Analysis & Presentation of Quantitative Data PDF

Summary

This document provides an analysis and presentation of quantitative data, with learning objectives and detailed explanations of different statistical methods. The document covers topics like descriptive and inferential statistics, frequency distributions, and measures of central tendency. It includes various examples and includes information on different measurement scales like Likert and graphic rating scales.

Full Transcript

ANALYSIS & PRESENTATION
OF QUANTITATIVE DATA
PREPARED BY:
YVETTE M. BATAR, RN, MAN,DM

Sources:
Polit, E. & Beck C., Essentials of Nursing Research, 10th Edition 2022.
Tan, Crestita B., A Research Guide in Nursing Education: Building an Evidence-based Practice, 4th Edition 2006.
 LEARNING OBJECTIVES
ON COMPLETING THIS C HAPTER, S TUDENT NURSES WILL BE ABLE TO:

Describe the characteristics of Specify the appropriate applications for t-
frequency distributions, and identify tests, analysis of variance, chi-squared
and interpret various descriptive tests, and correlation coefficients and
statistics. interpret the meaning of the calculated
statistics.
Describe the logic and purpose of
Describe the applications and principles of
parameter estimation, and interpret
multiple regression and analysis of
confidence intervals.
covariance.

Describe the logic and purpose of tests Understand the results of simple statistical
of statistical significance, describe procedures described in a research report.
hypothesis testing procedures, and
interpret p values. Define new terms in the chapter
 4 MAIN PURPOSES OF 4 MAJOR LEVELS OF
STATISTICAL ANALYSIS MEASUREMENTS
1. Nominal Measurement - the lowest level,
1.To describe data. involves using numbers to categorize
attributes.
2.To estimate population
2. Ordinal Measurement - ranks people on an
values.
attribute.

3.To test hypothesis. 3. Interval Measurement - occurs when
researchers can rank people on an attribute
4.To provide evidence & specify the distance between them.
regarding measurement
4. Ratio Measurement - the highest level,
properties of quantified have a meaningful zero & provide
variables. information about the magnitude of the
attribute.
 TYPES OF ORDINAL MEASUREMENT OR SCALE
1. Likert Scale 2. Graphic Rating Scale
Respondents are asked to Respondents are asked to
indicate the degree to which respond a bipolar continuum
they agree or disagree with such as from “highest” to
the ideas expressed by the “lowest” or “most” to “least”.
indicator. A simple line on which one
Used to assess the attitude marks an X anywhere
of respondents towards the between the extremes with an
variables being investigated. infinite number of places
where the X can be placed.
 TYPES OF ORDINAL MEASUREMENT OR SCALE

3. Guttman Scale 4. Semantic Differential
Used to assess the attitudes Scale
of respondents, using a Use to measure the meaning
continuum of cumulative of concepts to determine the
statements. emotional-evaluative
component of the
respondent’s attitude.
 STATISTICS
A branch of Mathematics used to summarize, organize, present, analyze
and interpret numerical data such as the numerical characteristics of
sample parameters and the numerical characteristics of a population.

DESCRIPTIVE STATISTICS INFERENTIAL STATISTICS
Used to analyze & describe Is concerned with
data & relationships between population and the use of
2 variables.
sample data to predict
Refers to statistics intended to future occurrences.
organize and summarize
numerical data from the
population and sample.
 USES OF DESCRIPTIVE STATISTICS
A. Measures & condenses data in:

Frequency Distribution –
arrangement of values from lowest to
highest & a count or percentage of
how many times each value occurred. Frequency Polygon

Graphic Presentation – data are
presented in graphic form to make
frequency distribution data readily
apparent.

B. Measures of central tendency –
used to describe the the 3 indexes:
Mean, Median and Mode.
 USES OF DESCRIPTIVE STATISTICS
3 INDEXES OF CENTRAL TENDENCY
Mode: the number that occurs most Mean Formula
frequently in a distribution. In the
following distribution, the mode is 53:
X = ∑ (wm)
N
50 51 51 52 53 53 53 53 54 55 56 Where: ∑ (w m) = sum of the
weighted means per item within a
Median: the point in a distribution that
given criterion
divides scores in half.
N = number of items
Mean: is equal to the sum of all values
divided by the number of participants—
what people refer to as the average.
 VARIABILITY OR MEASURE OF DISPERSION
Describes how far apart data points lie from each other and from the
center of a distribution, w/ 2 common indexes: Range & Standard
Deviation.
RAN GE STANDARD DEVIATION (SD)

Simplest measure of dispersion. Represents the average of
deviations from the mean.
Obtain by subtracting the lowest
score from the highest score. Mean tell us the best value for
summarizing an entire
Range is a difference score, w/c distribution.
uses only 2 extreme scores for
SD tells us how much the score
the comparison.
deviate from the mean & can be
interpreted as degree of error.
 VARIABILITY OR MEASURE OF DISPERSION
STANDARD DEVIATION (SD) - C ONT’D

Determines the homogeneity Most widely used.
or sameness of degree or Calculated based on every
dimension of given variables
value in the distribution.
or the heterogeneity or
Summarizes the average
degree of dispersal of
variance of variables. amount of deviation of values
Formula: S ∑ (X-X)2 from the mean.
n-1
Interpreted as degree of error
Where: ∑ (X-X)2 = sum of squares of the
differences between scores/ratings and
when mean is used to
the mean. describe an entire sample.
 BIVARIATE DESCRIPTIVE STATISTICS
CROSS TABUL ATIONS C ORREL ATION

Crosstabs Table - frequency Correlation Methods - described
relationships between 2 variables by
distribution in which the
calculating the correlation
frequencies of two variables coefficient w/c describes the
are cross-tabulated. intensity & direction of a relationship
Correlation Coefficient - indicates
how “perfect” a relationship is w/
possible values ranging from -1.00
thru.00 to +1.00
Pearson’s r - most widely used
correlation statistic.
 CORRELATION COEFFICIENT VALUES
1. A correlation coefficient of 1.00: 3. A correlation coefficient of 0.00:
represents a perfect positive linear suggests no linear relationship between
relationship. It means that when one the two variables. They are statistically
variable increases, the other variable independent of each other.
increases in a perfectly linear fashion.
4. A correlation coefficient between
All data points fall along a straight
line with a positive slope. -1.00 and 0.00: represents a negative
linear relationship. As the correlation
2. A correlation coefficient between coefficient gets closer to -1.00, the
0.00 and 1.00: indicates a positive negative relationship becomes stronger.
linear relationship. As the correlation
A value of -1.00 means a perfect
coefficient gets closer to 1.00, the
negative linear relationship, where one
relationship becomes stronger. A
v a r i a b l e i n c re a s e s a s t h e o t h e r
value of 0.00 means no linear
relationship. decreases in a perfectly linear fashion.
 PEARSON’S R
1. A d e s c r i p t i v e s t a t i s t i c ,
summarizes the characteristics of
a d a t a s e t. S p e c i f i c a l l y, i t
describes the strength & direction
of the linear relationship between
two quantitative variables.

2. Also an inferential statistic,
meaning that it can be used to
test statistical hypotheses.
Specifically, we can test whether
there is a significant relationship
between two variables.
 DECIDING RISK
Absolute Risk (AR) -the proportion of
people who experienced an undesirable
outcome in each group.

Absolute Risk Reduction (ARR) -comparison
of 2 risks, computed by subtracting the
absolute risk for the exposed group from the
absolute risk for the unexposed group.

Odds Ratio (OR) - the proportion of subjects
with the adverse outcome relative to those
without it.
NUMBER NEEDED TO TREAT (NNT) = 1/.30 = 3.33

Number Needed to Treat (NNT) - estimates
how many people would need to receive an
intervention to prevent one undesirable
outcome.
 INTRODUCTION TO INFERENTIAL STATISTICS
Inferential Statistics -a Uses of Inferential Statistics:
branch of statistics that A. To estimate population parameter
involves drawing Sampling error w/c is the difference b/n data
conclusions, making obtained from a random sampled population &
predictions, and data that would be obtained if an entire
generalizing findings from population is measured.
a sample to a larger
Sampling distribution is a theoretical frequency
population.
distribution based on an infinite number of
Concerned with samples.
population and the use Sampling bias occurs when samples are not
of sample data to predict carefully selected as in non-probability sampling.
future occurrences. B. Testing the Null Hypothesis
 INTRODUCTION TO INFERENTIAL STATISTICS
SAMPLIN G DISTRIBUTION
Are used in statistics to
understand how sample statistics,
such as means, variances, or
proportions, vary when
re p e a t e d l y d r a w i n g r a n d o m
samples from a population.

To c o m p u t e t h i s , s t a t i s t i c a l
software or programming
languages like R, Python, or
specialized statistical tools may
be used.
 INTRODUCTION TO INFERENTIAL STATISTICS
PARAMETER ESTIMATION STEPS IN TESTIN G HYPOTHESIS
Consists of 2 Techniques: 1. S e l e c t i n g a n a p p r o p r i a t e
statistical test.
1. Parameter Estimation is used to
estimate a parameter. 2. S p e c i f y i n g t h e l e v e l o f
Takes 2 forms: Point Estimation significance.
& Interval Estimation.
3. Compute a test statistic.
2. Hypothesis Testing - provides
4. Determining degrees of freedom.
objective criteria for deciding
whether research hypotheses 5. Comparing the test statistic to a
should be accepted as true or theoretical value.
rejected as false.
 INTRODUCTION TO INFERENTIAL STATISTICS
T YPE I & T YPE II ERRORS LEVEL OF SIGNIFIC ANCE (LOF)

Ty p e I E r r o r - f a l s e - p o s i t i v e Frequently used LOF are.05
conclusion &.01.
Occurs when the null hypothesis
Often denoted by the
is rejected when in reality it is not.
symbol α (alpha).
Type II Error - false-negative
conclusion Use to determine whether
Occurs when the null hypothesis the results of a statistical
is regarded as true but it is in fact test are statistically
false.
significant or not.
 BIVARIATE STATISTICAL TESTS
Analysis of Variance (ANOVA)
t-TESTs Used to test mean group differences of
three or more groups.

One-Way Analysis of Variance or ANOVA -
for testing mean differences among three or
more groups by comparing variability
between groups to variability within groups.

Two -way analysis of variance - used to test
the relationship between one independent
variable & multiple dependent variables,
commonly used in factorial design.

Repeated Measures ANOVA (RM-ANOVA) -
used when the means being compared are
means at different points in time.
 BIVARIATE STATISTICAL TESTS
Chi-Squared Test
Used to test hypotheses about differences in proportions.

Computed by summing differences between the observed
frequencies in each cell (such as those in Table 15.10) and the
expected frequencies—the frequencies that would be expected
if there were no relationship between the two variables.

Correlation Coefficients

Pearson’s r - already
discussed in slide #14.
 MULTIVARIATE STATISTICAL ANALYSIS
Multiple Regression Analysis of Covariance (ANCOVA)
Used to collate more than two Combines features of ANOVA &
variables. muliple regression, used to control
confounding variables statistically
Microstat software in which the —that is to “equalize’ groups being
formulas are embedded is used. compared.
Logistic Regression
Printouts contain the computed
values of R1 R2 and the critical Analyzes the relationships between
values, R at 0.05 or 0.01 multiple independent variables & a
significance level. nominal-level dependent variable

e.g., compliant versus noncompliant
Does not have negative values.
 MEASUREMENT STATISTIC

Reliability Assessment Validity Assessment
Content Validity - relevant for composite
Test-retest Reliability measures such as multi-item scales. Usually
relies on expert ratings of each item & ratings
Interrater Reliability are used to compare an index called CVI.

Criterion Validity - concerns the extent to w/c
Internal Consistency scores on a measure are consistent w/ a “gold
Reliability standard” criterion.

Construct Validity - concerns the extent to w/c
a measure is truly measuring the target
construct & often assessed using hypothesis
testing.
 ASSESSING QUALITY DATA

1. Credibility 2. Dependability
A. Prolonged engagement
3. Confirmability
B. Persistent observations
4. Transferability
C. Triangulation
5. Authenticity
D. Peer debriefing & member
checks

E. Search for disconfir ming
evidence