Psychology Chapter 18-19 PDF

Summary

This document is a chapter from a psychology textbook, focusing on memory and learning topics such as observational learning, encoding, storage and retrieval, and levels of processing. It includes examples like the self-reference effect and mnemonics.

Full Transcript

**The Process of Observational Learning**

18.1.01 The Process of Observational Learning

**Observational learning**, also known as social learning, occurs when
an observer imitates a behavior that someone else has modeled (Figure
18.1). For example, people can learn new behaviors by watching others
demonstrate those behaviors, such as when a medical student (observer)
sees an experienced surgeon perform a new technique (model) and so they
mimic that technique (imitation)

**The Biological Underpinnings of Observational Learning**

18.2.01 The Biological Underpinnings of Observational Learning

Specialized neurons called **mirror neurons** fire when organisms engage
in a particular behavior and when they observe that behavior in others.
Mirror neurons are found in multiple brain regions, including the
frontal lobe\'s (Figure 18.2) motor cortex, an area of the brain
responsible for planning and initiating voluntary movement.

**Figure 18.2** The frontal lobe.

[Observational learning](javascript:void(0)) (see Lesson 18.1) occurs
when an observer imitates a behavior that someone else has modeled.
Research shows that observational learning involves the mirror neuron
system. Mirror neurons play a role in imitation (the copying of
another\'s behavior) because they fire when an organism watches or
replicates a behavior.

**Encoding, Storage, and Retrieval**

19.1.01 Encoding

Memory involves **encoding**, the transfer of information into memory;
storage (retaining the information); and retrieval (accessing the
information) (Figure 19.1). Some information is processed automatically
with little effort (eg, registering the characters on a license plate as
letters or numbers), but to encode information, attention and effortful
processing are often required (eg, encoding a specific license plate
takes effort).

**Figure 19.1** Memory processes: encoding, storage, retrieval.

**Levels of processing** is a concept that describes how information
processed at a deeper level is encoded and retrieved (ie, remembered)
better than information processed on a shallower level. One encoding
strategy that can enhance memory is **elaboration**, in which new
information is meaningfully associated with previously known
information. This effortful, deep processing tends to result in more
connections to the new material, improving learning.

For example, consider a student studying the meaning of the words
\"ventral\" and \"dorsal.\" While studying the word ventral, she focuses
only on the appearance of the word and notices that it starts with a
\"v.\" In contrast, while studying the meaning of the word dorsal (ie,
\"to the back\"), she uses elaboration by meaningfully associating this
information with her favorite animal, dolphins, which have dorsal fins
on their backs. As a result, this student has better recall of the
meaning of the word dorsal as compared to ventral because she processed
information about the word dorsal at a deeper level (Figure 19.2).

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**Figure 19.2** Elaboration example.

Similarly, the **self-reference effect** states that information that is
personally relevant (ie, linked to oneself) is easier to remember
because personally relevant information is meaningful and so is
processed at a deeper level. For example, an individual who has
difficulty remembering passwords changes their email password to the
date of their wedding, making the password personally relevant, which
leads to easier retrieval (Figure 19.3).

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**Figure 19.3** Self-reference effect example.

Additionally, **mnemonics** are strategies (eg, songs, acronyms) that
aid memory encoding and retrieval. For example, an individual uses an
acronym to help her remember the colors of the rainbow (Figure 19.4).

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**Figure 19.4** Mnemonic example.

19.1.02 Storage

As Concept 19.1.01 introduces, memory involves three steps: encoding,
storage, and retrieval. **Storage** refers to retaining the encoded
information. The three types of memory, sensory memory, short-term
memory, and long-term memory, hold information for varying amounts of
time (Figure 19.5). **Sensory memory** first briefly and temporarily
stores information from the environment (eg, sights, sounds). Iconic
memory is sensory memory of visual information, whereas echoic memory is
sensory memory for auditory information.

**Figure 19.5** Three-stage model of memory.

**Short-term memory** then stores pieces of information from sensory
memory. Short-term memory has a short duration (about 20 seconds) and a
storage capacity of about seven items (plus or minus two). Maintenance
rehearsal (mentally repeating something over and over) can prolong the
duration of short-

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term memory. Chunking describes the strategy of grouping items into
clusters that are more easily held in short-term memory (eg, grouping
the digits of a phone number into three chunks rather than a long series
of individual digits).

Information not transferred from short-term to long-term memory is lost.
**Long-term memory** has a large capacity and a long duration (memories
can be stored permanently) and comprises two branches: implicit memory
and explicit memory.

**Implicit memory** (also called nondeclarative memory) is memory for
things that cannot be consciously recalled, such as skills, tasks,
emotions, and reflexes. Implicit memory includes procedural memory,
which is memory for well-learned motor skills (eg, riding a bicycle).
Another example of implicit memory is emotional/reflexive memory, which
is memory for associations between stimuli (eg, salty ocean air triggers
pleasant emotions from childhood beach vacations).

In contrast, **explicit memory** (also called declarative memory) is
memory for facts and events that can be consciously or intentionally
recalled. Explicit memory includes episodic memory, which is the memory
for personal experiences (eg, what one ate for dinner last night), and
semantic memory, which includes knowledge about facts (eg, Austin is the
state capital of Texas) and language (eg, \"their\" and \"there\" are
not synonymous).

Semantic long-term memory appears to be organized as a network of
interconnected nodes containing factual concepts (eg, colors, objects).
The organization and relationship between nodes (how linked or connected
they are in memory) is unique to each individual because of the personal
meaning associated with each node. For example, an individual with an
uncle who is a firefighter may think of \"uncle\" when viewing a fire
engine, which would not occur for most people.

The **spreading activation model** suggests that when a node in the
semantic network is activated (eg, viewing a picture of a toy fire
engine), nodes directly connected to that node (eg, siren, alarm) are
activated as well, which is known as priming.

19.1.03 Retrieval

As Concept 19.1.01 introduces, the final step involved in memory is
retrieval. **Retrieval** refers to accessing the encoded information
from storage. There are three types of memory retrieval processes:
recall, recognition, and relearning.

Recall is the retrieval of information previously encoded.

Recognition involves the correct identification of information that one
has been exposed to.

Relearning involves re-encoding information that was previously learned
but forgotten. Typically, relearning happens much faster than learning
something for the first time.

Memory retrieval can be aided by internal (eg, emotional state) or
external (eg, sights, smells) cues (Figure 19.6). **Context-dependent
effects** are external cues that aid retrieval. For example, if an
individual encodes a memory at the library, that memory is easier to
recall (ie, retrieve) at the library than in class. **State-dependent
effects** are internal cues that aid retrieval. For example, if an
individual encodes a memory while happy, that memory is easier to
retrieve during a later happy mood than when sad.

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**Figure 19.6** State-dependent versus context-dependent memory effects.

The **serial position effect** describes how the relative ease (or
difficulty) of remembering an item from a list is related to the item\'s
position on the list. The items that are easiest to recall are those
from the beginning (called the primacy effect) and end (called the
recency effect) of the list, while the middle items are the hardest to
recall. For example, when an individual views a list of items one at a
time, the items studied first and last would be the easiest to remember,
and those from the middle would be the hardest to remember (Figure
19.7).

**Figure 19.7** The serial position effect.


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Chapter 19: Memory

A retrieval failure in which a person experiences only partial recall of
a word or term is called the **tip-of-the-tongue phenomenon**.
Individuals experiencing the tip-of-the-tongue phenomenon can often
recall details about the word they are trying to retrieve, such as the
first letter or number of syllables, but they cannot recall the word
itself despite feeling that the information is \"on the tip of the
tongue.\" For example, an individual is unable to recall the word
\"peony\" despite knowing that the word is the name of a flower and
begins with the letter \"p\" (Figure 19.8)

19.2

**Forgetting**

19.2.01 Decay and Interference

**Memory Decay**

Early memory researcher Hermann Ebbinghaus assessed his own memory by
studying a list of short nonsense syllables and then repeatedly testing
his memory for the syllables over time. Ebbinghaus found that **memory**
**decay** (ie, forgetting) follows a characteristic pattern known as the
**forgetting curve** (Figure 19.9): the initial rate of decay is
greatest right after the material is first learned, then the rate of
decay plateaus over time unless the material is reviewed again.

**Figure 19.9** Typical memory decay: the forgetting curve.

Numerous studies have since produced the same basic forgetting curve
shape for different types of memory, including short-term and several
types of long-term memory (eg, episodic, semantic, procedural).

**Interference**

A common memory error that occurs when previously learned information
interferes with the ability to recall new information is called
**proactive interference**. For example, an individual\'s father cannot
remember her new boyfriend\'s name (ie, recent information) and
repeatedly refers to him by her old boyfriend\'s name (ie, older
information).

Conversely, **retroactive interference** occurs when recently encoded
information prevents the recall of older information. For example, an
individual\'s father cannot remember her old boyfriend\'s name (ie,
older information) and repeatedly refers to him by her new boyfriend\'s
name (ie, recent information). Proactive and retroactive interference
are contrasted in Figure 19.10.


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**Figure 19.10** Proactive versus retroactive interference.

19.2.02 Memory Construction

Memories are not perfect recordings of past events. **Memory
reconstruction** refers to how memories are altered in the process of
retrieval and subsequent storage.

In Elizabeth Loftus\'s memory reconstruction experiments, participants
were shown films of car accidents and later asked about them. The
results showed that a question about \"the crash\" as opposed to \"the
fender bender\" influenced how the participants remembered the event.
This **misinformation effect** explains how misleading information
presented after an event can distort memories, and these experiments are
often cited to bring the validity of eyewitness testimony into question.

The process of memory reconstruction leads to some common memory
mistakes, such as **source monitoring errors**, which occur when a
memory is attributed to the wrong source. For example, an individual may
think they heard a joke from their father, but they actually heard it
from a friend. The misinformation effect and source monitoring errors
help explain **false memories**: memories that are distorted or memories
of something that did not occur.

19.2.03 Aging and Memory

Aging affects the various types of memory differently. Aging has been
associated with declines in certain types of memory, including episodic
and source memory. Episodic memory (Concept 19.1.02) is the memory of
autobiographical events (eg, the name of a childhood friend), whereas
source memory is memory for the source of learned information (eg,
correctly attributing one\'s knowledge of an event to a newspaper
article).

Aging is also associated with declines in **flashbulb memory**: a vivid,
detailed type of autobiographical memory for an event that was extremely
emotional, distinct, or significant to the individual (eg, the 9/11
attacks, the birth of a child). Individuals are able to vividly recall
specific details surrounding the event, such as what they were wearing
and their emotional state at the time of the event. Once thought to be
extremely accurate snapshots of emotionally arousing events, studies
suggest that for people of all ages, flashbulb memories are not
completely accurate or consistent over time, despite people\'s
confidence in their recollections.

In contrast, other types of memory appear to remain relatively stable
with age, such as semantic memory (memory for words, facts, and concepts
that have been acquired over the lifetime) (see Concept 19.1.02).
Additionally, procedural memory, which involves motor skills one has
acquired, also remains relatively stable across adulthood.

19.2.04 Memory-Related Symptoms

Amnesia is severe memory loss that can be caused by brain trauma (eg, a
head injury). Amnesia can be classified by whether the memory loss
affects new or old explicit/declarative memories (ie, memory for facts
and events that can be intentionally recalled):

**Retrograde amnesia** is the loss of memories acquired prior to the
trauma. For example, the patient cannot remember what they were doing
just before the trauma.

**Anterograde amnesia** is the inability to form new memories. For
example, a patient can temporarily learn information while paying
attention, but this information, such as a new plan, cannot be
permanently stored and recalled later. Retrograde and anterograde
amnesia are contrasted in Figure 19.11

**The Biological Underpinnings of Memory**

19.3.01 Neural Plasticity

**Neural plasticity** (or neuroplasticity) refers to the ability of
neurons to change. The strengthening of neural connections, known as
potentiation, and weakening of neural connections, known as depression,
illustrate plasticity. Neuroplasticity enables the modification of
neurons during learning and can allow entire brain regions to recover
function after an injury.

Plasticity allows for synaptic as well as structural changes. Synaptic
plasticity is exemplified by changes in the firing rate of the
presynaptic neuron(s) altering the amount of neurotransmitter released
into the synaptic cleft and/or the number of postsynaptic receptors. In
contrast, forms of structural plasticity include sprouting (new
connections between neurons), rerouting (altered connections between
neurons), and pruning (elimination of connections between neurons).

Mechanisms such as these can, in some cases, allow the brain to
repurpose an area that is no longer used. For example, in an individual
who lost their sight at an early age, the occipital lobe (visual
processing area) is no longer receiving visual information. That brain
area may then become involved in processing information from the other
senses (eg, auditory processing) (Figure 19.12).

**Figure 19.12** Example of neural plasticity after the loss of sight.

19.3.02 Long-Term Potentiation

As Concept 19.3.01 introduces, neural plasticity refers to neurons\'
ability to change (eg, alterations to synapses). **Long-term
potentiation** (LTP) occurs when synapses that are stimulated frequently
are strengthened (ie, become more effective). Animal research has
supported the assertion that LTP enables both associative and
non-associative learning.

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Although LTP occurs at synapses throughout the brain, it has been
extensively studied at glutamatergic synapses in the hippocampus because
LTP at these synapses is hypothesized to be the mechanism underlying
memory consolidation. Consolidation is the process of converting
memories that are being kept temporarily as synaptic alterations into
long-term memory. Researchers have shown that brief, high-frequency (ie,
tetanic) stimulation of a hippocampal glutamatergic neuron induces LTP
and an excitatory postsynaptic potential (see Concept 4.2.02) that is
increased in magnitude relative to baseline (see Figure 19.13).

**Figure 19.13** Tetanic stimulation induces long-term potentiation at
hippocampal synapses.

LTP can result in changes to the presynaptic or postsynaptic neurons.
Increased calcium influx causes increased presynaptic neurotransmitter
release. At the postsynaptic neuron, LTP can cause phosphorylation of
postsynaptic receptors (leading to increased effectiveness), the
insertion of new receptors into the membrane, and an increase in
dendritic spine density, for example. The exact mechanisms of LTP vary
based on brain region and synapse type.

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Increased presynaptic neurotransmitter release is a more immediate but
transient form of LTP. Longer lasting strengthening of synaptic
connections involves alterations in gene expression, the synthesis of
new proteins, and/or new synaptic connections. The consolidation of
short-term memory into long-term memory, for example, requires changes
to existing proteins at synapses as well as new protein synthesis and
altered gene expression.

In addition to occurring as a result of repeated, high-frequency
stimulation from one presynaptic input, LTP can also occur when two (or
more) presynaptic neurons repeatedly fire at the same time. For example,
if neuron C repeatedly receives simultaneous input from two sources,
neuron A and neuron B, both synapses may become potentiated. Following
potentiation, either neuron A or neuron B alone can cause an action
potential in neuron C, whereas previously neither was sufficient to
induce postsynaptic depolarization to threshold. This process is
hypothesized to be the neural foundation for learned associations, such
as if, in this case, neuron A relays visual information about a flower
and neuron B relays olfactory information about a flower, the appearance
and smell of a flower become linked.

In contrast, **long-term depression** (LTD) describes when synapses that
are stimulated infrequently are weakened. LTD can result in, for
instance, a decrease in presynaptic neurotransmitter release,
dephosphorylation and an internalization of postsynaptic receptors, a
decrease in dendritic spine density, and synaptic pruning. Examples of
LTP and LTD are depicted in Figure 19.14