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梅斯医学MedSci APP
医路相伴,成就大医
具体做法,采用广义因素分析过程,即采用广义线性模型(General Linear
Models)模块的一个子模块,用于分析多个因素(变量)对一个因素(反应变量)的影响,包含了一般的方差分析内容,如完全随机设计资料的方差分析
(one way ANOVA),随机单位组设计资料的方差分析(two-way ANOVA),拉丁方设计资料的方差分析(three-way
ANOVA),析因分析(factorial analysis),交叉设计(cross-over design),正交设计(orthogonal
design),裂区设计(split-plot
design)资料的方差分析,协方差分析,重复测量数据的方差分析等。在SPSS新版本中,Two-way
Anova分析即采用广义线性模型(General Linear Models)进行分析。具体步骤如下:
The two-way ANOVA compares the mean differences between groups that have been split on two independent variables (called factors). You need two independent, categorical variables and one continuous, dependent variable (see our guide on Types of Variable).
A researcher was interested in whether an individual's interest in politics was influenced by their level of education and their gender. They recruited a random sample of participants to their study and asked them about their interest in politics, which they scored from 0 - 100 with higher scores meaning a greater interest. The researcher then divided the participants by gender (Male/Female) and then again by level of education (School/College/University).
In SPSS we separated the individuals into their appropriate groups by using two columns representing the two independent variables and labelled them "Gender" and "Edu_Level". For "Gender", we coded males as "1" and females as "2", and for "Edu_Level", we coded school as "1", college as "2" and university as "3". The participants interest in politics was entered under the variable name, "Int_Politics". To know how to correctly enter your data into SPSS in order to run a two-way ANOVA, please read our Entering Data in SPSS tutorial, where there is a specific example. The data setup can be seen in the diagram below (click image to see full data set). We have given our data text labels (see our Working with Variables guide).
Published with written permission from SPSS Inc, an IBM Company.
To determine whether your dependent variable is normally distributed for each combination of the levels of the two independent variables see our Testing for Normality guide that runs through how to test for normality using SPSS using a specific two-way ANOVA example. In SPSS, homogeneity of variances is tested using Levene's Test for Equality of Variances. This is included in the main procedure for running the two-way ANOVA, so we get to evaluate whether there is homogeneity of variances at the same time as we get the results from the two-way ANOVA.
Published with written permission from SPSS Inc, an IBM Company.
Published with written permission from SPSS Inc, an IBM Company.
button. If you are using older versions of SPSS you
will need to use the former method. The result is shown below:
[For this analysis you will not need to worry about the "Random Factor(s):", "Covariate(s):" or "WLS Weight:" boxes.]
Published with written permission from SPSS Inc, an IBM Company.
button. You will be presented with the "Univariate:
Profile Plots" dialogue box:
Published with written permission from SPSS Inc, an IBM Company.
[Tip: Put the independent variable with the greater number of levels in the "Horizontal Axis:" box.]
Published with written permission from SPSS Inc, an IBM Company.
You will see that "Edu_Level*Gender" has been added to the "Plots:" box.
button. This will return you to the "Univariate"
dialogue box.
button. You will be presented with the "Univariate:
Post Hoc Multiple Comparisons for Observed..." dialogue box as
shown below:
Published with written permission from SPSS Inc, an IBM Company.
Transfer "Edu_Level" from the "Factor(s):" box to the "Post Hoc Tests for:" box. This will make the "Equal Variances Assumed" section become active (loose the "grey sheen") and present you with some choices for which post-hoc test to use. For this example, we are going to select "Tukey", which is a good, all-round post-hoc test.
[You only need to transfer independent variables that have more than two levels into the "Post Hoc Tests for:" box. This is why we do not transfer "Gender".]
You will finish up with the following screen:
Published with written permission from SPSS Inc, an IBM Company.
button to return to the "Univariate" dialogue
box.
button. This will present you with the "Univariate:
Options" dialogue box as shown below:
Published with written permission from SPSS Inc, an IBM Company.
Published with written permission from SPSS Inc, an IBM Company.
Click the button to return to the "Univariate" dialogue
box.
button to generate the output.SPSS produces many tables in its output from a two-way ANOVA and we are going to start with the "Descriptives" table as shown below:
Published with written permission from SPSS Inc, an IBM Company.
This table is very useful as it provides the mean and standard deviation for the groups that have been split by both independent variables. In addition, the table also provides "Total" rows, which allows means and standard deviations for groups only split by one independent variable or none at all to be known.
The next table to look at is Levene's Test of Equality of Error Variances as shown below:
Published with written permission from SPSS Inc, an IBM Company.
From this table we can see that we have homogeneity of variances of the dependent variable across groups. We know this as the Sig. value is greater than 0.05, which is the level we set for alpha. If the Sig. value had been less than 0.05 then we would have concluded that the variance across groups was significantly different (unequal).
This table shows the actual results of the two-way ANOVA as shown below:
Published with written permission from SPSS Inc, an IBM Company.
We are interested in the Gender, Edu_Level and Gender*Edu_Level rows of the table as highlighted above. These rows inform us of whether we have significant mean differences between our groups for our two independent variables, Gender and Edu_Level, and for their interaction, Gender*Edu_Level. We must first look at the Gender*Edu_Level interaction as this is the most important result we are after. We can see from the Sig. column that we have a statistically significant interaction at the P = .014 level. You may wish to report the results of Gender and Edu_Level as well. We can see from the above table that there was no significant difference in interest in politics between Gender (P = .207) but there were significant differences between educational levels (P < .0005).
This table shows the Tukey post-hoc test results for the different levels of education as shown below:
Published with written permission from SPSS Inc, an IBM Company.
We can see form the above table that there is some repetition of the results but, regardless of which row we choose to read from, we are interested in the differences between (1) School and College, (2) School and University, and (3) College and University. From the results we can see that there is a significant difference between all three different combinations of educational level (P < .0005).
The following plot is not of sufficient quality to present in your reports but provides a good graphical illustration of your results. In addition, we can get an idea of whether there is an interaction effect by inspecting whether the lines are parallel or not.
Published with written permission from SPSS Inc, an IBM Company.
From this plot we can see how our results from the previous table might make sense. Remember that if the lines are not parallel then there is the possibility of an interaction taking place.
You can follow up the results of a significant interaction effect by running tests for simple main effects - that is, the mean difference in interest in politics between genders at each education level. SPSS does not allow you to do this using the graphical interface you will be familiar with, but requires you to use syntax. We explain how to do this below:
Published with written permission from SPSS Inc, an IBM Company.
Published with written permission from SPSS Inc, an IBM Company.
[Depending on the version of SPSS you are using you might have
suggestion boxes appear when you type in SPSS-recognised commands,
such as, UNIANOVA. If you are familiar with using this type of
auto-prediction then please feel free to do so, but otherwise
simply ignore the pop-up suggestions and keep typing
normally.](在SPSS
16中,你只管如下图右框显示输入命令,然后点击上面菜单中的Run-all,结果就输出了
)
Published with written permission from SPSS Inc, an IBM Company.
Basically, all text you see above that is in CAPITALS, is required by SPSS and does not change when you enter your own data. Non-capitalised text represents your variables and will change when you use your own data. Breaking it all down, we have:
| UNIANOVA | Tells SPSS to use the Univariate Anova command |
| Int_Politics BY Gender Edu_Level | Your dependent variable BY your two independent variables (with a space between them) |
| /EMMEANS | Tells SPSS to calculate estimated marginal means |
| TABLES(Gender*Edu_Level) | Generate statistics for the interaction term. Put your two independent variables here, separated by a * to denote an interaction |
| COMPARE(Gender) | Tells SPSS to compare the interaction term between genders |
button, which will run the syntax you have typed.
Your results should appear in the Output Viewer below the results
you have already generated.The table you are interested in is the Univariate Tests table:
Published with written permission from SPSS Inc, an IBM Company.
This table shows us whether there are statistical differences in mean political interest between gender for each educational level. We can see that there are no statistically significant mean differences between male and females' interest in politics when individuals are educated to school (P = .465) or college level (P = .793). However, when individuals are educated to University level, there are significant differences between males and females' interest in politics (P = .002).
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