Foundations of Perception and Cognition - Short-Term and Working Memory: Part 2 PDF

Summary

This document presents lecture notes on the subject of short-term and working memory in cognitive psychology. The lecturer covers various concepts, including the model of working memory, systems like the phonological loop and visuospatial sketchpad, and their applications.

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 Part 1 (Lecture 1) Part 2 (Lecture 2)
What is Memory? Working Memory: Overview
An Early Model of Memory The Phonological Loop
Short-Term Memory (pre-1970’s) What Use is The Phonological Loop?
Short-Term and Working Memory The Visuo-Spatial Sketchpad?
What Use is The Visuo-Spatial Sketchpad?
The Central Executive and Episodic Buffer
Working Memory: Evaluation
 Recommended Reading

This week’s recommended reading is:

Goldstein Chapter 5:
Short-Term and Working Memory

I discuss most major topics* but don’t always
cover them in the same order. I also cover
interesting topics that are not in the chapter

*Example: I leave out the content from the ‘Working Memory and the Brain’ section, but please do read this section
A Quick Recap

Atkinson and Shiffrin’s (1969) Modal Model of Memory saw STM as a unitary system for temporarily
storing small amounts of information. Then, in the early 1970’s:

1. Brain lesion research showed Verbal STM and Visuo-Spatial STM are distinct systems
2. STM underpins many cognitive abilities (e.g., reading, maths, problem solving)

Baddeley and Hitch (1974) there proposed a new model of STM called The Working Memory Model,
that had several systems and emphasised STM’s role in underpinning cognitive tasks
Defining Working Memory

Baddeley and Hitch (1974) defined WM as:

“a limited-capacity system for temporary storage
and manipulation of information for complex tasks
such as comprehension, learning, and reasoning”

Their original model had three systems, but
Baddeley (2000) added a fourth (see right)
STM vs Working Memory

Before discussing the Working Memory Model, let’s clarify how STM and WM differ. Some people use
both terms interchangeably, but most distinguish between:

 STM tasks: Participants briefly study / immediately recall information (e.g., a digit span task)

 WM tasks: Participants briefly study / immediately recall information, but also complete an ongoing
task at the same time and/or manipulate the information (e.g., recalling digits in a new order)

Most studies I discuss in this lecture are technically STM studies
The Working Memory Model

Two of the four systems are the:

1. Phonological Loop (Verbal STM)
 Temporarily stores language / sound-based
information (e.g., words when reading or
listening to a conversation)

2. Visuo-Spatial Sketchpad (Visuo-Spatial STM)
 Temporarily stores images / spatial location
information (e.g., colours or object locations) The Working Memory Model
The Working Memory Model

The other two systems are the:

3. Central Executive
 An attention system (not memory) that helps
us focus attention, switch attention between
tasks, and divide attention

4. Episodic Buffer
 Integrates / temporarily stores information
from the PL, VSSP, and LTM (e.g., chunking) The Working Memory Model
Working Memory and Everyday Abilities

Working Memory supports “complex tasks such as
comprehension, learning, and reasoning”

Working memory ability is a more powerful
predictor of success in school than IQ, and
strongly predicts workplace success

In class, I will show a 1 min 45 video by Alloway
and Alloway (see right) discusses its importance
Overview

Temporarily stores language / sound-based
information (so Verbal STM). It has two systems:

1. The Phonological Store: Speech enters the
store directly/is temporarily stored
2. The Articulatory Control Process: Written
words enter here, are converted, and are
transferred to the Phonological Store

What do I mean when I say written words are converted?
 Overview

The Phonological Store stores information in
a phonological (sound-based) code or format

Speech is in a phonological code (it is made
of sound) and can enter the store directly

Information in the store is quickly forgotten
(e.g., in 20 secs) unless rehearsed in the
Articulatory Control Process

The Articulatory Control Process is also called the Articulatory Loop or Articulatory Rehearsal Process
 Overview

Written words are not in a phonological (sound-
based) code, so cannot enter the store directly

They enter the Articulatory Control Process, are
converted to a phonological code using subvocal
articulation* (rehearsal) and are then sent to the
Phonological Store. Information in the store is
quickly forgotten (e.g., in 20 secs) unless
rehearsed in the Articulatory Control Process

*This is the voice you hear in your head each time you read a word.
Testing the Phonological Loop

Baddeley (1990) made several claims about the phonological loop. What evidence is there that:

1. Claim 1: Written and spoken letters/words are stored in phonological codes

2. Claim 2: Visually and aurally presented letters/words are processed differently:
 Speech is in a phonological code so enters the Phonological Store directly
 Written words are not in a phonological code. They must be converted into one to enter the store

Studies supporting both suggestions will now be discussed
Claim 1: Phonological codes

Letters/words that sound similar can get confused on STM tests (the phonological-similarity effect)

Their visual appearance or meaning has far less impact (so their sound seems to really matter)

 Conrad’s (1964) participants incorrectly recalled more non-studied letters that sounded like studied
ones (e.g., D, when C was studied) than looked like them (e.g., E, when F was studied)

 Baddeley’s (1966) participants made more errors recalling phonologically similar words (e.g., Cat,
Mat, Bat) than semantically similar words (e.g., Huge, Large, Big)
Claim 2: Different Processing Mechanisms

Baddeley et al.’s (1975) participants studied lists of 8 words:

▪ Some contained 1 syllable words (short lists) Word length effect
▪ Some contained 8 syllable words (long lists) should occur

 The lists were presented either aurally or visually Visual words need
converting

On 50% of trials, participants engaged in Articulatory Suppression to stop them
(1) rehearsing the words and (2) converting visual words to phonological codes
Claim 2: Different Processing Mechanisms

Baddeley et al.’s auditory presentation results:

▪ A word-length effect occurred, irrespective
of articulatory suppression (sloping lines)

▪ Articulatory suppression stopped rehearsal
and recall was impaired slightly (black line)

What happened during the visual presentation when words were not in a
sound-based format and needed converting?
Claim 2: Different Processing Mechanisms

Baddeley et al.’s visual presentation results:

▪ With no articulatory suppression (green line),
written words could be converted, recall was
good, and the word-length effect occurred

▪ When articulatory suppression occurred
(yellow line), written words could not be
converted, regardless of length. Recall was
poor and the word-length effect disappeared
The Phonological Loop and Language

Baddeley et al. (1998) argue the PL evolved to
support language acquisition

They felt it enables us to temporarily store and
repeat unfamiliar sound patterns (i.e., new words)
whilst permanent records are being constructed

This is important for longer words. If you struggle
holding them in Verbal STM, learning is harder
The Phonological Loop and Language

Gathercole and Baddeley (1990) tested:
Language impaired
 8-year-olds: language skills of a 6-year-old 8-year-olds
 6 & 8-year-olds: age-typical language skills struggled with non-
word repetition

Language-impaired 8-year-olds were worst on a
Verbal STM test and at repeating longer non-
words (e.g., woogalamic), as they should could
not hold them in mind to process / repeat them
The Phonological Loop and Language

Baddeley et al. (1988) studied Patient PV, who Healthy controls
learned foreign
developed Verbal STM problems after a stroke word-pairs easily
after 10 attempts

Her digit span was 2 - 3 items, but she had normal
visuo-spatial STM, LTM, and IQ PV could not
learn foreign
word-pairs after
PV and controls could easily learn native language 10 attempts
word-pairs, but could not learn foreign language
word-pairs (controls learnt them in 10 attempts)
Overview

1970’s researchers mainly studied the PL. In the
1980’s, Bob Logie studied the VSSP in detail. In
Logie (1995), he concluded it has two systems:

1. The Visual Cache: Stores visual information
about object shapes, patterns, and colours

2. The Inner Scribe: Stores spatial information Bob Logie worked with Baddeley on
(e.g., object locations and movement) many of his early VSSP studies
Evidence for Two Systems

Cognitive neuropsychological research on patients with brain lesions identified a double-dissociation
between performance on Visual Cache tasks (e.g., immediately recalling the colours of studied objects)
and Inner Scribe tasks (immediately recalling the spatial locations of studied objects):

Patient and Study Lesion Cause Visual Cache Tasks Inner Scribe Tasks

Patient L.H. Traffic accident Poor Normal
Farah et al. (1988)
Patient M.V. Stroke Normal Poor
Carlesimo et al. (2001)
The Visual Cache (Capacity)

Alvarez and Cavanagh (2004) tested the visual
cache’s capacity to see if is the same as Verbal
STM’s. They used stimuli of varying complexity:
 Squares (poor accuracy if 4.4 items)
 Polygons (poor accuracy for 2 items)
 Cubes (poor accuracy if 1.6 items)

The more complex a shape, the fewer could be
temporarily stored/recalled
The Inner Scribe (Capacity)

Vandierendonck et al. (2004) studied the inner
scribe’s capacity using Corsi blocks:

 A researcher taps out a sequence on blocks.
The participant must repeat the sequence

On average, participants could correctly recall the
order of 6 taps (so had a spatial span of 6) A child repeating a Corsi Block sequence
 Demonstration
In class, time permitting, we will test your Inner Scribe’s spatial memory capacity

5 items 6 items 7 items
The Inner Scribe (Capacity)

Corsi blocks were invented by Corsi (1972) and
based on Knox’s (1913) Cube Imitation Task

 Knox’s task was used to screen immigrants to
the US for intelligence problems (see right)

Random question: Can you outperform a chimp
on a spatial span task? In class, you will find out
Everyday Uses of the Visuo-Spatial Sketchpad

The VSSP has many uses (e.g., temporarily storing
what objects look like and their location in space,
before permanent records are created in LTM)

It plays a role in many tasks, such as learning new
routes when walking (Garden et al., 2001)

On the next two slides, its role in visual search
and visual imagery are considered
 The VSSP and Visual Search

Aziz et al. (2001), and others, have shown the
VSSP plays a role in visual searches:

 It holds information about target features &
previously searched distractors and locations

For young adults participants (18-35), as VSSP
capacity increased, search times decreased* A target (shown pre-search) and search array

*Older adults verbal STM capacity predicted search times. They had worse VSSP capacity (it declines faster than Verbal STM with
age) and their searches were highly verbalised (mentally rehearsing things like “find the man with the monocle and green scarf”)
The VSSP and Visual Imagery

The VSSP plays a role in visual imagery, which is an
important ability in design-focussed careers:

 architecture, engineering, art, etc

Wilson et al. (1999) studied an artist who
developed Visual STM problems. Her sculpting
changed from detailed realistic works to abstract
forms as she struggled visualising objects
 The Central Executive

Baddeley (2007) argued the CE is an attention
system (not memory) with three major functions:

1. Focussing attention on tasks*
2. Dividing attention between tasks
3. Switching attention between two tasks

In terms of Working Memory, it coordinates the
PL and VSSP’s limited resources (see right) The Working Memory Model

*This also includes ignoring distractions
The Central Executive

You are watching sport on tv (focussed attention)
and processing the images with your VSSP/the
commentary with your PL
The phone rings, so you stop focussing on the
match and answer it (task switching), using your
PL to process the conversation

As you talk on the phone, you keep one eye on
the sport (divided attention)
The Episodic Buffer

Baddeley (2007) argued the EB temporarily stores
integrated information from PL, VSSP, and LTM

 It allows allowing ‘chunking’ discussed earlier

Baddeley (2012) felt it stores approx. four chunks
of multidimensional information (i.e., visual,
auditory, and other information combined)
The Working Memory Model
Integration Can Boost Recall

Darling et al (2017) presented digit span digits:

a) One at a time (verbal STM only)
b) On a standard keypad display
c) On a random keyboard display

Recall was best with (B). They felt this occurred as
verbal STM, spatial STM, and LTM (keyboard
knowledge) combined in the EB, boosting memory
 Two Strengths Two Limitations
There is convincing empirical evidence for all Baddeley (2012) acknowledges the model is
components of the model oversimplified, as several kinds of information are
ignored (e.g., STM of smell, touch, and taste)
As Logie (2015, p. 100) noted, the model explains We need more research on the interactions among the
findings “from a very wide range of research topics, for working memory components (e.g., how the EB
example, aspects of children’s language development, integrates information from the PL, VSSP, and LTM)
aspects of counting and mental arithmetic, reasoning
and problem solving, dividing and switching attention,
navigating unfamiliar environments”.
By the end of Short-Term and Working Memory: Part 2, you should be able to

1. Differentiate Short-Term Memory tasks and Working Memory tasks

2. Draw Baddeley and Hitch’s (1974) Working Memory Model, correctly labelling its components

3. Describe each of Working Memory model’s major systems and their functions

4. Explain Working Memory’s is importance in everyday life

5. Explain the strengths and limitations of the Working Memory Model