODING & RETRIEVAL
Encoding: the process of acquiring information and transferring it into LTM
Ex.: a word can be encoded by repeating it over and over, by thinking of other
words that rhyme with it, or by using it in a sentence

Retrieval: process of transferring information from LTM to working memory

Shereshevsky’s “perfect” memory
could encode long lists of words, addresses, digits events in a short period of
time and recite them perfectly forward and backward
Technique: “see” everything told to him or everything he read as a sequence of
images
Relied on synaesthesia

Propositions
Propositions: semantic content of a statement/idea/event
any piece of such statement to which you can assign a “truth” value (T or F)
Mary is Canadian (T/F) = proposition
 Banff is not in Alberta (T/F) = proposition
Caroline kicked (no T/F) = not a proposition
Used as ways of encoding knowledge in logic and artificial intelligence

SPATIAL RELATIONS
Any given scene can be described in a myriad of ways
Chances are, we encode some, but not all these possible ways

Propositional representation in LTM: The Galileo Story
Subjects heard/read a long paragraph
Results:
Semantic violation was correctly detected: no significant difference between
sentences that preserve meaning
The gist is what is being encoded

Kintsch’s study on memory for propositions
Sentences varying in:
number of propositions
number of content words
Results:
Harder to fully recall sentences with more propositions (more complex)
twice as much partial recall for multi-propositional sentences
We retain propositions from sentences

Constructive Memory: Turtle Study
All experimental sentences had similar structures with different prepositions/verb
particles and final pronouns
Results:
Encoding the relational position of things

Mental models
Relation between proposition and images
It includes a “reference” to the discourse/context
It includes inferences drawn by the hearer/reader
a logical/semantic description of the sentence does not always suffice to
represent/encode real world events

Mental Images
Mental images can be anything (imagination, not viewing)

AS PERCEPTION:
relies on different properties of images
Allocentric: viewer-entered
“3D”: what is activated cannot be what is imagined
AS EXPLANATIONS
fundamental difference between empirical phenomena that reveal properties of
mind and ones that reveal what a subject knows or remembers

AS REPRESENTATIONS

Encoding: Getting Information Into Long-Term Memory
Rehearsal: process of repeating information over and over
can be used to keep information in STM/working memory
doesn’t guarantee that information will be transferred into LTM

MAINTENANCE REHEARSAL AND ELABORATIVE REHEARSAL

Maintenance rehearsal: repeating without any consideration of meaning or
making connections with other information
helps maintain information in STM/WM
not an effective way of transferring information into LTM

Elaborative rehearsal: when you think about the meaning of an item or make
connections between the item and something you know
more effective at transferring information into LTM

LEVELS-OF-PROCESSING THEORY

Levels-of-processing theory: memory depends on how information is encoded,
with “deeper” processing resulting in better encoding and retrieval than “shallow”
processing

THE BASICS OF LEVELS OF PROCESSING
depth of processing is determined by the nature of the task during encoding

Shallow processing occurs when attention is focused on physical features
involves little attention to meaning
occurs during maintenance rehearsal

Deep processing focuses on an item’s meaning and relating it to something else
involves close attention
occurs during elaborative rehearsal
results in better memory than shallow processing

THE DIFFICULTY IN DEFINING DEPTH OF PROCESSING
based mainly on common sense
desert island task causes deeper or shallower processing than the fill-in-the-
blanks task
results in deeper processing
no procedure was offered to define depth of processing independently of
memory performance
RESEARCH SHOWING THAT ENCODING INFLUENCES RETRIEVAL

Placing Words in a Complex Sentence
memory for a word is much better when the word is presented in a complex
sentence
complex sentence creates more connections (acting as cues) between the
word to be remembered and other things

Forming Visual Images
paired-associate learning: a list of word pairs is presented
participants who had created images remembered more than twice as many
words as the participants who had just repeated the word pairs

Linking Words to Yourself
self-reference effect: Memory is better if you are asked to relate a word to
yourself
Participants were more likely to remember words that they rated as describing
themselves

Generating Information
Generation effect: generating material yourself enhances learning and
retention, rather than passively receiving it

Organizing Information
The memory systems are designed to organize information so it can be accessed
more efficiently
participants spontaneously organize items as they recall them
Retrieval cue: a stimulus (word) that helps a person remember information
stored in memory
Participants tended to organize their responses in the same way the trees were
organized

Testing
Being tested on the material to be remembered results in better memory than
re-reading it
Testing effect: enhanced performance due to testing

Retrieval: Getting Information Out of Memory

RETRIEVAL CUES
Retrieval cues: as words or other stimuli that help us remember information
stored in our memory

Cued Recall
Free recall: participant is simply asked to recall stimuli
 Cued recall: participant is presented with retrieval cues (stories/elaborations) to
aid in recall of the previously experienced stimuli
retrieval cues aid memory
Increased percentage of words recalled
retrieval cues are significantly more effective when they are created by the
person whose memory is being tested

MATCHING CONDITIONS OF ENCODING AND RETRIEVAL
Another kind of “hint” (cue) that can help with retrieval: returning to a specific
location
Retrieval can be increased by matching the conditions at retrieval to the
conditions that existed at encoding

Encoding Specificity
Encoding specificity: we encode information along with its context
the best recall occurred when encoding and retrieval occurred in the same
location
participants did better when the testing condition matched the study condition

State-Dependent Learning
State-dependent learning: learning that is associated with a particular internal
state (ex: mood or state of awareness)
memory will be better when a person’s internal state/mood during retrieval
matches his or her internal state/mood during encoding

Transfer-Appropriate Processing
Transfer-appropriate processing: memory performance is enhanced if the
type of task at encoding matches the type of task at retrieval
better performance when the same type of task happens during both encoding
and retrieval

EVERYDAY MEMORY & MEMORY ERRORS

Autobiographical Memory: What Has Happened in My Life
Autobiographical memory: recollected events that belong to a person’s past
can also contain semantic components
the relative proportions of episodic and semantic components is defined by how
long ago the event to be remembered occurred
Recent: episodic (emotion, perceptual details)
Distant: semantic (facts)

THE MULTIDIMENSIONAL NATURE

Autobiographical memories are multidimensional because they consist of spatial,
emotional, and sensory components
 If one component is missing = some loss of autobiographical memory

Memory Can Be Modi ed or Created by Suggestion
People are suggestible & information presented by others can influence a person’s
memory for past events

THE MISINFORMATION EFFECT
Misinformation effect: misleading information presented after a person witnesses
an event can change how the person describes that event later
misleading post-event information: misleading information

Presenting Misleading Post-event Information
MPI is then presented (naturally) to one group of participants before their
memory is tested and is not presented to a control group
effect of MPI is determined by comparing the memory reports of participants who
received this misleading information to the memory reports of participants who
did not receive it
MPI can alter not only what participants report they saw, but their conclusions
about other characteristics of the situation
The misinformation effect shows not only that false memories can be created by
suggestion but also provides an example of how different researchers can
interpret the same data in different ways

MPI as Replacing the Original Memory
Memory trace replacement hypothesis: MPI impairs or replaces memories
that were formed during the original experiencing of an event
re-consolidation (reactivating a memory) can create the potential for forming
new memory traces

MPI as Causing Interference
Retroactive interference: occurs when more recent learning (MPI) interferes
with memory for something that happened in the past (the actual event)
the old information isn’t eliminated by the new one; it is simply interfered with

MPI as Causing Source Monitoring Errors
Source monitoring: a person incorrectly concludes that the source of his or her
memory for the incorrect event is due to the experience and not a misleading
information introduced to them
MPI is mistakenly identified as what was originally experienced

DRM false memory effect
False memory to the lure is often as strong as accurate memory for target items
Spreading activation to related words converge on the mis-remembered word
and makes it more ‘available’
fi
Eyewitness testimony
Information can be changed by elaboration or by misleading post-event
information
Results: changing the strength of the verb (crashed vs hit) changed the
perception of speed