Personality and Social Psychology Lecture 3: Correlation and Regression PDF

Summary

This lecture covers correlation and regression analysis in personality and social psychology. It explains how to visualize and quantify associations between variables and discusses correlation coefficients and regression analysis. The lecture also touches on the concept of measurement, reliability, and validity.

Full Transcript

Personality and Social
Psychology

Lecture 3:

Correlation and Regression
Overview of my lectures
Introduction to personality (week 2)
What is personality?
History and measurement
Correlation and regression (now)
Analysing data in personality and social psychology
Personality: Development and change
(week 4)
Is our personality stable across the lifespan?
Can we choose to change?
Personality and consequential outcomes
(week 5)
The predictive power of personality
Achievement, health, quality of life, social indicators
Persons and situations (week 6)
The ‘person-situation debate’
Overview for today
Visualising and quantifying associations
(relations between variables)

Correlation coefficients: Spearman and
Pearson

Regression analysis

Measurement, reliability, and validity
 “..the existing evidence broadly suggests that levels
of Agreeableness and Conscientiousness are
positively associated with age whereas levels of
Extraversion and Openness are negatively associated
with age”
Donnellan, M. B., & Lucas, R. E. (2008). Age differences in the big five across the life
span: Evidence from two national samples. Psychology and Aging, 23(3), 558–566.
https://doi.org/10.1037/a0012897

“The relationship between extraversion and
happiness or subjective well-being (SWB) is one
of the most consistently replicated and robust
findings in the SWB literature.”
Pavot, W., Diener, E., & Fujita, F. (1990). Extraversion and happiness. Personality and
Individual Differences, 11(12), 1299-1306. https://doi.org/10.1016/0191-8869(90)90157-M

“Conscientiousness is the most potent
noncognitive predictor of occupational
performance..”
Wilmot, M. P., & Ones, D. S. (2019). A century of research on conscientiousness at work.
Proceedings of the National Academy of Sciences, 116(46), 23004-23010.
https://doi.org/10.1073/pnas.1908430116
Patterns of association
One of the most fundamental questions we
ask in psychology: Is X related to Y?
Are boys more aggressive than girls?
Does our wellbeing rise in the summer and fall
in the winter?
Does extraversion predict leadership skills?
Does anxiety “run in families”?
Do people act a bit “crazy” when there is a full
moon?
Does lecture attendance predict higher
grades?
 Visualising these
patterns: Scatterplots
Plots pairs of X-Y scores:
Y-axis

Y-axis

X-axis X-axis
 Scatterplots

The scatterplot allows you to visualise the association
between X and Y
Correlation
Associations or relations between two variables (X, Y) can be
quantified in terms of a correlation coefficient (r)
Correlation is a form of bivariate analysis
The correlation coefficient quantifies a linear relation in
terms of…
Direction of association
Degree of association

Building block for more sophisticated methods…
Multiple regression, factor analysis, structural equation
modeling, partial correlations
 Direction, Degree, and Form of
Association
Direction
A correlation can be positive or negative
e.g., a baby’s age is positively related to their weight, but
negatively related to the time they spend crawling

Degree
Correlation coefficients (r) range in size from -1
to 1
An r of +1 or -1 is a perfect correlation
An r of zero indicates no association between the
variables

Form
 Direction—positive, negative, or no
relation?
Positive association: increases in X accompanied by
increases in Y
Negative association: increases in X accompanied by
decreases in Y
No relationship: knowing something about X tells you
nothing about Y and vice versa
Y-axis

Y-axis
Y-axis

X-axis X-axis X-axis
Direction—positive, negative, or no
relation?

Positive Negative

Source: Statistics for the Behavioural Sciences, Sixth Edition: Teaching Resources
 Degree—Strong, moderate,
weak?

PERFECT POSITIVE CORRELATION
PERFECT NEGATIVE CORRELATION
r = +1 r = -1
6 6
5 5

Y Values
Y Values

4 4
3 3
2 2
1 1
0
0
0 2
X Values
4 6 0 2 4 6
X Values

Perfect linear relation: every
change in the X variable is
accompanied by a corresponding
change in the Y variable.
 Degree—Strong, moderate,
weak?

r=0 2.50
r=.2 r=.4
2.50 2.50

y20
0.00
y0

y40
0.00

-2.50 -2.50
-2.50
R Sq Linear = 0.002 R Sq Linear = 0.053

R Sq Linear = 0.165

-2.50 0.00 2.50 -2.50 0.00 2.50

x x -2.50 0.00 2.50

x

r=1.0
4.00
r=.6 4.00
r=.8 2.50

2.00 2.00

y100
0.00
y80
y60

-2.00 -2.00

-2.50

-4.00 R Sq Linear = 0.345 R Sq Linear = 1
-4.00 R Sq Linear = 0.659

-2.50 0.00 2.50 -2.50 0.00 2.50 -2.50 0.00 2.50

x x x
 Degree—Strong, moderate,
weak?

A correlation is a measure of effect size

Traditional ‘rules of thumb’ (Cohen, 1988)
Small effect: r ~.10
Medium effect: r ~.30
Large effect: r ~.50

But the research context matters!
In psychology/medicine, only 1/3 of correlations exceed r =.30 (Hemphil,
2003)
In personality/social psychology, the average correlation is r =.21 (Richard
et al. 2003)
Alternative discipline-specific effect size guidelines have been proposed
 Form of the relation
Linear Non-Linear
POSITIVE:
e.g., Ability and
performance
e.g., Happiness
today
and happiness
tomorrow
e.g., arousal e.g., practice and
NEGATIVE: and performance
e.g., Depression and Performance
positive mood

No Relationship
e.g., internet
e.g., length of speed and
sleep and streaming quality
tiredness upon
waking
 Form of the relation
What pairs of variables might have these kinds
of
non-linear associations?
5.00

50.00

0.00

25.00
yquadratic

ycubic
-5.00

0.00

-10.00

R Sq Quadratic =0.779 -25.00
R Sq Cubic =0.637

-15.00

-2.50 0.00 2.50

x -2.50 0.00 2.50

x
 Form of the relation
Correlation measures the linear relation
between two variables.
If there is a nonlinear relation, the
correlation value may be misleading.

 Linear
association is
zero, (r = 0)
 Form of the relation
Correlation measures the linear relation
between two variables.
If there is a nonlinear relation, the
correlation value may be misleading.

Some more examples…
 How would you describe these
correlations?

Direction?
r=-.30
Form? r=.80

Degree?

r=.00
r=-1.00
 Extreme Scores
Juan
Extreme Full Sample r =.31

15
scores or Without Juan, r =.42

Number of “close friends”
Also without Kiki, r =.51
“outliers”
Kiki
can greatly 10
influence the
size of a
5

correlation
0

0 5 10 15 20
Extraversion Score

Check out this simulation to better understand the effect of extreme scores:
http://www.uvm.edu/~dhowell/SeeingStatisticsApplets/PointRemove.html
 Extreme Scores
Original data After adding extreme data point

a) Direction? Positive F
None Linear
b) Form? r =.85
None
c) Degree?
B r = -.08
A

Slide from Statistics for the Behavioural Sciences, Sixth
Edition: Teaching Resources
 Extreme Scores
As the number of observations increases, the influence of
extreme scores on the correlation decreases
In other words, correlations stabilize as sample size (N)
increases
An illustration using simulated correlations:

Schönbrodt & Perugi, 2013
 Calculating the correlation
coefficient (r)
Correlation is a function of two things:

1. Variability: how much a given variable (X) varies
from observation to observation:

2. Covariability: how much two variables (X and Y)
vary together…
 Calculating the correlation
coefficient (r)
Sum of Variability The difference
Squares: between each
observation and
the mean
summed
Obs. Mea together
Sum over all More variability
n
data points = larger sum of
squares

(99-100)2 = 1
+…
(85-100)2 =
225 + …
(124-100)2 =
576 + …
 Calculating the correlation
coefficient (r)
Sum of Variability The difference
Squares: between each
observation and
the mean
summed
Obs. Mea together
Sum over all More variability
n
data points = larger sum of
squares

Sum of Covariability
Products: The difference
between each
observation and
the mean for each
variable multiplied
Sum over allObs. Mea Obs. Mea together.
data points n n
Note that if X = Y,
SP = SS
 Calculating the correlation
coefficient (r)
When SS = SP,
the two terms
cancel out and r
=1

When SP = 0, r
=0
In other words…
r = Covariability of X and Y / Variability of X and Y
separately
 From earlier…

The scatterplot allows you to visualise the association
between X and Y
Calculating the correlation
coefficient (r) Variability

For X = (1-3.66)2 + (1-3.66)2 + (3-3.66)2 … =
31.33
For Y = (1-3.33)2 + (3-3.33)2 + (2-3.33)2 … =
13.33
Covariability

Mean: 3.66 3.33
= (1-3.66) x (1-3.33) + (1-3.66) x (3-3.33) …
=15.66
Correlation

= 15.66 / √(31.33 x 13.33) = 0.76
Calculating the correlation
coefficient (r) Variability

For X = (1-3.66)2 + (1-3.66)2 + (3-3.66)2 … =
31.33
For Y = (1-3.33)2 + (3-3.33)2 + (2-3.33)2 … =
13.33
Covariability

Mean: 3.66 3.33
= (1-3.66) x (1-3.33) + (1-3.66) x (3-3.33) …
=15.66
Correlation

= 15.66 / √(31.33 x 13.33) = 0.76
Calculating the correlation
coefficient (r) Variability

For X = (1-3.66)2 + (1-3.66)2 + (3-3.66)2 … =
31.33
For Y = (1-3.33)2 + (3-3.33)2 + (2-3.33)2 … =
13.33
Covariability

Mean: 3.66 3.33
= (1-3.66) x (1-3.33) + (1-3.66) x (3-3.33) …
=15.66
Correlation

= 15.66 / √(31.33 x 13.33) = 0.76
 Null hypothesis significance
testing
Often our research questions are not framed in terms of
direction, degree, or form. We want a Yes/No
answer…

Examples
1. Is personality associated with age?

2. Is extraversion associated with subjective
well-being?

3. Is conscientiousness associated with occupational
performance?

When can we say “yes”?
 Null hypothesis significance
testing
Suppose we ask “is X correlated with Y?”
1. We first assume the true correlation is 0 (the null
hypothesis)
2. We then determine whether we have evidence that
allows us to reject this assumption (reject the null)

The null hypothesis: H0: ρ = 0.
‘rho’ is the correlation in the population (the ‘true’
correlation)
We then inspect r, the correlation in our sample
Our question then becomes…

“What is the probability of finding an r this big, if the
association in the population (ρ) is zero?”
 Null hypothesis significance
testing
How improbable should the observed r be
under the null, H0, for us to reject the null?
Probability values, or “p values” (p)
p = 1.00: p(H0|r) =1 … we should expect to observe this
r 100% of the time under the null
p = 0.50: p(H0|r) =.5 … 50% of the time…
p = 0.05: … 5% of the time

p <.05: The threshold (“alpha level”) at which we usually
reject the null

If we reject the null, we say the correlation is
“significant” — r is significantly different
 Null hypothesis significance
testing
Why p <.05? Why not p <.01 or p <.10?

Arbitrary! Just a “rule of thumb” (like Cohen’s effect
size guidelines)

p <.05 represents the frequency of times we would
be comfortable being wrong in concluding that
there was an association – i.e., five times out of 100.

Some have argued for a more strict default alpha
level of
p <.005! (see Benjamin et al., 2018, Nature Human
Behavior)
 Null hypothesis significance
testing
Note that the size of our obtained p value will depend
on the size of the sample, N.
More precisely, it is a function of the degrees of
freedom df.
For correlation df = N – 2.
SIGNIFICANT p VALUE
df.10.05.02.01
 Null hypothesis significance
testing
Note that the size of our obtained p value will depend
on the size of the sample, N.
More precisely, it is a function of the degrees of
freedom df.
For correlation df = N – 2.
SIGNIFICANT p VALUE
df.10.05.02.01
 Null hypothesis significance
testing
Note that the size of our obtained p value will depend
on the size of the sample, N.
More precisely, it is a function of the degrees of
freedom df.
For correlation df = N – 2.
With 2 degrees of
SIGNIFICANT p VALUE freedom a
df.10.05.02.01 correlation needs
to be ≥.95 to be
significant

With df = 5 ,
≥.75

With df = 40,
≥.30
Why does significance
depend on sample size?
Remember Schönbrodt & Perugi, 2013?
Correlation estimates stabilise as sample size
increases.
i.e., at smaller samples, it is more likely for large
correlations to emerge purely by chance

An illustration…
Suppose Kiki correctly guesses 75% of coin
flips… can we conclude she has ESP?
🤨
What if it was 75% of four coin flips?

🤯
What if it was 75% of 200 coin flips?
 Example output from JASP
Can we confirm that age is
significantly positively associated
with conscientiousness and
agreeableness?

N = 980 adults assessed on the Big
Five…

data from https://osf.io/9wf2s/. Correlations are small (A) to average (C)…
 Example output from JASP
Can we confirm that age is
significantly positively associated
with conscientiousness and
agreeableness?

N = 980 adults assessed on the Big
Five…

data from https://osf.io/9wf2s/. … and p <.05, so they are significant
Example correlation matrix

Various Their means These are And their
trait and standard measure of correlations with
measures deviations reliability each other

(SD is a (We’ll come
measure of to that later!)
variability) Table from Wilt et al., 202
Spearman’s Correlation
So far we have examined the correlation
coefficient proposed by Karl Pearson —
“Pearson’s r”

An alternative is that proposed by Charles
Spearman — “Spearman’s rho”:
Karl Pearson
Data converted to ranks before calculating
correlations
e.g., lowest value is scored 1, next lowest value is
scored 2, etc. all the way up to the highest
Outliers: a sequence of data such as 15, 20, 2532
would be recoded as 1, 2, 3 – the outlier is only one
rank from the next data point

Provides a solution for non-linear data and
dealing with outliers…
Charles Spearman
Spearman’s Correlation
Non-linear
data…

Converting
to ranks
can
linearise
non-linear
data!

r rs
Spearman’s Correlation
Outliers…

Outlier is
just *one
rank*
above
the next
highest
value

r r
Example using JASP
Research question
Do anxious people tend to be less satisfied with their
work?

Operationalised RQ:
Is the anxiety facet of Big Five neuroticism (significantly)
negatively correlated with self-reported job satisfaction

The data:
Sample of managers (n = 28)
Important: This sample is REALLY SMALL and we could
never trust the results in reality!
Participants complete scales to measure job satisfaction
and anxiety (100-point scale)
 Example using JASP

How to report:
“There was a significant negative correlation between
satisfaction and anxiety, r(26) = –.581, p =.001.”

[Remember, df for correlaton = N – 2]
Correlation versus causation
Correlation is not evidence of
causation!
A significant correlation does not mean
that one variable causes the other

e.g., Neuroticism is negatively correlated
with job satisfaction
Perhaps low job satisfaction increases
neuroticism
Perhaps low neuroticism increases job
satisfaction
Perhaps a third variable is responsible for
both: work stress, problems at home,
From Correlation to
Regression…
Correlations quantify patterns of association— r
(and rho) describe a bivariate association
between X and Y

Regression involves prediction—e.g., based
on values of X, can I predict values of Y?

If two variables are correlated, we can base our
prediction on that correlation…
From Correlation to
Regression…
Pay-as-you go phone plan:
$30 per month subscription, plus 20c cents
per call.
 Monthly bill = 30 + 0.20  (no of calls)

A perfect correlation: we can predict the
exact bill for any number of calls
The general form of a perfect linear relationship:
Y=a+bX
From Correlation to
Regression…
A less than perfect
linear relation –

Subjective Well-being
extraversion and
subjective well-being:

What is the best linear
relationship of the form
Y=a+bX
for this data?

i.e., what is the line of Extraversion
best fit?
From Correlation to
Regression…
Line of best fit
(regression line):

Subjective Well-being
SWB = 0.65
+.65xExtra

But prediction will not be
exact—there will be
error

SWB = 0.65
+.65xExtra + e Extraversion
From Correlation to
Regression…

Sometimes Y will
Subjective Well-being

be perfectly
predicted

Sometimes not!

Extraversion These are our
errors of
prediction, or
residuals
 The Regression Model
e general form of a perfect linear relationship:
Criterion = Intercep + Slope × Predictor
variable t Variable

Y=a+bX
Does anxiety predict job satisfaction?
What is the best linear
relationship of the form Y = a +
b X for this data?

What is the line of best fit that
serves to model Y based on X?

 Satisfaction = 108 -.941 x
The Regression Model
The actual data:
Criterion = Intercep + Slope × Predictor + Erro
variable t Variable r

Y=a+bX+
e
Data in the population is dispersed randomly around this
population regression line, where…

a is the intercept parameter (sometimes called the constant)

b is the slope parameter (sometimes called the constant)

e is an error or residual term.

Errors are assumed to be:
– Independent
– Normally distributed (with a mean of zero)
– Homoscedastic
» Equal error variance for levels of predicted Y
The least squares parameter
estimates
Observed Predicted (prediction
Y Score from
Y Score
regression
(actual data) line)
(88 –
56)2
= 322
Estimate = 1024

parameters by (73 – 40)2
2
minimising the total = 33

squared error: = 1089

(45 –
regression 71)
coefficients =-262
=676
 Satisfaction and Anxiety
Mean Anxiety: 73
Hand calculations: Mean Satisfaction: 39
SS Anxiety: 6,040
Remember: 2

SS X  ( X  X ) 
2 2
X
  X SP: -5,685

SP  ( X  n
X )(Y  Y )

 XY 
 X Y
n

SP 𝑏=− 5686 =−.940
b=
SS X 6040

SP
b 
SS X
a Y  bX

=107.62
 JASP output:
Regression
coefficients:
a = 107.91
Note: Small differences between hand calculations and JASP Output is
due to rounding
b = -.941
Intercept,
aka Slope, aka
a b
Constant Rise (-18.83)
Y-intercept over Run (20)
Predicted = slope
value of Y (-.941)
Effect on Y for
when X is
0 a unit (1)
increase on
predictor
 Regression Diagnostics
Remember assumptions from earlier…

1. Independence of residuals—usually assumed based
on independence of observations
2. Normality of residuals—can assess by inspecting a
histogram of residuals

Predicted is Predicted is
greater than less than
observed; observed;
thus thus positive
negative residual
residual

Residual =
0: no error
 Regression Diagnostics
3. Residuals are homoscedastic—a scatterplot of
residuals against predicted values us used to check for
heteroscedasticity.
 Absence of any systematic pattern supports the
assumption of homoscedasticity
Homoscedasticity: vs heteroscedasticity:
 Variance explained (R2)
When there is a perfect correlation, all Y scores
fall exactly on the regression line.
Phone bill example:
The variation in my pay-as- Y = 30 +.20X
you-go phone bill is
completely explained by
the number of calls I make.

Proportion of variance
explained = 100%
R2 = 1.00
 Variance explained (R2)
But in our other example, not all variation in job
satisfaction can be explained by anxiety
Job satisfaction
The Y scores (job example:
satisfaction) do tend to
follow the regression line..
Y = 108
…but the Y scores also
-.914xAnxiety
vary around the regression
line.

Proportion of variance
explained = 33.7%
R2 = 0.337
 Null Hypothesis Significance
Testing (for the regression model)
Does the regression model help to explain the variance in
Y?
Can we reject the null hypothesis (H0): R2 = 0
This can be tested using an “Analysis of Variance” or
ANOVA:

JASP output:

The F test is our test statistic for regression
Because our p value <.05 we can reject the null
Thus, the proportion of variance explained by the
regression model is significantly different from zero.
 Null Hypothesis Significance
Testing (for regression
parameters)
Regression parameters
Intercept, a: estimated value of Y when X = zero

Slope, b: indicates:
the strength of association between X and Y
the direction of that association (positive or negative, cf
correlation)
estimated change in Y when X increases by 1

Slope can be translated into standardised form
standardised regression coefficient (called beta in SPSS or
JASP.)
compare with correlation coefficient for bivariate data
Can also have confidence intervals for regression coefficients
 Null Hypothesis Significance
Testing (for regression
parameters)
Does the slope parameter, b, help us to predict the
dependent variable Y?
i.e. is the slope non-zero? (H0: b = 0)
Can use a t-test to examine this null hypothesis (the t-
test and F test are closely related!)
If p <.05, reject the null hypothesis.
 Example using JASP
Research Question(s):
Are people who experience more positive
moods happier? (correlation)
Can we predict happiness from positive mood?
(regression)
Or, can we model happiness based on positive
mood?
 Example using JASP
Happiness

Positive Mood
Example using JASP
Example using JASP
Example using JASP

R-squared: Variance
explained by the model

The model (% var
explained) is
significant

Regression p