1. Copyright © 2011 by The McGraw-Hill Companies, Inc. All rights reserved. McGraw-Hill/Irwin Describing Data

2. 2 Descriptive statistics allow you to summarize data within only a few numbers Use exploratory data analysis (EDA) to search for patterns in your data Before conducting any inferential statistic, use EDA to ensure that your data meet the requirements and assumptions of the test you are planning to use (e.g., normally distributed)

3. 3 Steps involved in the EDA : 1. Organize and summarize your data on a data coding sheet 2. If desired, organize data for computer entry 3. Graph data (bar graph, histogram, line graph, or scatterplot) so that you can visually inspect distributions  This will help you choose the appropriate statistics 4. Display frequency distributions on a histogram, and create a STEMPLOT 5. Examine your graphs for normality or skewness in your distributions

4. 4 How you organize your data depends on the type of research conducted Survey data Organized into a series of columns one for respondent number and the rest for responses to survey items Nominally scaled data should be dummy coded (e.g., 1=Yes, 2=No) A “key” or “code sheet” is used to describe scales used for questions Experimental/quasi-experimental data Data broken down by condition Unstacked format: Separate column for data from each treatment Stacked format: Columns created for participant number, each treatment and data

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6. 6 You must decide whether to analyze grouped or individual data Grouped data Data represented by a single score (e.g., the average) Convenient but there are limitations Average score may not represent subjects’ individual performance in a group Curves representing averaged data may not represent true nature of psychological phenomenon measured

7. 7 Individual data Makes most sense for repeated measures Useful when phenomenon measured is either/or (something learned or not) May reflect effect more faithfully than grouped data Best strategy is to inspect both individual and grouped data

8. 8 A graph represents data in two dimensional space Two dimensions represented by two lines intersecting at a right angle Horizontal axis is called the abscissa or x-axis Levels of independent variable represented on x-axis Vertical axis is called the ordinate or y-axis Value of the dependent variable represented on y-axis A pair of values (one from x-axis and one from y- axis) defines a single point on the graph

9. 9 Bar Graph Presents data as bars extending from the axis representing the independent variable Length of each bar determined by value of the dependent variable Width of each bar has no meaning Precision of estimate shown in error bars (whiskers extending above and below top of each bar) Can be used to represent data from single-factor and two- factor designs Best if independent variable is categorical

10. 10 Error bar

11. 11 Line Graph Data represented by a series of points connected by a line Most appropriate for quantitative independent variables Used to display functional relationships Line graphs can show different shapes Positively accelerated: Curve starts flat and becomes progressively steeper as it moves along x-axis Negatively accelerated: Curve is steep at first and then “levels off” as it moves along x-axis Once the curve levels off it is said to be asymptotic

12. 12 Error bar

13. 13 A line graph can vary in complexity A monotonic function represents a uniformly increasing or decreasing function A nonmonotonic function has reversals in direction

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16. 16 Scatterplot Used to represent data from two dependent variables The value of one dependent variable is represented on the x-axis and the value of the other on the y-axis May include a “best fitting” straight line indicating the general trend in the data Correlation coefficient and equation for line usually shown in this case

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18. 18 Pie Graph Used to represent proportions or percentages Two types Standard pie graph Exploded pie graph

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20. 20 Graphing data has two advantages over tabular presentation Shows relationship between independent and dependent variables more clearly Graph shows subtleties that may not be evident in a table Helps you evaluate data to decide on appropriate statistical test Shapes of graphs can be inspected to see if data meet assumptions of statistical test

21. 21 Represents a set of mutually exclusive categories into which actual values are classified Can take the form of a table or a graph Graphically, a frequency distribution is shown on a histogram A bar graph on which the bars touch The y-axis represents a frequency count of the number of observations falling into a category Categories represented on the x-axis

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23. 23 You should examine your frequency distribution to determine its shape. Normal distribution: Most scores centered around the mean Positive skew: Most scores at the lower end of the measurement scale Negative skew: Most scores at the higher end of the measurement scale Bimodal distribution: Two modes

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27. 27 Alternative to histogram Displays data so that original numbers can be retrieved Creating a stemplot 1. Break each number into a stem (leftmost number) and leaf (rightmost number) 2. Arrange stems in a column and draw a line to the right of the stems 3. Place each leaf number for each stem to the right of the line

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29. 29 Mode Most frequent score in a distribution Simplest measure of center Scores other than the most frequent not considered Limited application and value Median Central score in an ordered distribution More information taken into account than with the mode Relatively insensitive to outliers Used primarily when the mean cannot be used

30. 30 Mean Average of all scores in a distribution Value dependent on each score in a distribution This makes the mean sensitive to outliers (extreme scores) Most widely used and informative measure of center

31. 31 Mode Used if data are measured along a nominal scale Median Used if data are measured along an ordinal or nominal scale Used if interval data do not meet requirements for using the mean

32. 32 Mean Used if data are measured along an interval or ratio scale Most sensitive measure of center Used if scores are normally distributed Mean does not represent center if distribution is skewed

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34. 34 Range Subtract the lowest from the highest score in a distribution of scores Simplest and least informative measure of spread Scores between extremes are not taken into account Very sensitive to extreme scores Semi-Interquartile Range Less sensitive than the range to extreme scores Used when you want a simple, rough estimate of spread

35. 35 Variance Average squared deviation of scores from the mean Not expressed in same units as original numbers Standard Deviation Square root of the variance Expressed in the same units as original numbers Most widely used measure of spread

36. 36 The range and standard deviation are sensitive to extreme scores In such cases the semi-interquartile range is best When your distribution of scores is skewed, the standard deviation does not provide a good index of spread With a skewed distribution, use the semi- interquartile range

37. 37 Five Number Summary Convenient way to represent a distribution with a few numbers Statistics included Minimum score The first quartile The median (second quartile) Third quartile Maximum score

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39. 39 Boxplot Graphic representation of the five number summary First and third quartile define the ends of the box A line in the box represents the median Vertical “whiskers” extending above and below the box represent the maximum and minimum scores (respectively) Data from multiple treatments are represented by side- by-side boxplots

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41. 41 Used when you want to determine the direction and degree of relationship between variables Various measures of association available for different applications

42. 42 Most widely used measure of association Value of r can range from +1 through 0 to – 1 Magnitude of r tells you the degree of LINEAR relationship between variables Sign of r tells you the direction (positive or negative) of the relationship between variables

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44. 44 Presence of outliers affects the sign and magnitude of r Variability of scores within a distribution affects the value of r Used when scores are normally distributed

45. 45 Pearson Product-Moment Correlation Index of linear relationship between two continuously measured variables Point-Biserial Correlation Index of correlation between two variables, one of which is measured on a nominal scale and the other on at least an interval scale Spearman Rank-Order Correlation (rho) Index of correlation between two variables measured along an ordinal scale

46. 46 Phi Coefficient Index of correlation between two variables measured along a nominal scale

47. 47 Used to find the straight line that best fits the data plotted on a scatterplot The best fitting straight line is known as the least squares regression line The regression line is defined mathematically:

48. 48 The regression weight (b) is based on raw scores and is difficult to interpret The standardized regression weight (beta weight) is based on standard scores and is easier to interpret You can predict a value of Y from a value of X once the regression equation has been calculated The difference between predicted and observed values of Y is the standard error of estimate

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