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hss2381A – stats... or whatever
Univariate Analysis, part 1Descriptive Statistics
• Evidence-based practice (EBP): Use of best clinical evidence in making patient care decisions
• Best source of evidence: Systematic research
• How reliable is the evidence? • What is the magnitude of effects? • How precise is the estimate of effects?
• Answering these questions requires an understanding of statistics
Evidence-Based Medicine (EBM) or Evidence-Based Practice (EBP) Questions:
Data and Data Analysis
• In the context of a study, the information gathered to address research questions is data
• In quantitative research, data are usually quantitative (numbers)
• Quantitative data are subjected to statistical analysis
Examples of Independent and Dependent Variables
• Independent variable (IV): Smoking• Dependent variable (DV): Lung cancer IV DV ?
Research Question
• Research questions are the queries researchers seek to answer through the collection and analysis of data
• Research questions communicate the research variables and the population (the entire group of interest)
– Example: In hospitalized children (population) does music (IV) reduce stress (DV)?
Defining a Variable
• Two phases:– Conceptual
– operational
Defining a Variable
• In studies, variables need to be defined• Conceptual definition: The theoretical
meaning of the underlying concept• Operational definition: The precise set of
operations and procedures used to measure the variable
Example:Concept = how long have you been on this planet?Operation = In what age group, by years, are you in?
Descriptive Statistics
• Researchers collect their data from a sample of study participants—a subset of the population of interest
• Descriptive statistics describe and summarize data about the sample
– Examples: Percent female in the sample, average weight of participants
Inferential Statistics
• Researchers obtain data from a sample but often want to draw conclusions about a population
• Parameter: A descriptive index for a population– Example: Average daily caloric intake of all 10-year-old
children in New York
• Statistic: A descriptive index for a sample– Example: Average daily caloric intake of 300 10-year-old
children from three particular NY schools
SPSS and Statistical Analysis
• SPSS (Statistical Package for the Social Sciences) is among the most popular statistical software packages for analyzing research data
• It is user friendly and menu driven• The datasets offered with this textbook are
set up as SPSS files
The Data Editor in SPSS
• The data editor in SPSS offers a convenient spreadsheet-like method of creating, editing, and viewing data
• There are two “views” within the data editor: – Data View: Shows the actual data values– Variable View: Shows variable information for all
variables
Data View in the Data Editor
• The columns represent one variable each; unique variable names (no more than eight characters long) are shown at the top of each column
• Each row is a case, representing an individual participant
• The data view tab is at the bottom
Variable View in the Data Editor
• Variable View shows a wealth of information about how variables are coded, how they will be labeled in output, level of measurement, and so on
• The Variable View tab is at the bottom
Versions of SPSS
• New versions of SPSS are created regularly, to offer improved options for analysis and presentation
• Examples in this book were created in SPSS Version 16.0
• The student version of SPSS is available for analyzing relatively small datasets (no more than 50 variables and no more than 1,500 cases)
What is this?FREQUENCY DISTRIBUTION
Same as Histogram?
Frequency Distributions
• A frequency distribution is a systematic arrangement of data values, with a count of how many times each value occurred in a dataset
• You can portray this as a table or as a graph
Constructing a Frequency Distribution
• List each data value in a sequence (usually, ascending order) 1, 2, 3, 4, 5…
• Tally each occurrence of the value • Total the frequencies for each value (f) • The sum of fs for all data values must equal
the sample size:Σf = N
Elements of a Typical Frequency Distribution
• Data values• Absolute frequencies (counts)• Relative frequencies (percentages) • Cumulative relative frequencies (the
percentage for a given score value, combined with percentages for all preceding values)
Example...• Let’s say we have 10 people of varying ages:
– Ages: 17, 26, 33, 35, 14, 55, 67, 35, 21, 19
• Let’s construct the frequency distribution of the age GROUPS: 0-25 yrs, 26-45 yrs, >45 yrs
Age group
0-25
26-45
>45
Frequency
4
4
2
Relative Freq.
4/10 = 40%
4/10 = 40%
2/10 = 20%
Cumulative Freq.
40%
40+40% = 80%
80+20% = 100%
Summary of Our ExampleData Value Frequency
(f)
Percentage
(%)
Cumulative Percentage
0-25 4 40.0 40.0
26-45 4 40.0 80.0
>45 2 20.0 100.0
TOTAL 10 100.0
Frequency Distributions and Measurement Levels
• Remember “measurement levels”?– Nominal, ordinal, interval, ratio...
• Frequency distributions can be constructed for variables measured at any level of measurement
• BUT…for categorical (nominal-level) variables, cumulative frequencies do not make sense
• Also...
Frequency Distributions for Variables with Many Values
• When a variable has many possible values, a regular frequency distribution may be unwieldy – For example, weight
values (here, in pounds)
Weight f
98 1
99 1
100 1
101 0
102 2
103 1
104 0
105 2
106 1
Etc. to 285 lb
…
Which is Why We Used “Age Group” instead of “Age”
• This is sometimes called a “grouped frequency distribution”
• In a grouped frequency distribution contiguous values are grouped into sets (class intervals)
• Typically, we use groupings that are psychologically appealing (e.g., 10-25 years etc, not 7-13 years, etc)
Weight f
98 1
99 1
100 1
101 0
102 2
103 1
104 0
105 2
106 1
Etc. to 285 lb
…
Weight Interval
f
75 - 100 6
101 - 125 15
126 - 150 33
151 - 175 26
176 - 200 24
201 - 225 14
226 - 250 9
251 - 275 6
276 - 300 2
This grouping communicates information more conveniently than individual weights
Reporting Frequency Information
• Can be reported narratively in text (e.g., “83% of study participants were male”)
• In a frequency distribution table (multiple variables often presented in a single table)
• In a graph: Different graphs used for different types of data
Bar Graphs
• Bar graphs: Used for nominal (and many ordinal) level variables
• Bar graphs have a horizontal dimension (X axis) that specifies categories (i.e., data values)
• The vertical dimension (Y axis) specifies either frequencies or percentages
• Bars for each category drawn to the height that indicates the frequency or %
Bar Graphs
• Example of a bar graph
• Note the bars do not touch each other
Pie Chart
• Pie Charts: Also used for nominal (and many ordinal) level variables
• Circle is divided into pie-shaped wedges corresponding to percentages for a given category or data value
• All pieces add up to 100%• Place wedges in order, with biggest wedge
starting at “12 o’clock”
Pie Chart
• Example of a pie chart, for same marital status data
Histograms
• Histograms: Used for interval- and ratio-level data
• Similar to a bar graph, with an X and Y axis—but adjacent values are on a continuum so bars touch one another
• Data values on X axis are arranged from lowest to highest
• Bars are drawn to height to show frequency or percentage (Y axis)
HistogramsExample of a histogram: Heart rate data
0
2
4
6
8
10
12
0 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74
Heart rate in bpm
f
Frequency Polygons
• Frequency polygons: Also used for interval- and ratio-level data
• Similar to histograms, but instead of bars, a dot is used above score values to designate frequency/percentage
• Better than histograms for showing shape of distribution of scores, and is usually preferred if variable is continuous
•Example of a frequency polygon (created in SPSS)
•Note that the line is brought down to zero for the score below lowest data point (54) and above highest data point (75)
Frequency Polygon, Heart Rate
Heart Rate in bpm
7472706866646260585654
Freq
uenc
y
12
10
8
6
4
2
0
Shapes of Distributions
• Distributions of data values can be described in terms of:– Modality – Symmetry– Kurtosis
Modality
• Modality concerns how many peaks (values with high frequencies) there are
• Unimodal = 1 peak• Bimodal = 2 peaks• Multimodal = multiple peaks
Unimodal:
Bimodal:
How is this useful?
Example: Tuberculosis
• What is it?• We apply tuberculin skin test (also called PPD
– purified protein derivative) test• Positive response is an “induration”
– a hard, raised area with clearly defined margins at and around the injection site
What type of curve is this?
Distribution of systolic blood pressure for men (unimodal distribution)
Symmetry
• Symmetric Distribution: the two halves of the distribution, folded over in the middle, are identical
Symmetry
• Asymmetric (Skewed) Distribution: Peaks are “off center” and there is a tail trailing off for data values with low frequency– Positive skew: Longer tail trails off to right (fewer
people with high values, like for income)– Negative skew: Longer tail trails off to left (fewer
people with low values, like age at death)
Direction of Skew
• Examples of distributions with different skews:
Skewness Index• Indexes have been developed to quantify
degree of skewness• One skewness index (e.g., in SPSS) has:
– Negative values, for a negative skew – 0, for no skew – Positive values, for a positive skew
• If skewness index is less than twice the value of its standard error (to be explained later), distribution can be treated as not skewed
Skewness Index Examples
• Skewness index = 0.80 • Standard error = 0.33
• Positive skew
• Skewness index = -0.72• Standard error = 0.34
• Negative skew
Kurtosis
• Kurtosis: Degree of pointedness or flatness of the distribution’s peak
• Leptokurtic: Very thin, sharp peak• Platykurtic: Flat peak• Mesokurtic: Neither pointy nor flat
– Like skewness, there is an index of kurtosis• Positive values: Greater peakedness• Negative values: Greater flatness
Kurtosis Examples
Leptokurtic (+ index)
Platykurtic (– index)
Normal Distribution
What is this curve called?
Normal Distribution
• A normal distribution (aka normal curve, bell curve, Gaussian distribution, etc) is:
– Unimodal– Symmetric– Neither peaked nor flat
• Plays an important role in inferential statistics
We will re-visit the Normal Distribution in more depth in the future
Some human characteristics are normally distributed (approximately), like height
1 short person, 3 medium persons, 1 tall person
Uses of Frequency Distributions in Data Analysis
• First step in understanding your data!– Begin by looking at the frequency distributions for
all or most variables, to “get a feel” for the data– Through inspection of frequency distributions,
you can begin to assess how “clean” the data are• (will discuss next time)
Central Tendency
• “Central Tendency” is a characteristic of a distribution– Describes how data is clustered around some value– In other ways, it’s a way of summarizing your data by
identifying one value in the set that is the most important
– There are several indices of central tendency, but 3 are the most important:
• Mode• Median• Mean
Next class, we’ll get into these in more depth
Homework!
• P.17: A1-A4• P.36: A1-A5