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Elementary Statistics for the Social Sciences (UC:CSU) - 3 units

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Presentation on theme: "Elementary Statistics for the Social Sciences (UC:CSU) - 3 units"— Presentation transcript:

1 Elementary Statistics for the Social Sciences (UC:CSU) - 3 units
Ray Lim, PhD. BEH 1306F Statistics 1

2 INTRODUCTION Statistics
A set of mathematical procedures for organizing , summarizing, and interpreting information Population A group of two or more individuals or things that share one or more common characteristics Sample A subgroup of two or more individuals or things from a population Statistics 1

3 Representative Sample
·      A subgroup of two or more individuals or things randomly and independently selected * from a population ·      Randomly and independently selected means each member of the population has an equal opportunity of being included in the sample Parameter ·      Usually a numerical value, that describes a population. Statistics 1

4 Relationship between a population and sample
Statistics 1

5 A value, usually a numerical value that describes a sample. Data
Statistic A value, usually a numerical value that describes a sample. Data measurements or observations Descriptive Statistics Statistical procedures used to summarize, organize and simplify data. Inferential Statistics Techniques that allow us to study samples and then make generalization about the population from which they were selected. Statistics 1

6 Sampling error ·      The discrepency, or amount of error, that exists between a sample statistic and the corresponding population parameter Variable ·      A characteristic or condition that changes or has different values for different individuals Constant ·      A characteristic or condition that does not vary but is the same for every individual. Statistics 1

7 Correlational Research: Observing naturally occurring phenomena
·      Naturalistic observation ·      Archival research ·      Case histories ·      Surveys Correlational Research –Is variable X associated with variable Y? –Example: Is watching WWE related to aggressive behavior in children? –How can we describe this relationship? Statistics 1

8 Correlational Research: Limitations – Correlation does not = causality
–Perhaps higher levels of WWE viewing is associated with higher levels of aggressive behavior Correlational Research: Limitations –       Correlation does not = causality –       Perhaps X  Y •          Viewing WWE  aggressive behavior –       Perhaps Y  X •          Aggressiveness  WWE viewing Perhaps some other variable (Z?) is causing both X & Y          Lack of parental supervision  both aggressive behavior & WWE viewing Statistics 1

9 Correlational Research: Advantages
–       A good place to start & explore (especially if relevant theory is lacking) –       Often cheapest & easiest option –       Can look at more variables simultaneously / greater realism Fewer ethical issues… Statistics 1

10 Experimental Research: Manipulation & Measurement
–       Independent (manipulated) variables –       Dependent (measured) variables –       Does manipulating IV “X” cause changes in DV “Y?” –       Example: Does assigning some children to watch WWE cause them to behave more aggressively than other children? Statistics 1

11 Experimental Research: Analyzing causality – Manipulation of IV
–    Random assignment to treatments –    Control of extraneous variables –    Eliminating threats to validity Experimenter bias, for example •   Affects treatments •   Affects measurements Statistics 1

12 Experimental Research: Limitations
-       Often harder, more time consuming, &/or expensive –       Some variables can’t be manipulated –       Difficult to control for all extraneous variables (hold them all constant) –       Difficult to make the experimental situation realistic –       Procedural mistakes or flawed sampling can make findings useless Statistics 1

13 Greater ethical obligations
–       Some variables shouldn’t be manipulated, or only with great caution Repeat as necessary to build, refine, or discard theory –       Theories allow us to generate testable hypotheses –       When hypotheses are supported by evidence, the theory is considered the best explanation so far When hypotheses are not supported, the theory is refined or discarded Statistics 1

14 Role of statistics in experimental research

15 Criteria for evaluating evidence Observations must be – Public
–         Replicable •   Can be repeated by others using same procedures –         Reliable •    Consistent across measurements &/or observers Statistics 1

16 Hypothetical results from a correlational study
Statistics 1

17 Depends on the population you want your findings to apply to
–    to talk about a specific group like women, study women –     to make statements about people in general, study samples representative of people in general Random sampling of the population of interest is best, but often difficult to achieve Statistics 1

18 Operational Definitions
–       Defining a construct in terms of the operation(s) used to measure it Ways to measure fear? attraction? Poor operational definitions bad research / misleading results –       Problems with reliability of observations –       Problems with interpretation of results Statistics 1

19 Independent variable –The variable that is manipulated by the researcher. Independent variable consists of the antecedent condition that were manipulated prior to observing the dependent variable. Dependent variable –The variable that is observed in order to assess the effect of the treatment. Statistics 1

20 –Individuals do not receive experimental treatment.
Control condition –Individuals do not receive experimental treatment. Experimental condition –Individuals receive experimental treatment. Confounding variable –An uncontrolled variable that is unintentionally allowed to vary systematically with the independent variable. Statistics 1

21 An example of a confounding variable (Instructor)
Statistics 1

22 Discrete vs. Continuous Variables
Discrete: each item corresponds to a separate value of the variable Values/categories do NOT overlap or “touch” on the scale. There are no values “in between” Statistics 1

23 Statistics 1

24 Intervals defined by upper & lower real limits
Continuous: each item corresponds to an interval on the scale of measurement. Intervals defined by upper & lower real limits Real limits are continuous (“they touch”) Statistics 1

25 Continuous Variable Statistics 1

26 Properties of scales of measurement
Each scale has all the properties of the ones below it plus an additional property. The higher-level measurements contain more detailed information about observations & allow more complex analyses. Statistics 1

27 o Identification (Name): allows you to label observations.
Nominal Scale o    Identification (Name): allows you to label observations. o    Applies to category labels & numbers used as labels. o    Examples: college major, any “yes/no,” participant number, etc… Statistics 1

28 o Applies to ordered category labels & numbers used as ranks.
Ordinal Scale o    Magnitude (Order): allows you to make statements about relative size or ordering/ranking of observations. o    Applies to ordered category labels & numbers used as ranks. o    Examples: any “high/medium/low,” class rank, etc… Statistics 1

29 o Applies to numbers, often scores or ratings.
Interval Scale o    Equal Intervals: allows you to assume that the distances between numbers on the measurement scale are equal & correspond to equal differences in the variable being measured. o    Applies to numbers, often scores or ratings. o    Examples: attitude as preference ratings, etc... Statistics 1

30 o Applies to numbers, often tallies or physical measurements.
Ratio Scale o    Absolute Zero: allows you to assume that a score of “0” on a variable really means the absence of that property, & that you can make meaningful ratio statements. o    Applies to numbers, often tallies or physical measurements. o    Examples: stress as change in BP, memory performance as # of words recalled, etc... Statistics 1

31 Displaying our observations: Frequency distribution tables & graphs of frequency distributions
Frequency distribution table: shows a range of possible values for a single variable (X) & the number of observations of each value (f). Statistics 1

32 Proportion: p= f / N percentage=p*100 p(m)= % of the class is male
Nominal data Example: X =gender of class members (1 = male; 2 = female) X f 1 14 OR Male 2 33 Female Σf=N= Proportion: p= f / N percentage=p*100 p(m)= % of the class is male Statistics 1

33 X f fX p = f/N % = p(100) 10 2 9 5 8 7 3 6 4 1 Σf = N = ΣX = ΣX² =
4 1 Σf = N = ΣX = ΣX² = Statistics 1

34 Rank or percentile rank
A particular score is defined as the percentage of individuals in the distribution with scores at or below the particular value. Calculating cumulative frequencies (cf) & cumulative percentages (cum%) cf = # of observations at or below a given value of X add up frequencies from bottom of table upwards cum% = percentage of observations at or below a given value of X divide cf/N for each row (better—less rounding error) OR add up percentages from bottom of table upwards Statistics 1

35 X f fX cf c% 10 2 9 5 8 7 3 6 4 1 Σf = N = ΣX = ΣX² = Statistics 1

36 Characteristics of distributions
Symmetry vs. skewness, number of modes or “pileups” Statistics 1

37 The Normal Distribution
mean = median = mode symmetrical Many complexly-determined traits are normally distributed, e.g. IQ & SAT scores. Statistics 1

38 A symmetrical bimodal distribution mean = median, with 2 modes
Bimodal distributions may also be asymmetrical (mean, median), & multimodal distributions are possible. Statistics 1

39 A positively skewed distribution (tail  positive end of scale)
Mode<median<mean Statistics 1

40 A negatively skewed distribution (tail  negative end of scale)
Mean<median<mode Statistics 1


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