Week 1: Types of Outcomes + NHST

Question 1

Process of hypothesis testing (6)

Answer 1

1. We have a question or hypothesis about a population
2. Propose a study to gather data
3. The design of the study aims to optimise it to gain the most valuable information about the hypothesis
4. Collect data
5. Use statistics to test the hypothesis base on a model of the data (informed by hypothesis)
6. Examine and interpret the results.

Question 2

There are constraints of getting valuable info for hypothesis from study’s design such as - (2)

Answer 2

duration of the study
how many people you can recruit

Question 3

What is a sample?

Answer 3

A sample is the specific group that you will collect data from.

Question 4

What is a population?

Answer 4

A population is the entire group that you want to draw conclusions about.

Question 5

Example of population vs sample (2)

Answer 5

Population : Advertisements for IT jobs in the UK
Sample: The top 50 search results for advertisements for IT jobs in the UK on 1 May 2020

Question 6

What does the arrows show in process of hypothesis testing? (2)

Answer 6

show the iterative nature of hypothesis testing,

the question or design to answer the question can be updated on the basis of the statistical analysis from only study so a future study can be devised.

Question 7

The decision tree above guides you to the appropriate

Answer 7

inferential statistics (statistical approach) to use

Question 8

What is inferential statistics?

Answer 8

Inferential statistics allow you to test a hypothesis or assess whether your data is generalisable to the broader population.

Question 9

What we have measured is called the (2)

Answer 9

outcome variable/
DV variable

Question 10

The outcome variables influences what

Answer 10

statistical test to use on data you have gathered

Question 11

Why is there a focus to do parametric tests than others in research? - (3)

Answer 11

• they are more rigorous, powerful and sensitive than non-parametric tests to answer your question
• This means that they have a higher chance of detecting a true effect or difference if it exists.
• They also allow you to make generalizations and predictions about the population based on the sample data.

Question 12

What question has been covered?

Answer 12

Question 13

We measure the answers to our question (hypothesis) which

Answer 13

informs on our question (hypothesis)

Question 14

We can obtain multiple outcomes from the

Answer 14

same people

Question 15

We can obtain outcomes under

Answer 15

different conditions, groups or both

Question 16

We specificy what we measure and under what condition we measure them in the

Answer 16

design of the experiment or study

Question 17

What are the 4 types of outcomes we measure? (4)

Answer 17

1. Ratio
2. Interval
3. Ordinal
4. Nominal

Question 18

What is a continous variables? - (2)

Answer 18

: there is an infinite number of possible values these variables can take on-

entities get a distinct score

Question 19

2 examples of continous variables (2)

Answer 19

• Interval
• Ratio

Question 20

What is an interval variable?

Answer 20

: Equal intervals on the variable represent equal differences in the property being measured

Question 21

Examples of interval variables - (2)

Answer 21

e.g. the difference between 600ms and 800ms is equivalent to the difference between 1300ms and 1500ms. (reaction time)

temperature (Farenheit), temperature (Celcius), pH, SAT score (200-800), credit score (300-850)

Question 22

What is ratio variable?

Answer 22

The same as an interval variable and also has a clear definition of 0.0.

Question 23

Examples of ratio variable - (3)

Answer 23

E.g. Participant height or weight
(can have 0 height or weight)

temp in Kelvin (0.0 Kelvin really does mean “no heat”)

dose amount, reaction rate, flow rate, concentration,

Question 24

What is a categorical variable? (2)

Answer 24

A variable that cannot take on all values within the limits of the variable

• • entities are divided into distinct categories

Question 25

What are 2 examples of categorical variables? (2)

Answer 25

• Nominal
• Ordinal

Question 26

What is nominal variable? - (2)

Answer 26

a variable with categories that do not have a natural order or ranking

Has two or more categories

Question 27

Examples of nominal variable - (2)

Answer 27

genotype, blood type, zip code, gender, race, eye color, political party

e.g. whether someone is an omnivore, vegetarian, vegan, or fruitarian.

Question 28

What is ordinal variables?

Answer 28

categories have a logical, incremental order

Question 29

Examples of ordinal variables - (3)

Answer 29

e.g. whether people got a fail, a pass, a merit or a distinction in their exam

socio economic status (“low income”,”middle income”,”high income”),

satisfaction rating [Likert Scale] (“extremely dislike”, “dislike”, “neutral”, “like”, “extremely like”).

Question 30

Using the term ‘variables’ for continous and categorical variables as - (2)

Answer 30

both outcome and predictor are variables

We will see later on that not only the type of outcome but also type of predictor influences our choice of stats test

Question 31

Likert scale is ordinal variable but sometimes outcomes measured on likert scale are treated as - (3)

Answer 31

continuous after inspection of the distribution of the data and may argue the divisons on scale are equal

(i.e., treated as interval if distribution is normal)

gives greater sensitivity in parametric tests

Question 32

What is measurement error?

Answer 32

The discrepancy between the actual value we’re trying to measure, and the number we use to represent that value.

Question 33

Example of measurement error in psych experiments - (2)

Answer 33

Imprecise measurement: Not accurate to use a stopwatch to measure reaction times that are about 1/2 second

Systematic problem: broken ruler (affects validity)

Question 34

In reducing measurement error in outcomes, the

Answer 34

values have to have the same meaning over time and across situations

Question 35

Validity means that the (2)

Answer 35

instrument measures what it set out to measure

refers to the accuracy of a measure (whether the results really do represent what they are supposed to measure

Question 36

Reliability means the

Answer 36

ability of the measure to produce the same results under the same conditions

Question 37

Test-retest reliability is the ability of a

Answer 37

measure to produce consistent results when the same entities are tested at two different points in time

Question 38

3 types of variation (3)

Answer 38

• Systematic variation
• Unsystematic variation
• Rnadomisation

Question 39

What is systematic variation - (2)

Answer 39

Differences in performance created by a specific experimental manipulation.

This is what we want

Question 40

What is Unsystematic variation (3)

Answer 40

Differences in performance created by unknown factors
.
Age, Gender,** IQ, **Time of day, Measurement error etc.

These differences can be controleld of course (e.g., inclusion/exclusion of pps setting age range of 18-25)

Question 41

Randomisation (other approaches) minimises - (2)

Answer 41

effects of unsystematic variation

does not remove unsystematic variation

Question 42

What is the independent variable (Factors)? ( 3)

Answer 42

• The hypothesised cause
• A predictor variable
• A manipulated variable (in experiments)

Question 43

What is depenedent variable? (measures)- (3)

Answer 43

• The proposed effect , change in DV
• An outcome variable
• Measured not manipulated (in experiments)

Question 44

In all experiments we have two hypotheses which is (2)

Answer 44

• Null hypothesis
• Alternative hypothesis

Question 45

What is null hypothesis?

Answer 45

that there is no effect of the predictor variable on the outcome variable

Question 46

What is alternative hypothesis?

Answer 46

is that this is an effect of the predictor variable on the outcome variable

Question 47

Null Hypothesis Signifiance Testing computes the probability the (2)

Answer 47

the probability of the null hypothesis being true (referred as p-value) by computing a statistic and how likely it is that the statistic has that value by chance alone

Referred as p-value

Question 48

The NHST does not compute the probability of the

Answer 48

null hypothesis

Question 49

Null Hypothesis Signifiance Testing Example Z Curve - (9)

Answer 49

• From experiment we have z statistic that is calculated from 2 groups
• Shows normal distribution in this case of z statistic
• The horizontal axis measures how many standard deviations from the mean
• the vertical axis measures the probability of density of z
• On left, mean of grp1 < mean of grp 2
• On right, mean of grp > mean of grp 2
• If two-tailed test/non-directional then spilt probability on two ends of the tail –> more extreme value of statistic for sig
• If directional hypothesis then not spilt alpha value –> leway along x axis and get lower value and still p 0.05

Question 50

There can be directional and non-directional hypothesis of

Answer 50

an alternate hypothesis

Question 51

non-directional alternate hypothesis is..

Answer 51

The alternative hypothesis is that this is an effect of the group on the outcome variable

Question 52

Directional alternate hypothesis is…

Answer 52

The alternative hypothesis is that this the mean of the outcome variable for group 1 is larger than the mean of group 2

Question 53

Example of directional alternate hypothesis

Answer 53

There would be far greater engagment in stats lecture if they were held at 4 PM and not 9AM

Question 54

For a non-directional hypothesis you will need to divide your alpha value at

Answer 54

two ends of the tail of normal distirbution

Question 55

The 3 misconceptions of Null Hypothesis Signifiance Testing (NHST) - (3)

Answer 55

1. A significant result means the effect is important
2. A non-significant result means the null hypothesis is true
3. A significant result means the null hypothesis is false (just give probability that data occured given null hypothesis, doesn’t say huge evidence that null hypothesis is categorically false)

Question 56

P-Hacking and HARKING is another issue with

Answer 56

NHST

Question 57

p-Hacking and HARKINGS are the - (2)

Answer 57

researchers degrees of freedom

cchange after results are in and some analysis has been done

Question 58

P-hacking refers to a

Answer 58

selective reporting of significant results

Question 59

Harking is

Answer 59

Hypothesising After the Results are Known

Question 60

P-hacking and HARKING are often used in

Answer 60

combination

Question 61

What does EMBERS stand for? (5)

Answer 61

1. Effect Sizes
2. Meta-analysis
3. Bayesian Estimation
4. Registration
5. Sense

Question 62

EMBERS can reduce issues of

Answer 62

NHST

Question 63

Uses of Effect sizes and Types of Effect Size (3)

Answer 63

• There a quite a few measures of effect size
• Get used to using them and understanding how studies can be compared on the basis of effect size
• A brief example: Cohen’s d

Question 64

Meaning of Effect Size (2)

Answer 64

Effect size is a quantitative measure of the magnitude of the experimental effect.

The larger the effect size the stronger the relationship between two variables.

Question 65

Formula of Cohen’s d

Answer 65

Question 66

What is meta-analysis?

Answer 66

Meta-analysis is a study design used to systematically assess previous research studies to derive conclusions about that body of research

Question 67

Meta-analysis brings together.. and assesses (2)

Answer 67

• Bringing together multiple studies to get a more realistic idea of the effect
• Can assess effect siz that are averaged across studies

Question 68

Funnel plots in meta-analysis can be made to….. values stuides…. (2)

Answer 68

investigating publication bias and other bias in meta-analysis

values studies by their sample size and observe bias

Question 69

Bayesian approaches capture

Answer 69

probabilities of the data given the hypothesis and null hypothesis

Question 70

Bayes factor is now often computed and stated alongside

Answer 70

conventional NHST analysis (and effect sizes)

Question 71

Registration is where (5)

Answer 71

• Telling people what you are doing before you do it
• Tell people how you intend to analyze the data
• Largely limits researcher degrees of freedom (HARKING p-hacking)
• A peer reviewed registered study can be published whatever the outcome
• The scientific record is therefore less biased to positive findings

Question 72

Sense is where (4)

Answer 72

• Knowing what you have done in the context of NHST
• Knowing misconceptions of NHST
• Understanding the outcomes
• Adopting measures to reduce researcher degrees of freedom (like preregistration etc..)

Question 73

most of the statistical tests in this book rely on
having data measured

Answer 73

at interval level

Question 74

To say that data are interval, we must be certain that
equal intervals on the scale represent

Answer 74

equal differences in the property being measured.

Question 75

To say that data are interval, we must be certain that
equal intervals on the scale represent equal differences in the property being measured. For
example, , on www.ratemyprofessors.com students are encouraged to rate their lecturers on
several dimensions (some of the lecturers’ rebuttals of their negative evaluations are worth
a look). Each dimension (i.e. helpfulness, clarity, etc.) is evaluated using a 5-point scale.

For this scale to be interval it must be the case that the - (2)

Answer 75

difference between helpfulness ratings of 1 and 2 is the same as the difference between say 3 and 4, or 4 and 5.

Similarly, the
difference in helpfulness between ratings of 1 and 3 should be identical to the difference
between ratings of 3 and 5. V

Question 76

The distinction between continous and discrete variables can often be blurred - 2 examples- (2)

Answer 76

continuous variables can be measured in discrete terms; we measure age we rarely use nanoseconds but use years (or possibly years and months).
In doing so we turn a continuous variable into a discrete
one

treat discrete variables as if they were continuous, e.g., the number of boyfriends/girlfriends
that you have had is a discrete variable. However, you might read a magazine that says ‘the average number of boyfriends that women in their 20s have has increased from 4.6 to 8.9’

Question 77

a device for measuring sperm motility that actually measures sperm count is not

Answer 77

valid

Question 78

Criterion validity is whether the

Answer 78

instrument is measuring what it claims to measure (does
your lecturers’ helpfulness rating scale actually measure lecturers’ helpfulness?).

Question 79

The two sources of variation that is always present in independent and repeated measures design is

Answer 79

unsystematic variation and systematic variation

Question 80

effect of our experimental manipulation
is likely to be more apparent in a repeated-measures design than in a

Answer 80

between-group design,

Question 81

effect of experimental manipulation is more apparent in repeated-design than independent since in independent design,

Answer 81

differences between the characteristics of the people allocated to each of the groups is likely to create considerable random variation both within
each condition and between them

Question 82

This means that, other things being equal, repeated-measures designs have
more power to

Answer 82

, repeated-measures designs have
more power to d

Question 83

We can use randomization in two different ways depending on
whether we have an

Answer 83

independent and repeated design measure

Question 84

Two sources of systematic variation in repeated design measure - (2)

Answer 84

• Practice effects
• Boredom effects

Question 85

What is practice effects?

Answer 85

Participants may perform differently in the second condition because
of familiarity with the experimental situation and/or the measures being used.

Question 86

What is boredom effects?

Answer 86

: Participants may perform differently in the second condition because
they are tired or bored from having completed the first condition.

Question 87

We can ensure no systematic variation between conditions in repeated measure is produced by practice and boredom effects by

Answer 87

counterbalancing the order in which a person participates in a condition

Question 88

Example of counterbalancing

Answer 88

we randomly determine whether a participant
completes condition 1 before condition 2, or condition 2 before condition 1

Question 89

To reduce unsystematic variation in independent design (between subject) , we can ensure - (2)

Answer 89

that confounding variables are unlikely to
contribute systematically to the variation between experimental conditions is to randomly allocate participants to a particular experimental condition.

This should ensure that these
confounding variables are evenly distributed across conditions.