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Inferential StatisticsMEDICAL STATISTICS -PART II
http://www.socialresearchmethods.net/kb/statinf.php
World of StatisticsDescriptive statistics
Inferential Statistics
PROVIDE SIMPLE SUMMARIES ABOUT THE SAMPLE AND THE MEASURES IN a)TABLES b) GRAGHS . CHARTS . CIRCLE .DOT PLOTS .BOX-AND-WHISKER PLOTS .SCATTER PLOT . SURVIVAL PLOTS . BLAND-ALTMAN PLOTS
The T-TestDummy Variables["proxy" ]=variables in inferential statisticsGeneral Linear Model[ most common use of inferential statistics]Post test-Only Analysis[simple t-test or one-way ANOVA]Factorial Design Analysis[ANOVA]Randomized Block AnalysisAnalysis of Covariance[ANOVA & ANCOVA]Non-equivalent Groups AnalysisRegression-Discontinuity AnalysisRegression Point Displacement Analysis
Talk to beginner in next 4 pages Descriptive statistics Inferential Statistics Properties of population Everything is visible in tables and graphs Everybody can understand with minimum
effort Uses central tendency(Bell curve) and
measure spread Measured in parameters( mean,
standard deviation and variance) But have not access to the whole
population you are interested in investigating
The sample behaviour inferences the population under study beyond just visibility
Estimates parameter(s) and looks beyond parameters at sample and population level
Testing of statistical hypotheses[how far not by chance]
Critically analyse variability using statistical models and advanced software under the guidance of expert statistician
VariablesIndependent Dependent Variables
Also called Experimental or predictor variable
The manipulation of which influence the result (dependent variable)
Example: The number revision or level of intelligence that influences mark secured from full 100 mark
Mark secured in examination is dependent variable affected by manipulation of dependent
Categorical and Continuous Variables
Categorical Continuous Also called Discrete or qualitative Three types
Nominal: only name them in 2 or more groups
Ordinal: Arrange them in orders in 2 or more groups
Dichotomous: Arrange them only two groups
https://statistics.laerd.com/statistical-guides/types-of-variable.php
Also called quantitative variables Two types
Interval: measured along a continuum and they have a numerical value (for example, temperature measured in degrees Celsius or Fahrenheit)
Ratio: The name "ratio" reflects the fact that you can use the ratio of measurements. example, a distance of ten metres is twice the distance of 5 metres. Ratio variables are interval variables, but with the added condition that 0 (zero) of the measurement indicates that there is none of that variable
Sample Sampling is the process of selecting units of people from a population of interest so that by studying the sample we may fairly generalize our results back to the population from which they were chosen)
The listing of the accessible population from which you'll draw your sample is called the sampling frame
What do these words mean
A "bell-shaped" curve that describes the group's distribution of a single variable
Think of the bell curve as a smoothed histogram or bar graph describing the frequency of each possible measurement response: The heart of statistics
Difference: 2 µ related not by chance
In the figure, we show distributions for both the treatment and control group. The mean values for each group are indicated with dashed lines. The difference between the means is simply the horizontal difference between where the control and treatment group means hit the horizontal axis.
Hypothesis TestingA statistical hypothesis is an assumption about a population parameterHypothesis testing refers to the formal procedures used by statisticians to accept or reject statistical hypothesesTypically examine a random sample from the populationIf sample data are not consistent with the statistical hypothesis, the hypothesis is rejected
2 types of statistical hypothesesNull hypothesis(Ho) Alternative hypothesis(Ha)Sample observations result purely from chance
sample observations are influenced by some non-random cause
Decision ErrorsType I error. A Type I error occurs when the researcher rejects a null hypothesis when it is true. The probability of committing a Type I error is called the significance level. This probability is also called alpha( α).
Type II error. A Type II error occurs when the researcher fails to reject a null hypothesis that is false. The probability of committing a Type II error is called Beta( β). The probability of not committing a Type II error is called the Power of the test.
Example Suppose we wanted to determine whether a coin was fair and balanced. A null hypothesis might be that half the flips would result in Heads and half, in Tails. The alternative hypothesis might be that the number of Heads and Tails would be very different. Symbolically, these hypotheses would be expressed as
H0: P = 0.5 Ha: P ≠ 0.5
Suppose we flipped the coin 50 times, resulting in 40 Heads and 10 Tails. Given this result, we would be inclined to reject the null hypothesis. We would conclude, based on the evidence, that the coin was probably not fair and balanced.http://stattrek.com/hypothesis-test/hypothesis-testing.aspx?Tutorial=AP
The region of acceptance
If p-Value is < than alpha-risk, reject Ho and accept Ha If p-Value is > than alpha-risk, fail to reject the Null, Ho
http://www.six-sigma-material.com/Hypothesis-Testing.html
The prototype inferential statistics: t-testTo compare the average performance of two groupsUse a single measure to see if there is a difference Example: Whether eighth-grade boys and girls differ in math test scores or whether a program group differs on the outcome measure from a control group
General Linear Model includest-test Analysis of Variance (ANOVA) Analysis of Covariance (ANCOVA) Regression analysisMultivariate methods : 1. Factor analysis 2.Multidimensional scaling 3.Cluster analysis 4. discriminant function analysis
General Linear Model is the simplest straight-line model that opens the door for more complex inferential statistics
Experimental Analysis: some inferential statisticsThe simple two-group posttest-only randomized experiment : t-test or one-way ANOVA The factorial experimental designs : Analysis of Variance (ANOVA) Model Randomized Block Designs: ANOVA blocking model The Analysis of Covariance Experimental Design uses the Analysis of Covariance statistical model[ANCOVA]
The T-Test :test the variability of 2 µ in posttest analysis Judge the difference between their means relative to the spread or variability of their scores
Mean equal but variability is different
In which of the three cases would it be easiest to conclude that the means of the two groups are different? If you answered the low variability case, you are correct! Why is it easiest to conclude that the groups differ in that case? Because that is the situation with the least amount of overlap between the bell-shaped curves for the two groups. If you look at the high variability case, you should see that there quite a few control group cases that score in the range of the treatment group and vice versa. Why is this so important? Because, if you want to see if two groups are "different" it's not good enough just to subtract one mean from the other -- you have to take into account the variability around the means! A small difference between means will be hard to detect if there is lots of variability or noise. A large difference will between means will be easily detectable if variability is low
Compute t value
standard error of the difference
varT=variance of treatment groupvarC=variance of control groupnt=sample number in treatment groupnc=sample number in control groupVar=variance=Square of standard deviation
Therefore finally
Interpretation of tPositive t-value shows first mean > second Negative if first mean is smaller Then match t value in table of significance to test whether this value is large enough to say that the difference between the groups is not likely to have been a chance finding
To test the significance, you need to set a risk level (called the) alpha level=P value) In most social research, the "rule of thumb" is to set the alpha level at .05 This means that five times out of a hundred you would find a statistically significant difference between the means even if there was none (i.e., by "chance")
Determine the degrees of freedom (df) for the test. In the t-test, the degrees of freedom is the sum of the persons in both groups minus 2 Given the alpha level, the df, and the t-value, you can look the t-value up in a standard table of significance to see whether this observation is a mere chance or real association.
The t-test, one-way Analysis of Variance (ANOVA) and a form of regression analysis are mathematically equivalent
Dummy VariablesIs a numerical variable Used in regression analysis distinguish different treatment groupsdummy variable is 0 indicates ,it is placebo group dummy variable is 1 indicates ,it is treatment groupenable us to use a single regression equation to represent multiple groupsact like 'switches' that turn various parameters on and off in an equation
General Linear Model[GLM ]Most important statistical tool that allows us to summarize a wide variety of research outcomes It is the foundation for
1. t-test 2. Analysis of Variance (ANOVA) 3. Analysis of Covariance (ANCOVA) 4.Regression analysis 5.Multivariate methods including factor analysis, cluster analysis, multidimensional scaling, discriminant function analysis, canonical correlation
y = b0 + bx + e: The straight-line model y = a set of outcome variablesx = a set of pre-test variables or covariatesb0 = the set of intercepts (value of each y when each x=0)b = a set of coefficients, one each for each x
e=vertical distance from the straight line to each point Z: regression analysis utilizes a dummy variable for treatment
General: in general[G]Model: an equation[M]Linear: An equation represented as line using bivariate or multivariate plot[L]Regression: The extent of agreement of pre and post test result(variable ) on a line of equationregression analysis:the result
Keywords
Regression line :The line in clouds [scattered variables]
Control
Treatment
b1=β1=the slope
Linearity
e: vertical distance from the straight line to each point. This term is called "error" because it is the degree to which the line is in error in describing each point
Posttest-Only Analysis[two-group posttest-only randomized experimental design]Two groups A post-only measure Two distributions (measures), each with an average and variation Assess treatment effect = statistical (i.e. non-chance) difference between the groups
3 ways to estimate Posttest-Only Analysis
T-test
ANOVA
Same result
ANCOVA
T-testANOVA[one-way Analysis of Variance ]ANCOVA[regression analysis ]:most general
Posttest-Only Analysis result by t-test
Posttest-Only Analysis result by regression
in the statistical model yi is the same as y in the straight line formula, β0 is the same as b, b1 is the same as m, and Zi is the same as x. In other words, in the statistical formula, b0 is the intercept and b1 is the slope.
Factorial Design Analysis:2x2
It is a regression analysis Ingredients from 2x2 factorial table A dummy variable (represented by a Z) for each factor Two main effects and one interaction Main effects are the statistics associated with the beta values that are adjacent to the Z-variables The interaction effect is the statistic associated with b3 (i.e., the t-value for this coefficient)
Randomized Block Analysis A regression analysis
Analysis of Covariance=mx[linear regression]ANOVA[one-way Analysis of Variance ]ANCOVA[one-way Analysis of Covariance ]
Non-equivalent Groups Analysis http://www.socialresearchmethods.net/kb/statnegd.php
Regression-Discontinuity Analysis http://www.socialresearchmethods.net/kb/statrd.php
Regression Point Displacement Analysis Requires A posttest score A pretest score A variable to represent the treatment group (where 0=comparison &1=treatment)Identical to the requirements for the ANCOVA except RPD design has a single treated group scoreThe model we'll use is the Analysis of Covariance (ANCOVA) model
Regression Point Displacement Analysis
Goal is to estimate the size of the vertical displacement of the treated unit from the regression line of all of the control units, indicated on the graph by the dashed arrow. The figure shows a bivariate (pre-post) distribution for a hypothetical RPD design of a community-based AIDS education program. The new AIDS education program is piloted in one particular county in a state, with the remaining counties acting as controls. The state routinely publishes annual HIV positive rates by county for the entire state. The x-values show the HIV-positive rates per 1000 people for the year preceding the program while the y-values show the rates for the year following it.
Analysis of Covariance (ANCOVA) model
The cost of this ppt.YOU CAN IMPROVE BY No plastic use Going through links given in this ppt,teachers, friends and workshops interested in statistics