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<h1 class="title toc-ignore">Logistic Regression</h1>

</div>


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<p>Regression for a qualitative binary response variable <span
class="math inline">\((Y_i = 0\)</span> or <span
class="math inline">\(1)\)</span>. The explanatory variables can be
either quantitative or qualitative.</p>
<hr />
<div id="simple-logistic-regression-model"
class="section level2 tabset tabset-pills tabset-fade">
<h2 class="tabset tabset-pills tabset-fade">Simple Logistic Regression
Model</h2>
<div style="float:left;width:125px;" align="center">
<p><img src="Images/BinomYQuantX.png" width=58px;></p>
</div>
<p>Regression for a qualitative binary response variable <span
class="math inline">\((Y_i = 0\)</span> or <span
class="math inline">\(1)\)</span> using a single (typically
quantitative) explanatory variable.</p>
<div id="overview" class="section level3">
<h3>Overview</h3>
<div style="padding-left:125px;">
<p>The probability that <span class="math inline">\(Y_i = 1\)</span>
given the observed value of <span class="math inline">\(x_i\)</span> is
called <span class="math inline">\(\pi_i\)</span> and is modeled by the
equation</p>
<div
style="float:right;font-size:.8em;background-color:lightgray;padding:5px;border-radius:4px;">
<a style="color:darkgray;" href="javascript:showhide('simplelogisticlatexrcode')">Math
Code</a>
</div>
<div id="simplelogisticlatexrcode" style="display:none;">
<pre><code>$$
  P(Y_i = 1|\, x_i) = \frac{e^{\beta_0 + \beta_1 x_i}}{1+e^{\beta_0 + \beta_1 x_i}} = \pi_i
$$</code></pre>
</div>
<center>
<span class="tooltipr"> <span class="math inline">\(P(\)</span> <span
class="tooltiprtext">The "P" stands for "Probability that..."</span>
</span><span class="tooltipr"> <span class="math inline">\(Y_i\)</span>
<span class="tooltiprtext">The response variable. The "i" denotes that
this is the y-value for individual "i", where "i" is 1, 2, 3,... and so
on up to <span class="math inline">\(n\)</span>, the sample size.</span>
</span><span class="tooltipr"> <span class="math inline">\(= 1\)</span>
<span class="tooltiprtext">Equals 1... This states that we are assuming
that the probability that the response variable <span
class="math inline">\(Y_i\)</span> is a 1 for the current
individual.</span> </span><span class="tooltipr"> <span
class="math inline">\(| x_i)\)</span> <span class="tooltiprtext">Given
<span class="math inline">\(x_i\)</span>... in other words, the "|" says
"given" and <span class="math inline">\(x_i\)</span> means the x-value
of the current individual.</span> </span><span class="tooltipr"> <span
class="math inline">\(=\)</span> <span class="tooltiprtext">Equals
sign.</span> </span><span class="tooltipr"> <span
class="math inline">\(\displaystyle\frac{e^{\beta_0 + \beta_1 x_i}}{1 +
e^{\beta_0 + \beta_1 x_i}}\)</span> <span class="tooltiprtext">The
logistic regression equation where <span
class="math inline">\(e=2.71828...\)</span> is the "natural constant"
number and <span class="math inline">\(\beta_0\)</span> is the
y-intercept and <span class="math inline">\(\beta_1\)</span> is teh
slope.</span> </span><span class="tooltipr"> <span
class="math inline">\(= \pi_i\)</span> <span class="tooltiprtext">The
<span class="math inline">\(\pi_i\)</span> stands for the probability of
individual <span class="math inline">\(i\)</span> having a y-value equal
to 1 given their <span class="math inline">\(x_i\)</span> value. It is
the short hand notation for <span class="math inline">\(P(Y_i = 1
|x_i)\)</span>. (It is NOT the number 3.14...)</span> </span>
</center>
<p><br/></p>
<p>The coefficents <span class="math inline">\(\beta_0\)</span> and
<span class="math inline">\(\beta_1\)</span> are difficult to interpret
directly. Typicall <span class="math inline">\(e^{\beta_0}\)</span> and
<span class="math inline">\(e^{\beta_1}\)</span> are interpreted
instead. The value of <span class="math inline">\(e^{\beta_0}\)</span>
or <span class="math inline">\(e^{\beta_1}\)</span> denotes the relative
change in the odds that <span class="math inline">\(Y_i=1\)</span>. The
odds that <span class="math inline">\(Y_i=1\)</span> are <span
class="math inline">\(\frac{\pi_i}{1-\pi_i}\)</span>.</p>
<hr />
<p><strong>Examples:</strong> <a
href="./Analyses/Logistic%20Regression/Examples/challengerLogisticReg.html">challenger</a>
| <a
href="./Analyses/Logistic%20Regression/Examples/mouseLogisticReg.html">mouse</a></p>
<hr />
</div>
</div>
<div id="r-instructions" class="section level3">
<h3>R Instructions</h3>
<div style="padding-left:125px;">
<p><strong>Console</strong> Help Command: <code>?glm()</code></p>
<div id="perform-a-logistic-regression" class="section level4">
<h4>Perform a Logistic Regression</h4>
<a href="javascript:showhide('logistic1')">
<div class="hoverchunk">
<p><span class="tooltipr"> YourGlmName <span class="tooltiprtext">This
is some name you come up with that will become the R object that stores
the results of your logistic regression <code>glm()</code>
command.</span> </span><span class="tooltipr">  &lt;-  <span
class="tooltiprtext">This is the "left arrow" assignment operator that
stores the results of your <code>glm()</code> code into
<code>YourGlmName</code>.</span> </span><span class="tooltipr"> glm(
<span class="tooltiprtext">glm( is an R function that stands for
"General Linear Model". It works in a similar way that the
<code>lm(</code> function works except that it requires a
<code>family=</code> option to be specified at the end of the
command.</span> </span><span class="tooltipr"> Y  <span
class="tooltiprtext">Y is your binary response variable. It must consist
of only 0's and 1's. Since TRUE's = 1's and FALSE's = 0's in R, Y could
be a logical statement like (Price &gt; 100) or (Animal == "Cat") if
your Y-variable wasn't currently coded as 0's and 1's.</span>
</span><span class="tooltipr"> ~  <span class="tooltiprtext">The tilde
symbol ~ is used to tell R that Y should be treated as a function of the
explanatory variable X.</span> </span><span class="tooltipr"> X, <span
class="tooltiprtext">X is the explanatory variable (typically
quantitative) that will be used to explain the probability that the
response variable Y is a 1.</span> </span><span class="tooltipr">  data
= NameOfYourDataset,<br />
<span class="tooltiprtext">NameOfYourDataset is the name of the dataset
that contains Y and X. In other words, one column of your dataset would
be called Y and another column would be called X.</span> </span><span
class="tooltipr">  family=binomial) <span class="tooltiprtext">The
family=binomial command tells the <code>glm(</code> function to perform
a logistic regression. It turns out that <code>glm</code> can perform
many different types of regressions, but we only study it as a tool to
perform a logistic regression in this course.</span> </span><br/><span
class="tooltipr"> summary(YourGlmName) <span class="tooltiprtext">The
<code>summary</code> command allows you to print the results of your
logistic regression that were previously saved in
<code>YourGlmName</code>.</span> </span></p>
</div>
<p></a></p>
<div id="logistic1" style="display:none;">
<p>Example output from a regression. Hover each piece to learn more.</p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Call:<br/> glm(formula = am ~ disp, family =
binomial, data = mtcars) <span class="tooltiprouttext">This is simply a
statement of your original glm(...) "call" that you made when performing
your regression. It allows you to verify that you ran what you thought
you ran in the glm(...).</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td colspan="2">
<span class="tooltiprout"> Deviance Residuals: <span
class="tooltiprouttext">Deviance residuals are a measure of how far the
fitted probability for <span class="math inline">\(\pi_i\)</span> has
differed from the actual outcome of <span
class="math inline">\(Y_i\)</span> in terms of the log of the fitted
probability space. (This is a fairly complicated idea.) </span>
</td>
</tr>
<tr>
<td align="right">
<span class="tooltiprout"> Min<br/>   -1.5651 <span
class="tooltiprouttext">"min" gives the value of the residual that is
furthest below the regression line. Ideally, the magnitude of this value
would be about equal to the magnitude of the largest positive residual
(the max) because the hope is that the residuals are normally
distributed around the line.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 1Q<br/>   -0.6648 <span
class="tooltiprouttext">"1Q" gives the first quartile of the residuals,
which will always be negative, and ideally would be about equal in
magnitude to the third quartile.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> Median<br/>   -0.2460 <span
class="tooltiprouttext">"Median" gives the median of the residuals,
which would ideally would be about equal to zero. Note that because the
regression line is the least squares line, the mean of the residuals
will ALWAYS be zero, so it is never included in the output summary. This
particular median value of -0.2460 is a little smaller than zero than we
would hope for and suggests a right skew in the data because the mean
(0) is greater than the median (-0.2460) witnessing the residuals are
right skewed. This can also be seen in the maximum being much larger in
magnitude than the minimum.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 3Q<br/>   0.7276 <span
class="tooltiprouttext">"3Q" gives the third quartile of the residuals,
which would ideally would be about equal in magnitude to the first
quartile. In this case, it is pretty close, which helps us see that the
first quartile of residuals on either side of the line is behaving
fairly normally.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> Max</br>   2.2691 <span
class="tooltiprouttext">"Max" gives the maximum positive residuals,
which would ideally would be about equal in magnitude to the minimum
residual. In this case, it is much larger than the minimum, which helps
us see that the residuals are likely right skewed.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td colspan="2">
<span class="tooltiprout"> Coefficients: <span
class="tooltiprouttext">Notice that in your glm(...) you used only <span
class="math inline">\(Y\)</span> and <span
class="math inline">\(X\)</span>. You did type out any coefficients,
i.e., the <span class="math inline">\(\beta_0\)</span> or <span
class="math inline">\(\beta_1\)</span> of the regression model. These
coefficients are estimated by the glm(...) function and displayed in
this part of the output along with standard errors, t-values, and
p-values.</span> </span>
</td>
</tr>
<tr>
<td align="left">
</td>
<td align="right">
<span class="tooltiprout">   Estimate <span class="tooltiprouttext">To
learn more about the "Estimates" of the "Coefficients" see the
"Explanation" tab, "Estimating the Model Parameters" section for
details.</span>
</td>
<td align="right">
<span class="tooltiprout">   Std. Error <span class="tooltiprouttext">To
learn more about the "Standard Errors" of the "Coefficients" see the
"Explanation" tab, "Inference for the Model Parameters" section.</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   z value <span class="tooltiprouttext">The
test statistic is a regular old z-score. It is most reliable when the
sample size is "large." It is a measurement of the number of standard
errors the estimate is from 0.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   Pr(&gt;|z|) <span
class="tooltiprouttext">This is the p-value, the probability of
observing a test statistic more extreme than Z. </span> </span>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> (Intercept) <span
class="tooltiprouttext">This always says "Intercept" for any glm(...)
you run in R. That is because R always assumes there is a y-intercept
for your regression function.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   2.630849 <span class="tooltiprouttext">This
is the estimate of the y-intercept, <span
class="math inline">\(\beta_0\)</span>. It is called <span
class="math inline">\(b_0\)</span>. It is the value of the log of the
odds that <span class="math inline">\(Y_i=1\)</span> when <span
class="math inline">\(x_i\)</span> is zero. Remember to use <span
class="math inline">\(e^{b_0}\)</span> to interpret this values actual
effect on the odds.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   1.050170 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_0\)</span>. It
tells you how much <span class="math inline">\(b_0\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 2.505 <span class="tooltiprouttext">The test
statistic for testing the hypothesis that <span
class="math inline">\(\beta_0 = 0\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.01224 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_0 = 0\)</span>. It measures the probability
of observing a z-score as extreme as the one observed. To compute it
yourself in R, use <code>pnorm(-abs(your z-value))*2</code>.</span>
</span>
</td>
<td align="left">
<span class="tooltiprout"> * <span class="tooltiprouttext">This is
called a "star". One star means significant at the 0.1 level of <span
class="math inline">\(\alpha\)</span>.</span> </span>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> disp <span class="tooltiprouttext">This is
always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   -0.014604 <span
class="tooltiprouttext">This is the estimate of the slope, <span
class="math inline">\(\beta_1\)</span>. It is called <span
class="math inline">\(b_1\)</span>. It is the change in the log of the
odds that <span class="math inline">\(Y_i = 1\)</span> as X is increased
by 1 unit. Remember to use <span class="math inline">\(e^{b_1}\)</span>
to compute the actual effect on the odds.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   0.005168 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_1\)</span>. It
tells you how much <span class="math inline">\(b_1\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> -2.826 <span class="tooltiprouttext">This is
the test statistic for testing the hypothesis that <span
class="math inline">\(\beta_1 = 0\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.00471 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_1 = 0\)</span>. To compute it yourself in R,
use <code>pnorm(-abs(your z-value))*2</code></span> </span>
</td>
<td align="left">
<span class="tooltiprout"> ** <span class="tooltiprouttext">This is
called a "star". Three stars means significant at the 0.001 level of
<span class="math inline">\(\alpha\)</span>.</span> </span>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span> --- </span>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Signif. codes: 0 ‘***’ 0.001 ‘**’ 0.01 ‘*’
0.05 ‘.’ 0.1 ‘ ’ 1 <span class="tooltiprouttext">These "codes" explain
what significance level the p-value is smaller than based on how many
"stars" * the p-value is labeled with in the Coefficients table
above.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> (Dispersion parameter for binomial family
taken to be 1) <span class="tooltiprouttext">This is a simplifying
assumption of the logistic regression. Overdispersion is a common
problem with logistic regression data, but is typically ignored. Unless
you become an expert in statistics, this is not something you need to
worry about.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout">   Null Deviance: <span
class="tooltiprouttext">The deviance of the null model. This is the
model that excludes any information from the x-variable, i.e., <span
class="math inline">\(\beta_1=0\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  43.230 <span class="tooltiprouttext"></span>
</span>
</td>
<td align="right">
<span class="tooltiprout">  on 31 degrees of freedom <span
class="tooltiprouttext">The residual degrees of freedom. The higher this
number, the more reliable the p-values will be from the logistic
regression.</span> </span>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Residual deviance: <span
class="tooltiprouttext">The sum of log of the squared residuals.
Essentially the resulting statistic of a goodness of fit test measuring
how well the data works with the logistic regression model. Using
pchisq(residual deviance, df residual deviance, lower.tail=FALSE) gives
the p-value for this goodness of fit test. However, the residual
deviance only follows a chi-squared distribution with df residual
deviance when there are many repeated x-values, and all x-values have at
least a few replicates.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  29.732 <span class="tooltiprouttext">This
can be calculated by <code>sum(log(myglm$res^2))</code>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  on 30 degrees of freedom <span
class="tooltiprouttext">This is <span class="math inline">\(n-p\)</span>
where <span class="math inline">\(n\)</span> is the sample size and
<span class="math inline">\(p\)</span> is the number of parameters in
the regression model. In this case, there is a sample size of 32 and two
parameters, <span class="math inline">\(\beta_0\)</span> and <span
class="math inline">\(\beta_1\)</span>, so 32-2 = 30.</span> </span>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> AIC: <span class="tooltiprouttext">As stated
in the R Help file for ?glm, "A version of Akaike's An Information
Criterion..." The AIC is useful for comparing different models for the
same Y-variable. The glm model with the lowest AIC (which can go
negative) is the best model.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  33.732 <span class="tooltiprouttext">The AIC
for this particular model is 33.732. So if a different model (using the
same Y-variable as this model) can get a lower AIC, it is a better
model.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Number of Fisher Scoring iterations: <span
class="tooltiprouttext">If you have taken a class in Numerical Analysis,
this tells you how many iterations of the maximization algorithm were
required before converging to the "Estimates" of the parameters <span
class="math inline">\(\beta_0\)</span> and <span
class="math inline">\(\beta_1\)</span> found in the summary.</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">  5 <span class="tooltiprouttext">This
implementation of glm required 5 Fisher Scoring iterations to converge.
Fewer iterations hints that the model is a better fit than when many
iterations are required.</span> </span>
</td>
</tr>
</table>
</div>
<p><br/></p>
</div>
<div id="diagnose-the-goodness-of-fit" class="section level4">
<h4>Diagnose the Goodness-of-Fit</h4>
<p>There are two ways to check the <strong>goodness of fit</strong> of a
logistic regression model.</p>
<div style="padding-left:25px;">
<p><strong>Option 1</strong>: Hosmer-Lemeshow Goodness-of-Fit Test (Most
Common)</p>
<p>To check the <strong>goodness of fit</strong> of a logistic
regression model where there are <strong>few or no replicated <span
class="math inline">\(x\)</span>-values</strong> use the Hosmer-Lemeshow
Test.</p>
<a href="javascript:showhide('goodnessoffit2')">
<div class="hoverchunk">
<p><span class="tooltipr"> library(ResourceSelection) <span
class="tooltiprtext">This loads the ResourceSelection R package so that
you can access the hoslem.test() function. You may need to run the code:
install.packages("ResourceSelection") first.</span> </span><br/><span
class="tooltipr"> hoslem.test( <span class="tooltiprtext">This R
function performs the Hosmer-Lemeshow Goodness of Fit Test. See the
"Explanation" file to learn about this test.</span> </span><span
class="tooltipr"> YourGlmName <span
class="tooltiprtext"><code>YourGlmName</code> is the name of your
glm(...) code that you created previously.</span> </span><span
class="tooltipr"> $y,  <span class="tooltiprtext">ALWAYS type a "y"
here. This gives you the actual binary (0,1) y-values of your logistic
regression. The goodness of fit test will compare these actual values to
your predicted probabilities for each value in order to see if the model
is a "good fit."</span> </span><span class="tooltipr"> YourGlmName <span
class="tooltiprtext"><code>YourGlmName</code> is the name you used to
save the results of your glm(...) code.</span> </span><span
class="tooltipr"> $fitted,  <span class="tooltiprtext">ALWAYS type
"fitted" here. This gives you the fitted probabilities <span
class="math inline">\(\pi_i\)</span> of your logistic regression.</span>
</span><span class="tooltipr"> g=10) <span class="tooltiprtext">The
"g=10" is the default option for the value of g. The g is the number of
groups to run the goodness of fit test on. Just leave it at 10 unless
you are told to do otherwise. Ask your teacher for more information if
you are interested.</span> </span></p>
</div>
<p></a></p>
<div id="goodnessoffit2" style="display:none;">
<pre><code>## 
##  Hosmer and Lemeshow goodness of fit (GOF) test
## 
## data:  myglm$y, myglm$fitted
## X-squared = 5.7327, df = 8, p-value = 0.6771</code></pre>
<p>Note that the null hypothesis of the goodness-of-fit test is that
"the logistic regression is a good fit." So we actually don't want to
"reject the null" in this case. So a large p-value here means our
logistic regression fits the data satisfactorily. A small p-value
implies a poor fit and the results of the logistic regression should not
be fully trusted.</p>
</div>
<p><br/></p>
<p><strong>Option 2</strong>: Deviance Goodness-of-fit Test (Less
Common)</p>
<p>In some cases, there are <strong>many replicated <span
class="math inline">\(x\)</span>-values</strong> for
<strong>all</strong> x-values, i.e., each value of x is repeated more
than 50 times. Though this is rare, it is good to use the <em>deviance
goodness-of-fit test</em> whenever this happens.</p>
<a href="javascript:showhide('goodnessoffit1')">
<div class="hoverchunk">
<p><span class="tooltipr"> pchisq( <span class="tooltiprtext">The
<code>pchisq</code> command allows you to compute p-values from the
chi-squared distribution.</span> </span><span class="tooltipr"> residual
deviance,  <span class="tooltiprtext">The residual deviance is shown at
the bottom of the output of your <code>summary(YourGlmName)</code> and
should be typed in here as a number like 25.3.</span> </span><span
class="tooltipr"> df for residual deviance,  <span
class="tooltiprtext">The df for the residual deviance is also shown at
the bottom of the output of your
<code>summary(YourGlmName)</code>.</span> </span><span class="tooltipr">
lower.tail=FALSE) <span class="tooltiprtext">This command ensures you
find the probability of the chi-squared distribution being as extreme or
more extreme than the observed value of residual deviance.</span>
</span></p>
</div>
<p></a></p>
<div id="goodnessoffit1" style="display:none;">
<pre><code>## 
## Call:
## glm(formula = am ~ disp, family = binomial, data = mtcars)
## 
## Deviance Residuals: 
##     Min       1Q   Median       3Q      Max  
## -1.5651  -0.6648  -0.2460   0.7276   2.2691  
## 
## Coefficients:
##              Estimate Std. Error z value Pr(&gt;|z|)   
## (Intercept)  2.630849   1.050170   2.505  0.01224 * 
## disp        -0.014604   0.005168  -2.826  0.00471 **
## ---
## Signif. codes:  0 &#39;***&#39; 0.001 &#39;**&#39; 0.01 &#39;*&#39; 0.05 &#39;.&#39; 0.1 &#39; &#39; 1
## 
## (Dispersion parameter for binomial family taken to be 1)
## 
##     Null deviance: 43.230  on 31  degrees of freedom
## Residual deviance: 29.732  on 30  degrees of freedom
## AIC: 33.732
## 
## Number of Fisher Scoring iterations: 5</code></pre>
<pre><code>## [1] 0.479439</code></pre>
<p>The null hypothesis of the goodness-of-fit test is that the logistic
regression is a good fit of the data. So a large p-value (like 0.479) is
good because it allows us to trust the results of our logistic
regression. When the p-value becomes very small, we must "reject the
null" and conclude a poor fit, which implies that we should not trust
the results of the logistic regression.</p>
</div>
</div>
<p><br/></p>
</div>
<div id="plot-the-regression" class="section level4">
<h4>Plot the Regression</h4>
<div class="tab">
<p><button class="tablinks" onclick="openTab(event, 'LogisticBaseplot')">Base
R</button>
<button class="tablinks" onclick="openTab(event, 'Logisticggplot')">ggplot2</button></p>
</div>
<div id="LogisticBaseplot" class="tabcontent">
<p>
<a href="javascript:showhide('LogisticBaseplot2')">
<div class="hoverchunk">
<p><span class="tooltipr"> plot( <span class="tooltiprtext">The plot
function allows us to draw a scatterplot where the y-axis is only 0's or
1's and the x-axis is quantitative.</span> </span><span
class="tooltipr"> Y <span class="tooltiprtext">Y should be some logical
statement like Fail &gt; 0 or sex == "B" or height &lt; 68. In other
words, Y needs to be a collection of 0's and 1's.</span> </span><span
class="tooltipr">  ~  <span class="tooltiprtext">The tilde is read "Y on
X."</span> </span><span class="tooltipr"> X, <span
class="tooltiprtext">X is some quantitative variable.</span>
</span><span class="tooltipr">  data= <span class="tooltiprtext">Tell
the plot which data set to use. X and Y are columns of that data
set.</span> </span><span class="tooltipr"> YourDataSet <span
class="tooltiprtext">The name of your data set.</span> </span><span
class="tooltipr"> ) <span class="tooltiprtext">Closing parenthesis for
plot(...) function.</span> </span><br/><span class="tooltipr"> curve(
<span class="tooltiprtext">A function in R that draws a "curve" on a
plot. Using add=TRUE puts the curve onto the current plot.</span>
</span><span class="tooltipr"> exp( <span class="tooltiprtext">This
allows you to compute e to the power of something. So exp(1) = e, exp(2)
= e^2 and so on.</span> </span><span class="tooltipr"> <span
class="math inline">\(b_0\)</span> + <span class="tooltiprtext">This is
the "Intercept" estimate from your logistic regression summary
output.</span> </span><span class="tooltipr">  <span
class="math inline">\(b_1\)</span> <span class="tooltiprtext">This is
the slope estimate from your logistic regression summary output.</span>
</span><span class="tooltipr"> *x <span class="tooltiprtext">The curve
function demands you ALWAYS use a lower-case "x" in this
function.</span> </span><span class="tooltipr"> ) <span
class="tooltiprtext">Closing parenthesis.</span> </span><span
class="tooltipr"> / <span class="tooltiprtext">The division
symbol.</span> </span><span class="tooltipr"> (1 + <span
class="tooltiprtext">Required for the formula.</span>
</span><span class="tooltipr">  exp(<span
class="math inline">\(b_0\)</span> + <span
class="math inline">\(b_1\)</span>*x) <span class="tooltiprtext">This
needs to match exactly the first version of this statement.</span>
</span><span class="tooltipr"> ), <span class="tooltiprtext">Closing
parenthesis for the denominator.</span> </span><span class="tooltipr">
 add = TRUE) <span class="tooltiprtext">This makes the curve be added to
the current plot. If it is left out, the curve will be drawn in a new
plot.</span> </span></p>
</div>
<p></a></p>
<div id="LogisticBaseplot2" style="display:none;">
<p><img src="LogisticRegression_files/figure-html/unnamed-chunk-4-1.png" width="672" /></p>
</div>
</p>
</div>
<div id="Logisticggplot" class="tabcontent">
<p>
<a href="javascript:showhide('Logisticggplot2')">
<div class="hoverchunk">
<p><span class="tooltipr"> ggplot( <span class="tooltiprtext">The
ggplot(...) function is used to create a basic ggplot frame.</span>
</span><span class="tooltipr"> data=YourDataSetName, <span
class="tooltiprtext">Use this to specify the name of your data
set.</span> </span><span class="tooltipr">  aes( <span
class="tooltiprtext">The aes(...) function stands for "aesthetics" and
tells the ggplot which variables to match up with the x-axis and y-axis
of the graph as well as other visual things like the type of plotting
characters, size of plotting characters, color, fill, and so on.</span>
</span><span class="tooltipr"> x=X, <span class="tooltiprtext">Use
x=nameOfYourXvariable to declare the x-axis of your graph.</span>
</span><span class="tooltipr"> y=Y <span class="tooltiprtext">Use
y=nameOfYourYvariable to declare the y-axis of your graph. If your
y-variable is a logical expression, like height&gt;60 then you must use
y=as.numeric(height&gt;60).</span> </span><span class="tooltipr"> )
<span class="tooltiprtext">Closing parenthesis for aes(...)
function.</span> </span><span class="tooltipr"> ) <span
class="tooltiprtext">Closing parenthesis for ggplot(...)
function.</span> </span><span class="tooltipr">  + <span
class="tooltiprtext">The plus sign adds a new layer to the
ggplot.</span> </span><br/><span class="tooltipr">   geom_point( <span
class="tooltiprtext">Tells the plot to add the physical geometry of
"points" to the plot.</span> </span><span class="tooltipr"> ) <span
class="tooltiprtext">Closing parenthesis for the geom_point()
function.</span> </span><span class="tooltipr">  + <span
class="tooltiprtext">Add another layer to the plot.</span>
</span><br/><span class="tooltipr">   geom_smooth( <span
class="tooltiprtext">Add a smoothing line to the graph.</span>
</span><span class="tooltipr"> method="glm", <span
class="tooltiprtext">This adds a general linear model to the
graph.</span> </span><span class="tooltipr"> method.args =
list(family="binomial"), <span class="tooltiprtext">This tells the
method="glm" to choose specifically the "binomial" model, otherwise
known as the "logistic regression" model.</span> </span><span
class="tooltipr">  se=FALSE <span class="tooltiprtext">Turn off the
displaying of the confidence band around the logistic regression. You
can turn this on if you know what it means.</span> </span><span
class="tooltipr"> ) <span class="tooltiprtext">Closing parenthesis for
the geom_smooth() function.</span> </span><span class="tooltipr">  +
<span class="tooltiprtext">Add another layer to the ggplot.</span>
</span><br/><span class="tooltipr">   theme_bw() <span
class="tooltiprtext">Give the graph a basic black and white theme. Other
themes are possible, see ?theme_ in your Console.</span> </span></p>
</div>
<p></a></p>
<div id="Logisticggplot2" style="display:none;">
<pre><code>## `geom_smooth()` using formula = &#39;y ~ x&#39;</code></pre>
<p><img src="LogisticRegression_files/figure-html/unnamed-chunk-5-1.png" width="672" /></p>
</div>
</p>
</div>
<p><br/></p>
</div>
<div id="predict-probabilities" class="section level4">
<h4>Predict Probabilities</h4>
<p>To predict the probability that <span
class="math inline">\(Y_i=1\)</span> for a given <span
class="math inline">\(x\)</span>-value, use the code</p>
<a href="javascript:showhide('LogisticPredict')">
<div class="hoverchunk">
<p><span class="tooltipr"> predict( <span class="tooltiprtext">The
predict() function allows us to use the regression model that was
obtained from glm() to predict the probability that <span
class="math inline">\(Y_i = 1\)</span> for a given <span
class="math inline">\(X_i\)</span>.</span> </span><span
class="tooltipr"> YourGlmName,  <span
class="tooltiprtext"><code>YourGlmName</code> is the name of the object
you created when you performed your logistic regression using
glm().</span> </span><span class="tooltipr"> newdata =  <span
class="tooltiprtext">The <code>newdata =</code> command allows you to
specify the x-values for which you want to obtain predicted
probabilities that <span class="math inline">\(Y_i=1\)</span>.</span>
</span><span class="tooltipr"> data.frame(xVariableName =
someNumericValue),  <span class="tooltiprtext">The xVariableName is the
same one you used in your glm(y ~ x, ...) statement for "x". Input any
desired value for the "someNumericValue" spot. Then, the predict code
uses the logistic regression model equation to calculate a predicted
probability that <span class="math inline">\(Y_i = 1\)</span> for the
given <span class="math inline">\(x_i\)</span> value that you
specify.</span> </span><span class="tooltipr"> type = "response") <span
class="tooltiprtext">The type = "response" options specifies that you
want predicted probabilities. There are other options available. See
?predict.glm for details.</span> </span></p>
</div>
<p></a></p>
<div id="LogisticPredict" style="display:none;">
<div class="sourceCode" id="cb6"><pre class="sourceCode r"><code class="sourceCode r"><span id="cb6-1"><a href="#cb6-1" aria-hidden="true" tabindex="-1"></a>myglm <span class="ot">&lt;-</span> <span class="fu">glm</span>(am <span class="sc">~</span> disp, <span class="at">data =</span> mtcars, <span class="at">family =</span> binomial)</span>
<span id="cb6-2"><a href="#cb6-2" aria-hidden="true" tabindex="-1"></a><span class="fu">predict</span>(myglm, <span class="at">newdata =</span> <span class="fu">data.frame</span>(<span class="at">disp =</span> <span class="dv">200</span>), <span class="at">type =</span> <span class="st">&quot;response&quot;</span>)</span></code></pre></div>
<pre><code>##         1 
## 0.4280016</code></pre>
</div>
<hr />
</div>
</div>
</div>
<div id="explanation" class="section level3">
<h3>Explanation</h3>
<div style="padding-left:125px;">
<p>Simple Logistic Regression is used when</p>
<ul>
<li>the response variable is binary <span
class="math inline">\((Y_i=0\)</span> or <span
class="math inline">\(1)\)</span>, and</li>
<li>there is a single explanatory variable <span
class="math inline">\(X\)</span> that is typically quantitative but
could be qualitative (if <span class="math inline">\(X\)</span> is
binary or ordinal).</li>
</ul>
<div id="the-model" class="section level4">
<h4>The Model</h4>
<p>Since <span class="math inline">\(Y_i\)</span> is binary (can only be
0 or 1) the model focuses on describing the probability that <span
class="math inline">\(Y_i=1\)</span> for a given scenario. The
probability that <span class="math inline">\(Y_i = 1\)</span> given the
observed value of <span class="math inline">\(x_i\)</span> is called
<span class="math inline">\(\pi_i\)</span> and is modeled by the
equation</p>
<p><span class="math display">\[
  P(Y_i = 1|\, x_i) = \frac{e^{\beta_0 + \beta_1 x_i}}{1+e^{\beta_0 +
\beta_1 x_i}} = \pi_i
\]</span></p>
<p>The assumption is that for certain values of <span
class="math inline">\(X\)</span> the probability that <span
class="math inline">\(Y_i=1\)</span> is higher than for other values of
<span class="math inline">\(X\)</span>.</p>
</div>
<div id="interpretation" class="section level4">
<h4>Interpretation</h4>
<p>This model for <span class="math inline">\(\pi_i\)</span> comes from
modeling the <em>log of the odds</em> that <span
class="math inline">\(Y_i=1\)</span> using a linear regression, i.e.,
<span class="math display">\[
  \log\underbrace{\left(\frac{\pi_i}{1-\pi_i}\right)}_{\text{Odds for}\
Y_i=1} = \underbrace{\beta_0 + \beta_1 x_i}_{\text{linear regression}}
\]</span> Beginning to solve this equation for <span
class="math inline">\(\pi_i\)</span> leads to the intermediate, but
important result that <span class="math display">\[
    \underbrace{\frac{\pi_i}{1-\pi_i}}_{\text{Odds for}\ Y_i=1} =
e^{\overbrace{\beta_0 + \beta_1 x_i}^{\text{linear regression}}} =
e^{\beta_0}e^{\beta_1 x_i}
\]</span> Thus, while the coefficients <span
class="math inline">\(\beta_0\)</span> and <span
class="math inline">\(\beta_1\)</span> are difficult to interpret
directly, <span class="math inline">\(e^{\beta_0}\)</span> and <span
class="math inline">\(e^{\beta_1}\)</span> have a valuable
interpretation. The value of <span
class="math inline">\(e^{\beta_0}\)</span> is interpreted as the odds
for <span class="math inline">\(Y_i=1\)</span> when <span
class="math inline">\(x_i = 0\)</span>. It may not be possible for a
given model to have <span class="math inline">\(x_i=0\)</span>, in which
case <span class="math inline">\(e^{\beta_0}\)</span> has no
interpretation. The value of <span
class="math inline">\(e^{\beta_1}\)</span> denotes the proportional
change in the odds that <span class="math inline">\(Y_i=1\)</span> for
every one unit increase in <span class="math inline">\(x_i\)</span>.</p>
<p>Notice that solving the last equation for <span
class="math inline">\(\pi_i\)</span> results in the logistic regression
model presented at the beginning of this page.</p>
</div>
<div id="hypothesis-testing" class="section level4">
<h4>Hypothesis Testing</h4>
<p>Similar to linear regression, the hypothesis that <span
class="math display">\[
  H_0: \beta_1 = 0 \\
  H_a: \beta_1 \neq 0
\]</span> can be tested with a logistic regression. If <span
class="math inline">\(\beta_1 = 0\)</span>, then there is no
relationship between <span class="math inline">\(x_i\)</span> and the
log of the odds that <span class="math inline">\(Y_i = 1\)</span>. In
other words, <span class="math inline">\(x_i\)</span> is not useful in
predicting the probability that <span class="math inline">\(Y_i =
1\)</span>. If <span class="math inline">\(\beta_1 \neq 0\)</span>, then
there is information in <span class="math inline">\(x_i\)</span> that
can be utilized to predict the probability that <span
class="math inline">\(Y_i = 1\)</span>, i.e., the logistic regression is
meaningful.</p>
</div>
<div id="diagnostics" class="section level4">
<h4>Checking Model Assumptions</h4>
<p>The model assumptions are not as clear in logistic regression as they
are in linear regression. For our purposes we will focus only on
considering the goodness of fit of the logistic regression model. If the
model appears to fit the data well, then it will be assumed to be
appropriate.</p>
<div style="padding-left:15px;">
<div id="deviance-goodness-of-fit-test" class="section level5">
<h5>Deviance Goodness of Fit Test</h5>
<p>If there are replicated values of each <span
class="math inline">\(x_i\)</span>, then the deviance goodness of fit
test tests the hypotheses <span class="math display">\[
  H_0: \pi_i = \frac{e^{\beta_0 + \beta_1 x_i}}{1+e^{\beta_0 + \beta_1
x_i}}
\]</span> <span class="math display">\[
  H_a: \pi_i \neq \frac{e^{\beta_0 + \beta_1 x_i}}{1+e^{\beta_0 +
\beta_1 x_i}}
\]</span></p>
</div>
<div id="hosmer-lemeshow-goodness-of-fit-test" class="section level5">
<h5>Hosmer-Lemeshow Goodness of Fit Test</h5>
<p>If there are very few or no replicated values of each <span
class="math inline">\(x_i\)</span>, then the Hosmer-Lemeshow goodness of
fit test can be used to test these same hypotheses. In each case, the
null assumes that logistic regression is a good fit for the data while
the alternative is that logistic regression is not a good fit.</p>
</div>
</div>
</div>
<div id="prediction" class="section level4">
<h4>Prediction</h4>
<p>One of the great uses of Logistic Regression is that it provides an
estimate of the probability that <span
class="math inline">\(Y_i=1\)</span> for a given value of <span
class="math inline">\(x_i\)</span>. This probability is often referred
to as the <em>risk</em> that <span class="math inline">\(Y_i=1\)</span>
for a certain individual. For example, if <span
class="math inline">\(Y_i=1\)</span> implies a person has a disease,
then <span class="math inline">\(\pi_i=P(Y_i=1)\)</span> represents the
risk of individual <span class="math inline">\(i\)</span> having the
disease based on their value of <span
class="math inline">\(x_i\)</span>, perhaps a measure of their
cholesterol or some other predictor of the disease.</p>
</div>
</div>
<hr />
</div>
<div id="section" class="section level3">
<h3></h3>
<hr />
</div>
</div>
<div id="multiple-logistic-regression-model"
class="section level2 tabset tabset-pills tabset-fade">
<h2 class="tabset tabset-pills tabset-fade">Multiple Logistic Regression
Model</h2>
<div style="float:left;width:125px;" align="center">
<p><img src="Images/BinomYMultX.png" width=98px;></p>
</div>
<p>Logistic regression for multiple explanatory variables that can
either be quantitative or qualitative or a mixture of the two.</p>
<div id="overview-1" class="section level3">
<h3>Overview</h3>
<div style="padding-left:125px;">
<p>The probability that <span class="math inline">\(Y_i = 1\)</span>
given the observed data <span
class="math inline">\((x_{i1},\ldots,x_{ip})\)</span> is called <span
class="math inline">\(\pi_i\)</span> and is modeled by the equation</p>
<p><span class="math display">\[
  P(Y_i = 1|\, x_{i1},\ldots,x_{ip}) = \frac{e^{\beta_0 + \beta_1 x_{i1}
+ \ldots + \beta_p x_{ip}}}{1+e^{\beta_0 + \beta_1 x_{i1} + \ldots +
\beta_p x_{ip} }} = \pi_i
\]</span></p>
<p>The coefficents <span
class="math inline">\(\beta_0,\beta_1,\ldots,\beta_p\)</span> are
difficult to interpret directly. Typically <span
class="math inline">\(e^{\beta_k}\)</span> for <span
class="math inline">\(k=0,1,\ldots,p\)</span> is interpreted instead.
The value of <span class="math inline">\(e^{\beta_k}\)</span> denotes
the relative change in the odds that <span
class="math inline">\(Y_i=1\)</span>. The odds that <span
class="math inline">\(Y_i=1\)</span> are <span
class="math inline">\(\frac{\pi_i}{1-\pi_i}\)</span>.</p>
<hr />
<p><strong>Examples:</strong> <a
href="./Analyses/Logistic%20Regression/Examples/GSSMultipleLogisticReg.html">GSS</a></p>
<hr />
</div>
</div>
<div id="r-instructions-1" class="section level3">
<h3>R Instructions</h3>
<div style="padding-left:125px;">
<p><strong>Console</strong> Help Command: <code>?glm()</code></p>
<div id="perform-the-logistic-regression" class="section level4">
<h4>Perform the Logistic Regression</h4>
<p>To perform a logistic regression in R use the commands</p>
<a href="javascript:showhide('logistic2')">
<div class="hoverchunk">
<p><span class="tooltipr"> YourGlmName <span class="tooltiprtext">This
is some name you come up with that will become the R object that stores
the results of your logistic regression <code>glm()</code>
command.</span> </span><span class="tooltipr">  &lt;-  <span
class="tooltiprtext">This is the "left arrow" assignment operator that
stores the results of your <code>glm()</code> code into
<code>YourGlmName</code>.</span> </span><span class="tooltipr"> glm(
<span class="tooltiprtext">glm( is an R function that stands for
"General Linear Model". It works in a similar way that the
<code>lm(</code> function works except that it requires a
<code>family=</code> option to be specified at the end of the
command.</span> </span><span class="tooltipr"> Y  <span
class="tooltiprtext">Y is your binary response variable. It must consist
of only 0's and 1's. Since TRUE's = 1's and FALSE's = 0's in R, Y could
be a logical statement like (Price &gt; 100) or (Animal == "Cat") if
your Y-variable wasn't currently coded as 0's and 1's.</span>
</span><span class="tooltipr"> ~  <span class="tooltiprtext">The tilde
symbol ~ is used to tell R that Y should be treated as a function of the
explanatory variable X.</span> </span><span class="tooltipr"> X1 <span
class="tooltiprtext">X1 is the first explanatory variable (typically
quantitative) that will be used to explain the probability that the
response variable Y is a 1.</span> </span><span class="tooltipr"> *
<span class="tooltiprtext">The times symbol allows a shortcut for
writing X1 + X2 + X1:X2 = X1*X2.</span> </span><span class="tooltipr">
X2  <span class="tooltiprtext">X2 is second the explanatory variable
either quantitative or qualitative that will be used to explain the
probability that the response variable Y is a 1.</span> </span><span
class="tooltipr"> ..., <span class="tooltiprtext">In theory, you could
have many other explanatory variables, interaction terms, or even
squared, cubed, or other transformations of terms added to this
model.</span> </span><span class="tooltipr">  data =
NameOfYourDataset,<br />
<span class="tooltiprtext">NameOfYourDataset is the name of the dataset
that contains Y and X. In other words, one column of your dataset would
be called Y and another column would be called X.</span> </span><span
class="tooltipr">  family=binomial) <span class="tooltiprtext">The
family=binomial command tells the <code>glm(</code> function to perform
a logistic regression. It turns out that <code>glm</code> can perform
many different types of regressions, but we only study it as a tool to
perform a logistic regression in this course.</span> </span><br/><span
class="tooltipr"> summary(YourGlmName) <span class="tooltiprtext">The
<code>summary</code> command allows you to print the results of your
logistic regression that were previously saved in
<code>YourGlmName</code>.</span> </span></p>
</div>
<p></a></p>
<div id="logistic2" style="display:none;">
<p>Example output from a regression. Hover each piece to learn more.</p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Call:<br/> glm(formula = weight &gt; 100 ~
Time*Diet, family = binomial, data = ChickWeight) <span
class="tooltiprouttext">This is simply a statement of your original
glm(...) "call" that you made when performing your regression. It allows
you to verify that you ran what you thought you ran in the
glm(...).</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td colspan="2">
<span class="tooltiprout"> Deviance Residuals: <span
class="tooltiprouttext">Deviance residuals are a measure of how far the
fitted probability for <span class="math inline">\(\pi_i\)</span> has
differed from the actual outcome of <span
class="math inline">\(Y_i\)</span> in terms of the log of the fitted
probability space. (This is a fairly complicated idea.) </span>
</td>
</tr>
<tr>
<td align="right">
<span class="tooltiprout"> Min<br/>   -2.9446 <span
class="tooltiprouttext">"min" gives the value of the residual that is
furthest below the regression line. Ideally, the magnitude of this value
would be about equal to the magnitude of the largest positive residual
(the max) because the hope is that the residuals are normally
distributed around the line.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 1Q<br/>   -0.2364 <span
class="tooltiprouttext">"1Q" gives the first quartile of the residuals,
which will always be negative, and ideally would be about equal in
magnitude to the third quartile.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> Median<br/>   0.0000 <span
class="tooltiprouttext">"Median" gives the median of the residuals,
which would ideally would be about equal to zero. Note that because the
regression line is the least squares line, the mean of the residuals
will ALWAYS be zero, so it is never included in the output
summary.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 3Q<br/>   0.2776 <span
class="tooltiprouttext">"3Q" gives the third quartile of the residuals,
which would ideally would be about equal in magnitude to the first
quartile. In this case, it is pretty close, which helps us see that the
first quartile of residuals on either side of the line is behaving
fairly normally.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> Max</br>   1.9968 <span
class="tooltiprouttext">"Max" gives the maximum positive residuals,
which would ideally would be about equal in magnitude to the minimum
residual. In this case, it is much larger than the minimum, which helps
us see that the residuals are likely right skewed.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td colspan="2">
<span class="tooltiprout"> Coefficients: <span
class="tooltiprouttext">Notice that in your glm(...) you used only <span
class="math inline">\(Y\)</span> and <span
class="math inline">\(X\)</span>. You did type out any coefficients,
i.e., the <span class="math inline">\(\beta_0\)</span> or <span
class="math inline">\(\beta_1\)</span> of the regression model. These
coefficients are estimated by the glm(...) function and displayed in
this part of the output along with standard errors, t-values, and
p-values.</span> </span>
</td>
</tr>
<tr>
<td align="left">
</td>
<td align="right">
<span class="tooltiprout">   Estimate <span class="tooltiprouttext">To
learn more about the "Estimates" of the "Coefficients" see the
"Explanation" tab, "Estimating the Model Parameters" section for
details.</span>
</td>
<td align="right">
<span class="tooltiprout">   Std. Error <span class="tooltiprouttext">To
learn more about the "Standard Errors" of the "Coefficients" see the
"Explanation" tab, "Inference for the Model Parameters" section.</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   z value <span class="tooltiprouttext">The
Z-score testing the hypothesis that <span
class="math inline">\(\beta_j=0\)</span></span> </span>
</td>
<td align="right">
<span class="tooltiprout">   Pr(&gt;|z|) <span
class="tooltiprouttext">The p-value for the corresponding
Z-score.</span> </span>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> (Intercept) <span
class="tooltiprouttext">This always says "Intercept" for any glm(...)
you run in R. That is because R always assumes there is a y-intercept
for your regression function.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   -4.97603 <span class="tooltiprouttext">This
is the estimate of the y-intercept, <span
class="math inline">\(\beta_0\)</span>. It is called <span
class="math inline">\(b_0\)</span>. It is the average y-value when X is
zero.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   0.65316 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_0\)</span>. It
tells you how much <span class="math inline">\(b_0\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> -7.618 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_0\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 2.57e-14 <span class="tooltiprouttext">This
is the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_0 = 0\)</span>. It measures the probability
of observing a Z-value as extreme as the one observed. To compute it
yourself in R, use <code>pnorm(-abs(your z-value))*2</code>.</span>
</span>
</td>
<td align="left">
<span class="tooltiprout"> *** <span class="tooltiprouttext">This is
called a "star". Three stars means significant at the 0.01 level of
<span class="math inline">\(\alpha\)</span>.</span> </span>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> Time <span class="tooltiprouttext">This is
always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   0.39111 <span class="tooltiprouttext">This
is the estimate of the slope, <span
class="math inline">\(\beta_1\)</span>. It is called <span
class="math inline">\(b_1\)</span>. It is the change in the average
y-value as X is increased by 1 unit.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   0.04979 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_1\)</span>. It
tells you how much <span class="math inline">\(b_1\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 7.854 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_1\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 4.02e-15 <span class="tooltiprouttext">This
is the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_1 = 0\)</span>. To compute it yourself in R,
use <code>pt(-abs(your t-value), df of your regression)*2</code></span>
</span>
</td>
<td align="left">
<span class="tooltiprout"> *** <span class="tooltiprouttext">This is
called a "star". Three stars means significant at the 0.01 level of
<span class="math inline">\(\alpha\)</span>.</span> </span>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> Diet2 <span class="tooltiprouttext">This is
always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   0.58283 <span class="tooltiprouttext">This
is the estimate of the change in the intercept, <span
class="math inline">\(\beta_2\)</span>. It is called <span
class="math inline">\(b_2\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   1.04061 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_2\)</span>. It
tells you how much <span class="math inline">\(b_2\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.560 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_2\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.5754 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_2 = 0\)</span>. To compute it yourself in R,
use <code>pt(-abs(your t-value), df of your regression)*2</code></span>
</span>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> Diet3 <span class="tooltiprouttext">This is
always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   -8.44476 <span class="tooltiprouttext">This
is the estimate of the change in the intercept, <span
class="math inline">\(\beta_3\)</span>. It is called <span
class="math inline">\(b_3\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   4.32324 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_3\)</span>. It
tells you how much <span class="math inline">\(b_3\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> -1.953 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_3\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.0508 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_3 = 0\)</span>. To compute it yourself in R,
use <code>pt(-abs(your t-value), df of your regression)*2</code></span>
</span>
</td>
<td align="left">
<span class="tooltiprout"> . <span class="tooltiprouttext">This is
called a period. It means significant at the 0.1 level of <span
class="math inline">\(\alpha\)</span>.</span> </span>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> Diet4 <span class="tooltiprouttext">This is
always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   -67.41995 <span
class="tooltiprouttext">This is the estimate of the change in the
intercept, <span class="math inline">\(\beta_4\)</span>. It is called
<span class="math inline">\(b_4\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   3768.10023 <span
class="tooltiprouttext">This is the standard error of <span
class="math inline">\(b_4\)</span>. It tells you how much <span
class="math inline">\(b_4\)</span> varies from sample to sample. The
closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> -0.018 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_4\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.9857 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_2 = 0\)</span>. To compute it yourself in R,
use <code>pt(-abs(your t-value), df of your regression)*2</code></span>
</span>
</td>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> Time:Diet2 <span class="tooltiprouttext">This
is always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   0.02391 <span class="tooltiprouttext">This
is the estimate of the change in the slope, <span
class="math inline">\(\beta_5\)</span>. It is called <span
class="math inline">\(b_5\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   0.08679 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_5\)</span>. It
tells you how much <span class="math inline">\(b_5\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.275 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_5\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.7830 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_2 = 0\)</span>. To compute it yourself in R,
use <code>pt(-abs(your t-value), df of your regression)*2</code></span>
</span>
</td>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> Time:Diet3 <span class="tooltiprouttext">This
is always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   1.20955 <span class="tooltiprouttext">This
is the estimate of the change in the slope, <span
class="math inline">\(\beta_6\)</span>. It is called <span
class="math inline">\(b_6\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   0.51249 <span class="tooltiprouttext">This
is the standard error of <span class="math inline">\(b_6\)</span>. It
tells you how much <span class="math inline">\(b_6\)</span> varies from
sample to sample. The closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 2.360 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_6\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.0183 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_2 = 0\)</span>. To compute it yourself in R,
use <code>pt(-abs(your t-value), df of your regression)*2</code></span>
</span>
</td>
<td align="left">
<span class="tooltiprout"> * <span class="tooltiprouttext">This is
called a "star". One star means significant at the 0.05 level of <span
class="math inline">\(\alpha\)</span>.</span> </span>
</td>
</td>
</tr>
<tr>
<td align="left">
<span class="tooltiprout"> Time:Diet4 <span class="tooltiprouttext">This
is always the name of your X-variable in your glm(Y ~ X, ...).</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">   8.83168 <span class="tooltiprouttext">This
is the estimate of the change in the slope, <span
class="math inline">\(\beta_7\)</span>. It is called <span
class="math inline">\(b_7\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">   471.01259 <span
class="tooltiprouttext">This is the standard error of <span
class="math inline">\(b_7\)</span>. It tells you how much <span
class="math inline">\(b_7\)</span> varies from sample to sample. The
closer to zero, the better.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.019 <span class="tooltiprouttext">Z-score
for <span class="math inline">\(b_7\)</span>.</span> </span>
</td>
<td align="right">
<span class="tooltiprout"> 0.9850 <span class="tooltiprouttext">This is
the p-value of the test of the hypothesis that <span
class="math inline">\(\beta_2 = 0\)</span>. To compute it yourself in R,
use <code>pt(-abs(your t-value), df of your regression)*2</code></span>
</span>
</td>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span> --- </span>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Signif. codes: 0 ‘***’ 0.001 ‘**’ 0.01 ‘*’
0.05 ‘.’ 0.1 ‘ ’ 1 <span class="tooltiprouttext">These "codes" explain
what significance level the p-value is smaller than based on how many
"stars" * the p-value is labeled with in the Coefficients table
above.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> (Dispersion parameter for binomial family
taken to be 1) <span class="tooltiprouttext">A simplifying assumption of
the logistic regression. This can be changed if you know what you are
doing. See ?summary.glm and look at the dispersion option for details.
Unless you are pursuing an advanced degree in statistics, it is not
recommended that you explore this option.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout">   Null Deviance: <span
class="tooltiprouttext">The deviance of the null model.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  800.44 <span class="tooltiprouttext">In this
case, the null deviance is 800.44</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  on 577 degrees of freedom <span
class="tooltiprouttext">The residual degrees of freedom for the null
model.</span> </span>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Residual deviance: <span
class="tooltiprouttext">The test statistic from the chi-squared goodness
of fit test of the logistic regression.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  256.30 <span class="tooltiprouttext">This is
computed by the sum(log(myglm$res^2)). As long as this value is similar
in size to the degrees of freedom, then the model is a good fit.</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">  on 570 degrees of freedom <span
class="tooltiprouttext">This is <span class="math inline">\(n-p\)</span>
where <span class="math inline">\(n\)</span> is the sample size and
<span class="math inline">\(p\)</span> is the number of parameters in
the regression model. In this case, there is a sample size of 578 and
five parameters, <span class="math inline">\(\beta_0\)</span>, <span
class="math inline">\(\beta_1\)</span>, <span
class="math inline">\(\beta_2\)</span>, <span
class="math inline">\(\beta_3\)</span>, <span
class="math inline">\(\beta_4\)</span>, <span
class="math inline">\(\beta_5\)</span>,<span
class="math inline">\(\beta_6\)</span>, and <span
class="math inline">\(\beta_7\)</span> so 578-8 = 570.</span> </span>
</td>
</tr>
</table>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> AIC: <span class="tooltiprouttext">A form of
the Akiake Information Criterion. Smaller values of the AIC indicate a
better fitting model.</span> </span>
</td>
<td align="right">
<span class="tooltiprout">  272.3 <span class="tooltiprouttext">If a
model for the same Y-variable can be found with an AIC value lower than
272.3, then it is a better fit of the data.</span> </span>
</td>
</tr>
</table>
<p><br/></p>
<table class="rconsole">
<tr>
<td>
<span class="tooltiprout"> Number of Fisher Scoring iterations: <span
class="tooltiprouttext">If you have taken a class in Numerical Analysis,
this tells you how many iterations of the maximization algorithm were
required before converging to the "Estimates" of the parameters <span
class="math inline">\(\beta_0\)</span> and <span
class="math inline">\(\beta_1\)</span> found in the summary.</span>
</span>
</td>
<td align="right">
<span class="tooltiprout">  20 <span class="tooltiprouttext">This
implementation of glm required 20 Fisher Scoring iterations to converge.
Fewer iterations hints that the model is a better fit than when many
iterations are required.</span> </span>
</td>
</tr>
</table>
</div>
<p><br/></p>
</div>
<div id="diagnose-the-goodness-of-fit-1" class="section level4">
<h4>Diagnose the Goodness-of-Fit</h4>
<p>There are two ways to check the <strong>goodness of fit</strong> of a
logistic regression model.</p>
<div style="padding-left:25px;">
<p><strong>Option 1</strong>: Hosmer-Lemeshow Goodness-of-Fit Test</p>
<p>To check the <strong>goodness of fit</strong> of a logistic
regression model where there are <strong>few or no replicated <span
class="math inline">\(x\)</span>-values</strong> use the Hosmer-Lemeshow
Test.</p>
<a href="javascript:showhide('goodnessoffit2')">
<div class="hoverchunk">
<p><span class="tooltipr"> library(ResourceSelection) <span
class="tooltiprtext">This loads the ResourceSelection R package so that
you can access the hoslem.test() function. You may need to run the code:
install.packages("ResourceSelection") first.</span> </span><br/><span
class="tooltipr"> hoslem.test( <span class="tooltiprtext">This R
function performs the Hosmer-Lemeshow Goodness of Fit Test. See the
"Explanation" file to learn about this test.</span> </span><span
class="tooltipr"> YourGlmName <span
class="tooltiprtext"><code>YourGlmName</code> is the name of your
glm(...) code that you created previously.</span> </span><span
class="tooltipr"> $y,  <span class="tooltiprtext">ALWAYS type a "y"
here. This gives you the actual binary (0,1) y-values of your logistic
regression. The goodness of fit test will compare these actual values to
your predicted probabilities for each value in order to see if the model
is a "good fit."</span> </span><span class="tooltipr"> YourGlmName <span
class="tooltiprtext"><code>YourGlmName</code> is the name you used to
save the results of your glm(...) code.</span> </span><span
class="tooltipr"> $fitted,  <span class="tooltiprtext">ALWAYS type
"fitted" here. This gives you the fitted probabilities <span
class="math inline">\(\pi_i\)</span> of your logistic regression.</span>
</span><span class="tooltipr"> g=10) <span class="tooltiprtext">The
"g=10" is the default option for the value of g. The g is the number of
groups to run the goodness of fit test on. Just leave it at 10 unless
you are told to do otherwise. Ask your teacher for more information if
you are interested.</span> </span></p>
</div>
<p></a></p>
<div id="goodnessoffit2" style="display:none;">
<pre><code>## Warning: glm.fit: fitted probabilities numerically 0 or 1 occurred</code></pre>
<pre><code>## 
##  Hosmer and Lemeshow goodness of fit (GOF) test
## 
## data:  myglm$y, myglm$fitted
## X-squared = 18.212, df = 8, p-value = 0.0197</code></pre>
<p>Note that the null hypothesis of the goodness-of-fit test is that
"the logistic regression is a good fit." So we actually don't want to
"reject the null" in this case. So a large p-value here means our
logistic regression fits the data satisfactorily. A small p-value
implies a poor fit and the results of the logistic regression should not
be fully trusted.</p>
</div>
<p><br/></p>
<p><strong>Option 2</strong>: Deviance Goodness-of-fit Test</p>
<p>In some cases, there are <strong>many replicated <span
class="math inline">\(x\)</span>-values</strong> for
<strong>all</strong> x-values. Though this is rare, it is good to use
the <em>deviance goodness-of-fit test</em> whenever this happens.</p>
<a href="javascript:showhide('goodnessoffit1')">
<div class="hoverchunk">
<p><span class="tooltipr"> pchisq( <span class="tooltiprtext">The
<code>pchisq</code> command allows you to compute p-values from the
chi-squared distribution.</span> </span><span class="tooltipr"> residual
deviance,  <span class="tooltiprtext">The residual deviance is shown at
the bottom of the output of your <code>summary(YourGlmName)</code> and
should be typed in here as a number like 25.3.</span> </span><span
class="tooltipr"> df for residual deviance,  <span
class="tooltiprtext">The df for the residual deviance is also shown at
the bottom of the output of your
<code>summary(YourGlmName)</code>.</span> </span><span class="tooltipr">
lower.tail=FALSE) <span class="tooltiprtext">This command ensures you
find the probability of the chi-squared distribution being as extreme or
more extreme than the observed value of residual deviance.</span>
</span></p>
</div>
<p></a></p>
<div id="multipleGOF2" style="display:none;">
<div class="sourceCode" id="cb10"><pre class="sourceCode r"><code class="sourceCode r"><span id="cb10-1"><a href="#cb10-1" aria-hidden="true" tabindex="-1"></a>myglm <span class="ot">&lt;-</span> <span class="fu">glm</span>(weight<span class="sc">&gt;</span><span class="dv">100</span> <span class="sc">~</span> Time<span class="sc">*</span>Diet, <span class="at">data =</span> ChickWeight, <span class="at">family =</span> binomial)</span>
<span id="cb10-2"><a href="#cb10-2" aria-hidden="true" tabindex="-1"></a><span class="fu">summary</span>(myglm)</span></code></pre></div>
<pre><code>## 
## Call:
## glm(formula = weight &gt; 100 ~ Time * Diet, family = binomial, 
##     data = ChickWeight)
## 
## Deviance Residuals: 
##     Min       1Q   Median       3Q      Max  
## -2.9446  -0.2364   0.0000   0.2776   1.9968  
## 
## Coefficients:
##               Estimate Std. Error z value Pr(&gt;|z|)    
## (Intercept)   -4.97603    0.65316  -7.618 2.57e-14 ***
## Time           0.39111    0.04979   7.854 4.02e-15 ***
## Diet2          0.58283    1.04061   0.560   0.5754    
## Diet3         -8.44476    4.32324  -1.953   0.0508 .  
## Diet4        -67.41995 3768.10023  -0.018   0.9857    
## Time:Diet2     0.02391    0.08679   0.275   0.7830    
## Time:Diet3     1.20955    0.51249   2.360   0.0183 *  
## Time:Diet4     8.83168  471.01259   0.019   0.9850    
## ---
## Signif. codes:  0 &#39;***&#39; 0.001 &#39;**&#39; 0.01 &#39;*&#39; 0.05 &#39;.&#39; 0.1 &#39; &#39; 1
## 
## (Dispersion parameter for binomial family taken to be 1)
## 
##     Null deviance: 800.44  on 577  degrees of freedom
## Residual deviance: 256.30  on 570  degrees of freedom
## AIC: 272.3
## 
## Number of Fisher Scoring iterations: 20</code></pre>
<div class="sourceCode" id="cb12"><pre class="sourceCode r"><code class="sourceCode r"><span id="cb12-1"><a href="#cb12-1" aria-hidden="true" tabindex="-1"></a><span class="fu">pchisq</span>(<span class="fl">256.30</span>, <span class="dv">570</span>, <span class="at">lower.tail =</span> <span class="cn">TRUE</span>)</span></code></pre></div>
<pre><code>## [1] 6.585816e-33</code></pre>
</div>
<p>The null hypothesis of the goodness-of-fit test is that the logistic
regression is a good fit of the data. So a large p-value (like 0.479) is
good because it allows us to trust the results of our logistic
regression. When the p-value becomes very small, we must "reject the
null" and conclude a poor fit, which implies that we should not trust
the results of the logistic regression.</p>
</div>
<p><br/></p>
</div>
<div id="predict-probabilities-1" class="section level4">
<h4>Predict Probabilities</h4>
<p>To predict the probability that <span
class="math inline">\(Y_i=1\)</span> for a given <span
class="math inline">\(x\)</span>-value, use the code</p>
<a href="javascript:showhide('MultipleLogisticPredict')">
<div class="hoverchunk">
<p><span class="tooltipr"> predict( <span class="tooltiprtext">The
predict() function allows us to use the regression model that was
obtained from glm() to predict the probability that <span
class="math inline">\(Y_i = 1\)</span> for a given <span
class="math inline">\(X_i\)</span>.</span> </span><span
class="tooltipr"> YourGlmName,  <span
class="tooltiprtext"><code>YourGlmName</code> is the name of the object
you created when you performed your logistic regression using
glm().</span> </span><span class="tooltipr"> newdata =  <span
class="tooltiprtext">The <code>newdata =</code> command allows you to
specify the x-values for which you want to obtain predicted
probabilities that <span class="math inline">\(Y_i=1\)</span>.</span>
</span><span class="tooltipr"> NewDataFrame,  <span
class="tooltiprtext">Typically, NewDataFrame is created in real time
using the data.frame( X1 = c(Value 1, Value 2, ...), X2 = c(Value 1,
Value 2, ...), ...) command. You should see the GSS example file for an
example of how to use this function.</span> </span><span
class="tooltipr"> type = "response") <span class="tooltiprtext">The type
= "response" options specifies that you want predicted probabilities.
There are other options available. See ?predict.glm for details.</span>
</span></p>
</div>
<p></a></p>
<div id="MultipleLogisticPredict" style="display:none;">
<pre><code>##         1 
## 0.7314498</code></pre>
</div>
<p><br/></p>
</div>
<div id="plot-the-regression-1" class="section level4">
<h4>Plot the Regression</h4>
<div class="tab">
<p><button class="tablinks" onclick="openTab(event, 'MultipleLogisticBaseplot')">Base
R</button>
<button class="tablinks" onclick="openTab(event, 'MultipleLogisticggplot')">ggplot2</button></p>
</div>
<div id="MultipleLogisticBaseplot" class="tabcontent">
<p>
<a href="javascript:showhide('MultipleLogisticBaseplot2')">
<div class="hoverchunk">
<p><span class="tooltipr"> b &lt;- coef(myglm) <span
class="tooltiprtext">This stores the estimated coefficients from the
regression into the "b" vector.</span> </span><br/><span
class="tooltipr"> palette( <span class="tooltiprtext">The palette()
function allows you to specify the colors R chooses for the plot.</span>
</span><span class="tooltipr"> c("SomeColor","DifferentColor",...) <span
class="tooltiprtext">Specify as many colors for the palette as you wish.
R will choose a color for each group that you specify later on in your
plot(...) code.</span> </span><span class="tooltipr"> )) <span
class="tooltiprtext">Closing parentheses.</span> </span><br/><span
class="tooltipr"> plot( <span class="tooltiprtext">Create the binary
scatterplot for the logistic regression.</span> </span><span
class="tooltipr"> Y <span class="tooltiprtext">Note that Y must be
binary (0,1) values. If it is not, use a logical statement to make it
binary, like height&gt;60 or sex=="B".</span> </span><span
class="tooltipr">  ~  <span class="tooltiprtext">The formula operator in
R.</span> </span><span class="tooltipr"> X1, <span
class="tooltiprtext">The first x-variable in your glm code.</span>
</span><span class="tooltipr">  data = YourDataSet, <span
class="tooltiprtext">Specify the name of your data set.</span>
</span><span class="tooltipr">  pch = 16) <span
class="tooltiprtext">Select the type of plotting characters to use for
the plot.</span> </span><br/><span class="tooltipr"> curve( <span
class="tooltiprtext">Use the curve function to add the logistic
regression curve to the plot.</span> </span><span class="tooltipr"> exp(
<span class="tooltiprtext">The exp(...) function computes e^(stuff) in R
and stands for the "exponential function."</span> </span><span
class="tooltipr"> (b[1]+ <span class="tooltiprtext">The first
coefficient found in b is the y-intercept.</span> </span><span
class="tooltipr"> b[2] <span class="tooltiprtext">The second coefficient
found in b is the slope term.</span> </span><span class="tooltipr"> *x)
<span class="tooltiprtext">The curve(...) function requires that you
call the x-variable "x" although you can change this behavior using
xname="SomeOtherName" if you want.</span> </span><span class="tooltipr">
/ <span class="tooltiprtext">The logistic model is e^(stuff) / (1 +
e^(stuff)).</span> </span><span class="tooltipr">
(1+exp(b[1]+b[2]<em>x)) <span class="tooltiprtext">The denominator of
the logistic regression. Be careful to group the entire denominator
(1+exp(stuff)).</span> </span><span class="tooltipr">  col =
palette()[1], <span class="tooltiprtext">Pull the first color from the
color palette for the first curve.</span> </span><span class="tooltipr">
 add = TRUE) <span class="tooltiprtext">Add the curve to the current
plot.</span> </span><br/><span class="tooltipr">
curve(exp((b[1]+b[3])+(b[2]+b[4])</em>x) <span class="tooltiprtext">Note
how the numerator of this second logistic curve uses and adjusted
y-intercept (b[1]+b[3]) and an adjusted slope (b[2]+b[4])<em>x.</span>
</span><span class="tooltipr"> / <span class="tooltiprtext">Begin the
denominator.</span> </span><span class="tooltipr">
(1+exp((b[1]+b[3])+(b[2]+b[4])</em>x)) <span class="tooltiprtext">The
denominator consists of (1+exp(stuff)).</span> </span><span
class="tooltipr"> , <span class="tooltiprtext">Begin optional
parameters.</span> </span><span class="tooltipr">  col = palette()[2],
<span class="tooltiprtext">Set the color of this second curve to the
second color in the palette.</span> </span><span class="tooltipr">  add
= TRUE) <span class="tooltiprtext">Add the curve to the current
plot.</span> </span><br/><span class="tooltipr"> legend( <span
class="tooltiprtext">The legend function adds a legend to the current
plot.</span> </span><span class="tooltipr"> "topright", <span
class="tooltiprtext">Typically the legend is placed in the top-right
corner of the graph. But it could be placed "top", "topleft", "left",
"bottomleft", "bottom", "center", "right", or "bottomright".</span>
</span><span class="tooltipr">  legend = <span class="tooltiprtext">Why
you have to write legend again, no one knows, but you do.</span>
</span><span class="tooltipr"> c("Lable 1", "Label 2"), <span
class="tooltiprtext">These are the values that will appear in the
legend, one entry on each line of the legend.</span> </span><span
class="tooltipr">  col = palette(), <span class="tooltiprtext">This
specifies the colors of the symbols in the legend. First color goes with
"Label 1", and second goes with "Label 2" and so on.</span> </span><span
class="tooltipr">  lty = 1, <span class="tooltiprtext">Specifies that
solid lines should be used in the legend. If you wanted dots instead,
use pch=16. If you wanted dashed lines, use lty=2. Many other options
exist.</span> </span><span class="tooltipr">  bty = <span
class="tooltiprtext">Specifies the "box type" (bty) that should be drawn
around the legend.</span> </span><span class="tooltipr"> 'n') <span
class="tooltiprtext">By placing a "no" option ('n') here, no box is
drawn around the legend.</span> </span></p>
</div>
<p></a></p>
<div id="MultipleLogisticBaseplot2" style="display:none;">
<div class="sourceCode" id="cb15"><pre class="sourceCode r"><code class="sourceCode r"><span id="cb15-1"><a href="#cb15-1" aria-hidden="true" tabindex="-1"></a>myglm <span class="ot">&lt;-</span> <span class="fu">glm</span>(weight<span class="sc">&gt;</span><span class="dv">100</span> <span class="sc">~</span> Time<span class="sc">*</span>Diet, <span class="at">data =</span> ChickWeight, <span class="at">family =</span> binomial)</span>
<span id="cb15-2"><a href="#cb15-2" aria-hidden="true" tabindex="-1"></a><span class="fu">palette</span>(<span class="fu">c</span>(<span class="st">&quot;firebrick&quot;</span>, <span class="st">&quot;green&quot;</span>, <span class="st">&quot;skyblue&quot;</span>, <span class="st">&quot;darkorchid4&quot;</span>))</span>
<span id="cb15-3"><a href="#cb15-3" aria-hidden="true" tabindex="-1"></a>b <span class="ot">&lt;-</span> myglm<span class="sc">$</span>coefficients</span>
<span id="cb15-4"><a href="#cb15-4" aria-hidden="true" tabindex="-1"></a><span class="fu">plot</span>(weight<span class="sc">&gt;</span><span class="dv">100</span> <span class="sc">~</span> Time, <span class="at">data =</span> ChickWeight, <span class="at">pch=</span><span class="dv">16</span>)</span>
<span id="cb15-5"><a href="#cb15-5" aria-hidden="true" tabindex="-1"></a><span class="fu">curve</span>(<span class="fu">exp</span>(b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">2</span>]<span class="sc">*</span>x)<span class="sc">/</span>(<span class="dv">1</span><span class="sc">+</span><span class="fu">exp</span>(b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">2</span>]<span class="sc">*</span>x)), <span class="at">add=</span><span class="cn">TRUE</span>, <span class="at">col =</span> <span class="fu">palette</span>()[<span class="dv">1</span>])</span>
<span id="cb15-6"><a href="#cb15-6" aria-hidden="true" tabindex="-1"></a><span class="fu">curve</span>(<span class="fu">exp</span>((b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">3</span>])<span class="sc">+</span>(b[<span class="dv">2</span>]<span class="sc">+</span>b[<span class="dv">6</span>])<span class="sc">*</span>x)<span class="sc">/</span>(<span class="dv">1</span><span class="sc">+</span><span class="fu">exp</span>((b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">3</span>])<span class="sc">+</span>(b[<span class="dv">2</span>]<span class="sc">+</span>b[<span class="dv">6</span>])<span class="sc">*</span>x)), <span class="at">add=</span><span class="cn">TRUE</span>, <span class="at">col =</span> <span class="fu">palette</span>()[<span class="dv">2</span>])</span>
<span id="cb15-7"><a href="#cb15-7" aria-hidden="true" tabindex="-1"></a><span class="fu">curve</span>(<span class="fu">exp</span>((b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">4</span>])<span class="sc">+</span>(b[<span class="dv">2</span>]<span class="sc">+</span>b[<span class="dv">7</span>])<span class="sc">*</span>x)<span class="sc">/</span>(<span class="dv">1</span><span class="sc">+</span><span class="fu">exp</span>((b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">4</span>])<span class="sc">+</span>(b[<span class="dv">2</span>]<span class="sc">+</span>b[<span class="dv">7</span>])<span class="sc">*</span>x)), <span class="at">add=</span><span class="cn">TRUE</span>, <span class="at">col =</span> <span class="fu">palette</span>()[<span class="dv">3</span>])</span>
<span id="cb15-8"><a href="#cb15-8" aria-hidden="true" tabindex="-1"></a><span class="fu">curve</span>(<span class="fu">exp</span>((b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">5</span>])<span class="sc">+</span>(b[<span class="dv">2</span>]<span class="sc">+</span>b[<span class="dv">8</span>])<span class="sc">*</span>x)<span class="sc">/</span>(<span class="dv">1</span><span class="sc">+</span><span class="fu">exp</span>((b[<span class="dv">1</span>]<span class="sc">+</span>b[<span class="dv">5</span>])<span class="sc">+</span>(b[<span class="dv">2</span>]<span class="sc">+</span>b[<span class="dv">8</span>])<span class="sc">*</span>x)), <span class="at">add=</span><span class="cn">TRUE</span>, <span class="at">col =</span> <span class="fu">palette</span>()[<span class="dv">4</span>])</span>
<span id="cb15-9"><a href="#cb15-9" aria-hidden="true" tabindex="-1"></a><span class="fu">legend</span>(<span class="st">&quot;topleft&quot;</span>, <span class="at">legend =</span> <span class="fu">c</span>(<span class="st">&quot;Diet 1&quot;</span>, <span class="st">&quot;Diet 2&quot;</span>, <span class="st">&quot;Diet 3&quot;</span>, <span class="st">&quot;Diet 4&quot;</span>), <span class="at">col =</span> <span class="fu">palette</span>(), <span class="at">lty =</span> <span class="dv">1</span>, <span class="at">bty =</span> <span class="st">&#39;n&#39;</span>)</span></code></pre></div>
<p><img src="LogisticRegression_files/figure-html/unnamed-chunk-10-1.png" width="672" /></p>
</div>
</p>
</div>
<div id="MultipleLogisticggplot" class="tabcontent">
<p>
<a href="javascript:showhide('MultipleLogisticggplot2')">
<div class="hoverchunk">
<p><span class="tooltipr"> ggplot(data=YourDataName, <span
class="tooltiprtext">Initialize a ggplot.</span> </span><span
class="tooltipr">  aes( <span class="tooltiprtext">Declare the
aesthetics of the graph.</span> </span><span class="tooltipr"> x=X1,
<span class="tooltiprtext">Set the x-axis to be your X1 variable.</span>
</span><span class="tooltipr"> y=Y <span class="tooltiprtext">Set the
y-axis to be your Y-variable.</span> </span><span class="tooltipr"> )
<span class="tooltiprtext">Closing parenthesis for aes(...)
function.</span> </span><span class="tooltipr"> ) <span
class="tooltiprtext">Closing parenthesis for ggplot(...)
function.</span> </span><span class="tooltipr">  + <span
class="tooltiprtext">Add a layer to the ggplot.</span> </span><br/><span
class="tooltipr">   geom_point( <span class="tooltiprtext">Add dots to
the ggplot.</span> </span><span class="tooltipr"> ) <span
class="tooltiprtext">Closing parenthesis for the geom_point()
function.</span> </span><span class="tooltipr">  + <span
class="tooltiprtext">Add a layer to the ggplot.</span> </span><br/><span
class="tooltipr">   geom_smooth(method="glm",
method.args=list(family="binomial"), se=FALSE, <span
class="tooltiprtext">Add the logistic regression curve to the
plot.</span> </span><span class="tooltipr">   aes(color="X2) <span
class="tooltiprtext">Create a different logistic regression curve for
each group found in X2, and give each curve a different color.</span>
</span><span class="tooltipr"> ) <span class="tooltiprtext">Closing
parenthesis for the geom_smooth() function.</span> </span><span
class="tooltipr">  + <span class="tooltiprtext">Add a layer to the
plot.</span> </span><br/><span class="tooltipr">   theme_bw() <span
class="tooltiprtext">Add a black and white them to the plot.</span>
</span></p>
</div>
<p></a></p>
<div id="MultipleLogisticggplot2" style="display:none;">
<div class="sourceCode" id="cb16"><pre class="sourceCode r"><code class="sourceCode r"><span id="cb16-1"><a href="#cb16-1" aria-hidden="true" tabindex="-1"></a><span class="fu">ggplot</span>(ChickWeight, <span class="fu">aes</span>(Time, <span class="fu">as.numeric</span>(weight<span class="sc">&gt;</span><span class="dv">100</span>))) <span class="sc">+</span></span>
<span id="cb16-2"><a href="#cb16-2" aria-hidden="true" tabindex="-1"></a>  <span class="fu">geom_point</span>() <span class="sc">+</span></span>
<span id="cb16-3"><a href="#cb16-3" aria-hidden="true" tabindex="-1"></a>  <span class="fu">stat_smooth</span>(<span class="fu">aes</span>(<span class="at">color =</span> Diet), <span class="at">method =</span> <span class="st">&quot;glm&quot;</span>, <span class="at">method.args =</span> <span class="fu">list</span>(<span class="at">family =</span> <span class="st">&quot;binomial&quot;</span>), <span class="at">se =</span> <span class="cn">FALSE</span>) <span class="sc">+</span></span>
<span id="cb16-4"><a href="#cb16-4" aria-hidden="true" tabindex="-1"></a>  <span class="fu">theme_bw</span>() <span class="sc">+</span></span>
<span id="cb16-5"><a href="#cb16-5" aria-hidden="true" tabindex="-1"></a>  <span class="fu">labs</span>(<span class="at">y =</span> <span class="st">&quot;weight&gt;100&quot;</span>)</span></code></pre></div>
<pre><code>## `geom_smooth()` using formula = &#39;y ~ x&#39;</code></pre>
<p><img src="LogisticRegression_files/figure-html/unnamed-chunk-11-1.png" width="672" /></p>
</div>
</p>
</div>
<hr />
</div>
</div>
</div>
<div id="explanation-1" class="section level3">
<h3>Explanation</h3>
<div style="padding-left:125px;">
<p>Multiple Logistic Regression is used when</p>
<ul>
<li>the response variable is binary <span
class="math inline">\((Y_i=0\)</span> or <span
class="math inline">\(1)\)</span>, and</li>
<li>there are multiple explanatory variables <span
class="math inline">\(X_1,\ldots,X_p\)</span> that can be either
quantitative or qualitative.</li>
</ul>
<div id="the-model-1" class="section level4">
<h4>The Model</h4>
<p>Very little changes in multiple logistic regression from Simple
Logistic Regression. The probability that <span
class="math inline">\(Y_i = 1\)</span> given the observed data <span
class="math inline">\((x_{i1},\ldots,x_{ip})\)</span> is called <span
class="math inline">\(\pi_i\)</span> and is modeled by the expanded
equation</p>
<p><span class="math display">\[
  P(Y_i = 1|\, x_{i1},\ldots,x_{ip}) = \frac{e^{\beta_0 + \beta_1 x_{i1}
+ \ldots + \beta_p x_{ip}}}{1+e^{\beta_0 + \beta_1 x_{i1} + \ldots +
\beta_p x_{ip} }} = \pi_i
\]</span></p>
<p>The assumption is that for certain combinations of <span
class="math inline">\(X_1,\ldots,X_p\)</span> the probability that <span
class="math inline">\(Y_i=1\)</span> is higher than for other
combinations.</p>
</div>
<div id="interpretation-1" class="section level4">
<h4>Interpretation</h4>
<p>The model for <span class="math inline">\(\pi_i\)</span> comes from
modeling the <em>log of the odds</em> that <span
class="math inline">\(Y_i=1\)</span> using a linear regression, i.e.,
<span class="math display">\[
  \log\underbrace{\left(\frac{\pi_i}{1-\pi_i}\right)}_{\text{Odds for}\
Y_i=1} = \underbrace{\beta_0 + \beta_1 x_{i1} + \ldots + \beta_p
x_{ip}}_{\text{linear regression}}
\]</span> Beginning to solve this equation for <span
class="math inline">\(\pi_i\)</span> leads to the intermediate, but
important result that <span class="math display">\[
    \underbrace{\frac{\pi_i}{1-\pi_i}}_{\text{Odds for}\ Y_i=1} =
e^{\overbrace{\beta_0 + \beta_1 x_{i1} + \ldots + \beta_p
x_{ip}}^{\text{liear regression}}} = e^{\beta_0}e^{\beta_1 x_{i1}}\cdots
e^{\beta_p x_{ip}}
\]</span> As in Simple Linear Regression, the values of <span
class="math inline">\(e^{\beta_0}\)</span>, <span
class="math inline">\(e^{\beta_1}\)</span>, <span
class="math inline">\(\ldots\)</span>, <span
class="math inline">\(e^{\beta_p}\)</span> are interpreted as the
proportional change in odds for <span
class="math inline">\(Y_i=1\)</span> when a given <span
class="math inline">\(x\)</span>-variable experiences a unit change,
<em>all other variables being held constant</em>.</p>
</div>
<div id="checking-the-model-assumptions" class="section level4">
<h4>Checking the Model Assumptions</h4>
<p>Diagnostics are the same in multiple logistic regression as they are
in simple logistic regression.</p>
</div>
<div id="prediction-1" class="section level4">
<h4>Prediction</h4>
<p>The idea behind prediction in multiple logistic regression is the
same as in simple logistic regression. The only difference is that more
than one explanatory variable is used to make the prediction of the
<em>risk</em> that <span class="math inline">\(Y_i=1\)</span>.</p>
<p><a
href="https://stats.oarc.ucla.edu/r/dae/multinomial-logistic-regression/"
class="uri">https://stats.oarc.ucla.edu/r/dae/multinomial-logistic-regression/</a>
<a href="https://stats.oarc.ucla.edu/r/dae/ordinal-logistic-regression/"
class="uri">https://stats.oarc.ucla.edu/r/dae/ordinal-logistic-regression/</a>
----</p>
</div>
</div>
</div>
<div id="section-1" class="section level3">
<h3></h3>
<hr />
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