Different forms of validity and why they matter Week 8, Psych 350 – R. Chris Fraley.
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Transcript of Different forms of validity and why they matter Week 8, Psych 350 – R. Chris Fraley.
Different forms of validity and why they matter
Week 8, Psych 350 – R. Chris Fraley
Validity
• In our last class, we began to discuss some of the ways in which we can assess the quality of our measurements.
• We discussed the concept of reliability (i.e., the degree to which measurements are free of random error).
Why reliability alone is not enough
• Understanding the degree to which measurements are reliable, however, is not sufficient for evaluating their quality.
• Recall that test-retest estimates of reliability tend to range between 0 (low) and 1(high).
• Nice online correlation calculator: • https://www.easycalculation.com/statistics/
correlation.php
Validity
• In this example, the measurements appear reliable, but there is a problem.
• Validity reflects the degree to which measurements are free of both random error, E, and systematic error, S.
• O = T + E + S• Systematic errors reflects the influence of
any non-random factor beyond what we are attempting to measure.
Validity: Does systematic error accumulate?
• Question: If we create a composite of multiple observations, how will systematic errors influence our estimates of the “true” score?
Validity: Does error accumulate?
• Answer: Unlike random errors, systematic errors accumulate.
• Systematic errors exert a constant source of influence on measurements. We will always overestimate (or underestimate) T if systematic error is present.
Person O T E S
A 12 10 0 +2
B 12 10 0 +2
C 12 10 0 +2
D 12 10 0 +2
E 12 10 0 +2
F 12 10 0 +2
G 12 10 0 +2
Average 12 10 0 +2
Note: Each measurement is 2 points higher than the True value of 10. The systematic errors do not average out.
Person O T E S
A 12 10 0 +2
B 11 10 -1 +2
C 12 10 0 +2
D 13 10 +1 +2
E 10 10 -2 +2
F 12 10 0 +2
G 14 10 +1 +2
Average 12 10 0 +2
Note: Even when random error is present, E average to 0 but S does not. Thus we have reliable measurements that have validity problems.
Validity: Ensuring validity
• What can we do to minimize the impact of systematic errors?
• One way to do so is to use a variety of indicators—different sources of information.
• Different kinds of indicators of a latent variable may not share the same systematic errors.
• If true, then S will behave like random error across measurements (but not within measurements).
Example
• As an example, let’s consider the measurement of self-esteem.
• Some methods, such as self-report questionnaires, may lead people to over-estimate their self-esteem. Most people want to think highly of themselves.
• Other methods, such as clinical ratings by trained observers, may lead to under-estimates of self-esteem. Clinicians, for example, may not be prone to assume that people are not as well-off as they say they are.
O T E S
Self-reports
item 1 13 10 +1 +2
item 2 12 10 0 +2
item 3 12 10 0 +2
item 4 11 10 -1 +2
Clinical ratings
rating 1 10 10 +2 -2
rating 2 8 10 0 -2
rating 3 8 10 0 -2
rating 4 6 10 -2 -2
Average 10 10 0 0
Another Example
• One problem with the use of self-report questionnaire rating scales is that some people tend to give consistently high (or low) answers, regardless of the question being asked.
• This is sometimes referred to as a yay-saying or nay-saying bias. Acquiescence.
Item T S O
I think I am a worthwhile person.
4 +1 5
I have high self-esteem. 4 +1 5
I am confident in my ability to meet challenges in life.
4 +1 5
My friends and family value me as a person.
4 +1 5
Average 4 +1 5
1 = strongly disagree and 5 = strongly agreeIn this example we have someone with relatively high self-esteem, but this person systematically rates questions 1 point higher than he or she should.
Item T S O
I think I am a worthwhile person.
4 +1 5
I have high self-esteem. 4 +1 5
I am NOT confident in my ability to meet challenges in life.
2 +1 3
My friends and family DO NOT value me as a person.
2 +1 3
Average 4 +1 4
If we reverse key half the items, the bias averages out. Responses to reverse keyed items are counted in the opposite direction.
Validity
• To the extent to which a measure has validity, we say that it measures what it is supposed to measure.
• Big question: How do we assess validity?
Different ways to think about validity
• To the extent that a measure has validity, we can say that it measures what it is supposed to measure.
• There are different reasons for measuring psychological variables. The previse way in which we assess validity depends on the reason that we are taking the measurements in the first place.
Prediction
• As an example, if one’s goal is to develop a way to determine who is at risk for developing schizophrenia, one’s goal is prediction.
Predictive Validity
• We may begin by obtaining a group of people who have schizophrenia and a group of people who do not.
• Then we may try to figure out which kinds of antecedent variables differentiate the two groups.
Correct Classifications
Lost a parent before the age of 10 10%
Parent or grandparent had schizophrenia
50%
Mother was cold and aloof to the person when he or she was a child.
15%
Predictive Validity
• In short, some of these variables appear to be better than others at discriminating schizophrenics from non-schizophrenics.
• The degree to which a measure can predict what it is supposed to predict is called its predictive validity.
• When we are taking measurements for the purpose of prediction, we can assess validity as the degree to which those predictions are accurate (i.e., useful).
• Baserate problem
Yes
No
Yes 40
10
Reality: Schizophrenic
Mea
sure
: Sch
izop
hren
icNo
10
40
80% ( [40 + 40] / 100) people were correctly classified (50% base rate)
YesNo
No
Yes 40
10
Reality: Schizophrenic
Mea
sure
: Sch
izop
hren
ic
40
10
50% ( [40 + 10] / 100) people were correctly classified (with a 50% base rate. Yuck.)
YesNo
No
Yes 1
0
Reality: Schizophrenic
Mea
sure
: Sch
izop
hren
ic
1
98
99% ( [98 + 1] / 100) people were correctly classified, but note the base rate problem. Cohen’s kappa is used to account for this problem. Kappa in this example is 66%
Construct Validity
• Sometimes we’re not interested in measuring something just for “technological” purposes, such as prediction.
• We may be interested in measuring a construct in order to learn more about it– Example: We may be interested in measuring self-
esteem not because we want to predict something with the measure per se, but because we want to know how self-esteem develops, whether it develops differently for males and females, etc.
Construct Validity
• Notice that this is much different than what we were discussing before. In our schizophrenia example, it doesn’t matter whether our measure of schizophrenia really measured schizophrenic tendencies per se.
• As long as the measure helps us predict schizophrenia well, we don’t really care what it measures or how that is accomplished.
Construct Validity
• When we are interested in the theoretical construct per se, however, the issue of exactly what is being measured becomes much more important.
• The general strategy for assessing construct validity involves (a) explicating the theoretical relations among relevant variables and (b) examining the degree to which the measure of the construct relates to things that it should and fails to relate to things that it should not.
Nomological Network
• The nomological network represents the interrelations among variables involving the construct of interest.
self-esteem
achieve in school
distrust friends
ability to cope
-
++
Nomological Network & Validity
• The process of assessing construct validity basically involves determining the degree to which our measure of the construct behaves in the way assumed by the theoretical network in which it is embedded.
• If, theoretically, people with high self-esteem should be more likely to succeed in school, then our measure of self-esteem should be able to predict people’s grades in school.
Construct Validity
• Notice here that establishing construct validity involves prediction. The difference between prediction in this context and prediction in the previous context is that we are no longer trying to predict school performance as best as we possibly can.
• Our measure of self-esteem should only predict performance to the degree to which we would expect these two variables to be related theoretically.
Discriminant Validity
• The measure should also fail to be related to variables that, theoretically, are unrelated to self-esteem.
• The ability of a measure to fail to predict irrelevant variables is referred to as the measure’s discriminant validity.
self-esteem
achieve in school
distrust friends
ability to cope
-
++
like coffee
0
Validity: Assessing validity
• Finally, it is useful, but not necessary, for a measure to have face validity.
• Face validity: The degree to which a measure appears to measuring what it is supposed to measure.
• A questionnaire item designed to measure self-esteem that reads “I have high self-esteem” has face validity. An item that reads “I like cabbage in my Frosted Flakes” does not.
• In the context of prediction, face validity doesn’t matter. In the context of construct validity, it matters more.
A Final Note on Construct Validity
• The process of establishing construct validity is one of the primary enterprises of psychological research.
• When we are measuring the association between two variables to assess a measure’s predictive or discriminant validity, we are evaluating both (a) the quality of the measure and (b) the soundness of the nomological network.
• It is not unusual for researchers to refine the nomological network as they learn more about how various measures are inter-related.