Connection between learning and memory ppt.ppt
shitalmusale1
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Aug 28, 2025
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About This Presentation
Learning and Memory
Slide Content
Learning and Memory
Adapted from:
home.cc.umanitoba.ca/~marotta/3350/Lecture18_memory.ppt
www.hartnell.edu/faculty/.../powerpoint/...PPT/Coon_08... - United States
Adapted from:
home.cc.umanitoba.ca/~marotta/3350/Lecture18_memory.ppt
www.hartnell.edu/faculty/.../powerpoint/...PPT/Coon_08... - United States
Why are learning and memory important?
To be able to adapt to changes in the environment
Learning
•Acquire and process information from the
environment
Changes the nervous system
Memory
•Ability to retain this information
To be able to adapt to changes in the environment
Learning
•Acquire and process information from the
environment
Changes the nervous system
Memory
•Ability to retain this information
Hypothesized Memory Processes
Incoming
information
Performance
Retrieval
Working
memory
Short-term
storageEncoding
Long-term
storage
Consolidation
Sensory
buffers
Sight
Sound
Smell
Touch
Adapted from Rozenzeig, 2002
Loss of information
Incoming
information
Performance
Retrieval
Working
memory
Short-term
storageEncoding
Long-term
storage
Consolidation
Sensory
buffers
Sight
Sound
Smell
Touch
Adapted from Rozenzeig, 2002
Loss of information
Multiple Trace Hypothesis of Memory
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Sensory buffer
Short-term memory
Intermediate-term memory
Long-term memory
High
Low
Input
Adapted from Rozenzeig, 2002
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Sensory buffer
Short-term memory
Intermediate-term memory
Long-term memory
High
Low
Input
Adapted from Rozenzeig, 2002
Multiple Memory Systems Hypothesis
Memory can be divided into categories that reflect the type of
information being remembered.
Each system primarily employs a distinct brain region
Declarative Hippocampus
Procedural Basal Ganglia
Emotional Amygdala
‘Working With’ Memory Prefrontal Cortex
Memory can be divided into categories that reflect the type of
information being remembered.
Each system primarily employs a distinct brain region
Declarative Hippocampus
Procedural Basal Ganglia
Emotional Amygdala
‘Working With’ Memory Prefrontal Cortex
Sensory memory
•Large capacity, but rapid decay
•Sensory association areas involved
•Example: Your mother is lecturing
you and you aren’t paying attention,
however, if asked, you can repeat the
last sentence she said.
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Sensory buffer
High
Low
Input
•Large capacity, but rapid decay
•Sensory association areas involved
•Example: Your mother is lecturing
you and you aren’t paying attention,
however, if asked, you can repeat the
last sentence she said.
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Sensory buffer
High
Low
Input
Short-term memory
(Working memory)
•Lasts for seconds to minutes
•Severely limited capacity
•magical 7 ± 2 – hold for digits, letters,
etc.
•Available to conscious awareness
•Prefrontal cortex involved
•Example: remember a phone number
between looking it up and dialing
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Sensory buffer
Short-term memory
High
Low
Input
(Working memory)
•Lasts for seconds to minutes
•Severely limited capacity
•magical 7 ± 2 – hold for digits, letters,
etc.
•Available to conscious awareness
•Prefrontal cortex involved
•Example: remember a phone number
between looking it up and dialing
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Sensory buffer
Short-term memory
High
Low
Input
Intermediate-term Memory
•Lasts for hours and days
•May be transferred to LTM through
rehearsal
•Example: remembering where you
parked your car
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Sensory buffer
Short-term memory
Intermediate-term memory
High
Low
Input
•Lasts for hours and days
•May be transferred to LTM through
rehearsal
•Example: remembering where you
parked your car
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Sensory buffer
Short-term memory
Intermediate-term memory
High
Low
Input
STM and Forgetting
• Decay theory
•memory fades away with time, unless there is rehearsal
• Interference theory
•memory for other material interferes with information
we are trying to remember
• Decay theory
•memory fades away with time, unless there is rehearsal
• Interference theory
•memory for other material interferes with information
we are trying to remember
Decay Theory of Forgetting
100%
Rehearsal
Day 1 Day 2 Day 7 Day 30
•Example: reviewing notes after class
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•Memory fades away with time
•unless there is rehearsal
100%
Rehearsal
Day 1 Day 2 Day 7 Day 30
•Example: reviewing notes after class
A
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•Memory fades away with time
•unless there is rehearsal
Interference Theory of Forgetting
Example: studying versus cramming
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Massed Learning
Spaced Learning
•Better recall when presentation of information is spaced
Massed
Spaced
Example: studying versus cramming
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Massed Learning
Spaced Learning
•Better recall when presentation of information is spaced
Massed
Spaced
Interference Theory of Forgetting
BOOK
CAP
HAWK
BALL
LETTER
BIRD
CAN
SHIRT
LION
DOOR
•Better recall for items presented first (primacy) and last (recency) in
a list
BOOK
CAP
HAWK
BALL
LETTER
BIRD
CAN
SHIRT
LION
DOOR
•Better recall for items presented first (primacy) and last (recency) in
a list
Mechanisms of Primacy and Recency
Primacy:
•Memory system has enough resources to transfer
items at the beginning of a list into LTM
Recency:
•Items at the end of the list are still in STM and
are therefore available for recall
1. BOOK
2. CAP
3. HAWK
4. BALL
5. LETTER
6. BIRD
7. CAN
8. SHIRT
9. LION
10. DOOR
Primacy:
•Memory system has enough resources to transfer
items at the beginning of a list into LTM
Recency:
•Items at the end of the list are still in STM and
are therefore available for recall
1. BOOK
2. CAP
3. HAWK
4. BALL
5. LETTER
6. BIRD
7. CAN
8. SHIRT
9. LION
10. DOOR
Hypothesized Memory Processes
Incoming
information
Performance
Retrieval
Working
memory
Short-term
storageEncoding
Long-term
storage
Consolidation
Sensory
buffers
Sight
Sound
Smell
Touch
Adapted from Rozenzeig, 2002
Attention Rehearsal
Incoming
information
Performance
Retrieval
Working
memory
Short-term
storageEncoding
Long-term
storage
Consolidation
Sensory
buffers
Sight
Sound
Smell
Touch
Adapted from Rozenzeig, 2002
Attention Rehearsal
Factors Affecting Primacy and Recency
•A distractor task at the end of a list interfered with recency, but not
primacy.
•Interrupts rehearsal
•A faster presentation rate interfered with primacy, but not recency.
•Increases load and effects transfer of information from STM to
LTM
•Changing the length of delay between training and testing interfered
with both primacy and recency.
•A distractor task at the end of a list interfered with recency, but not
primacy.
•Interrupts rehearsal
•A faster presentation rate interfered with primacy, but not recency.
•Increases load and effects transfer of information from STM to
LTM
•Changing the length of delay between training and testing interfered
with both primacy and recency.
Effect of Delay on Primacy and Recency
40
60
80
100
Serial Position of Memory Item
P
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Test immediately
Test after short delay
Test after long delay
Primacy
Recency
40
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80
100
Serial Position of Memory Item
P
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Test immediately
Test after short delay
Test after long delay
Primacy
Recency
Consolidation
•Hippocampus and amygdala involved
•Memories are subject to modification during reactivation and
reconsolidation
•Memories are more likely to reflect how person perceived the event,
rather than what actually happened
•Confidence is not correlated with accuracy
•Implications for eyewitness accounts, repressed memories of
abuse
•Hippocampus and amygdala involved
•Memories are subject to modification during reactivation and
reconsolidation
•Memories are more likely to reflect how person perceived the event,
rather than what actually happened
•Confidence is not correlated with accuracy
•Implications for eyewitness accounts, repressed memories of
abuse
Story so far…
Learning and memory involves multiple processes, traces and systems.
•Processes
•Encoding, consolidation and retrieval
•Traces
•Sensory, short-, intermediate- and long-term
•Systems
•Declarative, procedural, emotional, ‘working-with’
Learning and memory involves multiple processes, traces and systems.
•Processes
•Encoding, consolidation and retrieval
•Traces
•Sensory, short-, intermediate- and long-term
•Systems
•Declarative, procedural, emotional, ‘working-with’
Long-term memory
•Lasts for months and years
•Takes a long time to consolidate
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Sensory buffer
Short-term memory
Intermediate-term memory
Long-term memory
High
Low
Input
Declarative
•Episodic
•Semantic
Non-declarative
•Procedural
•Perceptual
•Conditioning
•Non-associative
•Lasts for months and years
•Takes a long time to consolidate
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Sensory buffer
Short-term memory
Intermediate-term memory
Long-term memory
High
Low
Input
Declarative
•Episodic
•Semantic
Non-declarative
•Procedural
•Perceptual
•Conditioning
•Non-associative
Declarative memory
•Knowledge we have conscious access to
•Often referred to as explicit memory
•Episodic
•Personal experiences / events etc.
•Canoeing on Lake Winnipeg, surfing in San Diego
•Often referred to as autobiographical memory
•Semantic
•Conceptual knowledge
•“Where is Lake Winnipeg, where is San Diego?”
•“How do you canoe, how do you surf?”
•Knowledge we have conscious access to
•Often referred to as explicit memory
•Episodic
•Personal experiences / events etc.
•Canoeing on Lake Winnipeg, surfing in San Diego
•Often referred to as autobiographical memory
•Semantic
•Conceptual knowledge
•“Where is Lake Winnipeg, where is San Diego?”
•“How do you canoe, how do you surf?”
Non-declarative Memory
•Performance informed by implicit knowledge
•Perceptual memory
•Priming
•Procedural memory
•Operant / instrumental conditioning
•Emotional memory
•Conditioned fear response
•Non-associative memory
•Habituation / sensitization
•Performance informed by implicit knowledge
•Perceptual memory
•Priming
•Procedural memory
•Operant / instrumental conditioning
•Emotional memory
•Conditioned fear response
•Non-associative memory
•Habituation / sensitization
Perceptual Memory:
Priming
•An alteration of response to a stimulus as a result of prior exposure
Priming
•An alteration of response to a stimulus as a result of prior exposure
•Can last for hours
•Not dependent on level of processing
•Reduced (but not eliminated) when presentation and test modalities
are different
•Perceptual short-term memory involves
the sensory association cortices
Perceptual Memory:
Priming
•Not dependent on level of processing
•Reduced (but not eliminated) when presentation and test modalities
are different
•Perceptual short-term memory involves
the sensory association cortices
Perceptual Memory:
Priming
Procedural Memory:
Instrumental / Operant Conditioning
Pressing a button provides a reward
•Increases the likelihood that the animal will press the button again
Instrumental / Operant Conditioning
Pressing a button provides a reward
•Increases the likelihood that the animal will press the button again
Procedural Memory:
Instrumental / Operant Conditioning
•Association between stimulus-response
•Stimuli following a behaviour can be either:
•Reinforcing: perceived as positive
•Punishing: perceived as negative
•Basal ganglia are involved
Instrumental / Operant Conditioning
•Association between stimulus-response
•Stimuli following a behaviour can be either:
•Reinforcing: perceived as positive
•Punishing: perceived as negative
•Basal ganglia are involved
Procedural Memory:
Motor Learning
Other examples: how to tie a shoe lace, ride a bike, drive a manual
transmission, play piano
Series of connected movements that become automatic with practice.
Motor Learning
Other examples: how to tie a shoe lace, ride a bike, drive a manual
transmission, play piano
Series of connected movements that become automatic with practice.
Emotional Memory:
Conditioned Fear
•Little Albert
•Conditioned to fear rats – hammer hitting metal
•Extended to other furry animals and objects
•Association between stimulus-valence (pleasant-unpleasant)
•Amygdala is involved
Conditioned Fear
•Little Albert
•Conditioned to fear rats – hammer hitting metal
•Extended to other furry animals and objects
•Association between stimulus-valence (pleasant-unpleasant)
•Amygdala is involved
Emotional Memory:
Conditioned Fear
•Nothing lasts forever!
•If CS is repeated without US often enough, then the CR
disappears (extinction)
Conditioned Fear
•Nothing lasts forever!
•If CS is repeated without US often enough, then the CR
disappears (extinction)
Non-associative Memory: Habituation
•Ignore incoming information that is not relevant
•Most basic form of learning
•Even worms can do it
•Ignore incoming information that is not relevant
•Most basic form of learning
•Even worms can do it
Short-term memory
•Prefrontal cortex, sensory
association areas
Declarative long-term memory
•Hippocampus
Procedural long-term memory
•Basal ganglia, motor association
areas, cerebellum
Emotional long-term memory
•Amygdala
Memory can be subdivided into multiple categories
•involve distinct brain regions.
•Prefrontal cortex, sensory
association areas
Declarative long-term memory
•Hippocampus
Procedural long-term memory
•Basal ganglia, motor association
areas, cerebellum
Emotional long-term memory
•Amygdala
Memory can be subdivided into multiple categories
•involve distinct brain regions.
Long-term potentiation
•Stimulation of pre-synaptic neuron leads to a long-term increase in
the magnitude of EPSPs in post-synaptic neurons
•First measured in hippocampal tissue
•Stimulation of pre-synaptic neuron leads to a long-term increase in
the magnitude of EPSPs in post-synaptic neurons
•First measured in hippocampal tissue
LTP and Firing Rate
•For LTP to occur, rapid rate of stimulation is needed
•EPSP’s are summated as successive EPSP’s occur and before past
EPSP’s have dissipated
•For LTP to occur, rapid rate of stimulation is needed
•EPSP’s are summated as successive EPSP’s occur and before past
EPSP’s have dissipated
Synaptic plasticity
•LTP strengthens existing synapses and creates new ones
•Important for recovery of function post stroke
Before LTP
Presynaptic density
After LTP
Synaptic structure
Before LTPAfter LTP
•LTP strengthens existing synapses and creates new ones
•Important for recovery of function post stroke
Before LTP
Presynaptic density
After LTP
Synaptic structure
Before LTPAfter LTP
Long-term depression
•A long-term decrease in the excitability of a neuron to a particular synaptic
input caused by stimulation of the terminal button while the postsynaptic
membrane is hyperpolarized.
•Low frequency stimulation decreasing the strength of synaptic connections
(> 10 Hz)
•May allow for reversal of learned
patterns in response to changes in the
environment
•A long-term decrease in the excitability of a neuron to a particular synaptic
input caused by stimulation of the terminal button while the postsynaptic
membrane is hyperpolarized.
•Low frequency stimulation decreasing the strength of synaptic connections
(> 10 Hz)
•May allow for reversal of learned
patterns in response to changes in the
environment
Learning: Some Key Terms
Learning: Relatively permanent change in
behavior due to experience
Does NOT include temporary changes due to
disease, injury, maturation, or drugs, since these
do NOT qualify as learning even though they can
alter behavior
Reinforcement: Any event that increases the
probability that a response will recur
Response: Any identifiable behavior
Internal: Faster heartbeat
Observable: Eating, scratching
Learning: Relatively permanent change in
behavior due to experience
Does NOT include temporary changes due to
disease, injury, maturation, or drugs, since these
do NOT qualify as learning even though they can
alter behavior
Reinforcement: Any event that increases the
probability that a response will recur
Response: Any identifiable behavior
Internal: Faster heartbeat
Observable: Eating, scratching
Learning: More Key Terms
Antecedents: Events that precede a response
Consequences: Effects that follow a response
Antecedents: Events that precede a response
Consequences: Effects that follow a response
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