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<title>Judging Exercise Correctness from Accelerator Data</title>

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<h1>Judging Exercise Correctness from Accelerator Data</h1>

<p>Practical Machine Learning - Course Project Write-up</p>

<p>Mike Wise - 25 Aug 2014 - predmachlearn-004</p>

<h1>Background</h1>

<p>Using devices such as Jawbone Up, Nike Fuel Band, and Fitbit it is now possible to collect a large amount of data about personal activity relatively inexpensively. These type of devices are part of the quantified self movement - a group of enthusiasts who take measurements about themselves regularly to improve their health, to find patterns in their behavior, or because they are tech geeks. One thing that people regularly do is quantify how much of a particular activity they do, but they rarely quantify the quality - i.e.how well they do it. The goal here is to use data from accelerometers on the belt, forearm, arm, and dumbbell to assess the quality. </p>

<p>In this exercise 6 young health participants were asked to perform one set of 10 repetitions of the Unilateral Dumbbell Biceps Curl. The quality of the execution was judged by an expert and fell into 5 different classes or grades:</p>

<ul>
<li>Class A - correct - exactly according to the specification</li>
<li>Class B - mistake - throwing the elbows to the front</li>
<li>Class C - mistake - lifting the dumbbell only halfway</li>
<li>Class D - mistake - lowering the dumbbell only halfway</li>
<li>Class E - mistake - throwing the hips to the front</li>
</ul>

<p>At the same time these exercises were being performed data was being recorded from a large number of sensors mounted on the body of the exercise participant. There are 19622 observations in our data training set, the goal here is to see if this judging can be can automate.</p>

<p>More information is available from the website here (see the section on the Weight Lifting Exercise Dataset):</p>

<pre><code>         http://groupware.les.inf.puc-rio.br/har 
</code></pre>

<h1>Overall Approach</h1>

<p>The overall approach was as follow:</p>

<ul>
<li>1. <strong>Data Preperation</strong> - here the training and test data was read and new datasets were created containing only numeric columns that were appropriate for modeling.</li>
<li>2. <strong>Data Exploration and Model Selection</strong> - here the data was investigated, and an investigation of the trade off between accuracy and training/validation split size was performed for various combinations of modeling techniques and variable subsets.</li>
<li>3. <strong>Modeling and Analysis</strong> - In this section the split was performed and selected model was run and an analysis of the results was performed. The Out of sample error is also calculated.</li>
<li>4. <strong>Prediction</strong> - Here the results for the Prediction Assignment Submission are calculated.</li>
</ul>

<p>Some additional code is also presented in the Appendix.</p>

<h1>Data Preperation</h1>

<p>Our data came in two spreadsheet files:</p>

<ul>
<li><strong>pml-training.csv</strong> - a csv file containing 19622 observations with 160 columns with labeled training data. This data is to be used to train and validate our model.</li>
<li><strong>pml-training.csv</strong> - a csv file containing 20 observations with the same columns (but minus the label). This data is t be predicted with our final model and submitted. it is only used in the last step of this project.</li>
</ul>

<h2>Loading and preprocessing the data</h2>

<p>First of course we load the data.</p>

<pre><code class="r">library(data.table,quietly=T)

otrn &lt;- data.table(read.csv(&quot;pml-training.csv&quot;))
otst &lt;- data.table(read.csv(&quot;pml-testing.csv&quot;))
</code></pre>

<h2>Data Cleaning</h2>

<p>There are 160 columns in the original data, many of them blank and filled with NA values. We reduce the dataset, throwing away all columns that are not numeric or integer. We also exclude the columns &ldquo;num_window&rdquo; and &ldquo;user_name&rdquo; out of the training set as these are not sensor data columns.</p>

<pre><code class="r">## Create new tables without of all non-numeric columns not present in both datasets
cnstst &lt;- colnames(otrn)[7:160]
ntrn &lt;- data.table(user_name=otrn[[&quot;user_name&quot;]],classe=otrn[[&quot;classe&quot;]])
ntst &lt;- data.table(user_name=otst[[&quot;user_name&quot;]])

for (i in 1:length(cnstst))
{
  cn &lt;- cnstst[[i]]
  if (cn==&quot;num_window&quot;) next
  if (cn==&quot;user_window&quot;) next
  clstst &lt;- class(otst[[cn]])
  clstrn &lt;- class(otrn[[cn]])
  if (clstst!=&quot;numeric&quot; &amp;&amp; clstst !=&quot;integer&quot;) next
  if (clstrn!=&quot;numeric&quot; &amp;&amp; clstrn !=&quot;integer&quot;) next
  ntrn[[cn]] &lt;- otrn[[cn]]
  ntst[[cn]] &lt;- otst[[cn]]
}
</code></pre>

<p>Here the quality of the data is checked, showing what columns we have retained (all relevant sensor data columns) and showing the reduction in  the number of &ldquo;NA&rdquo; values from 1.2 million to zero, mostly by eliminating columns that consisted mostly of &ldquo;NA&rdquo; values.</p>

<pre><code class="r">ona &lt;- sum(is.na(otrn))
nna &lt;- sum(is.na(ntrn))
print(sprintf(&quot;Original training NA count:%d  - After processing:%d&quot;,ona,nna))
</code></pre>

<pre><code>## [1] &quot;Original training NA count:1287472  - After processing:0&quot;
</code></pre>

<h2>Data Exploration</h2>

<p>Now that we have a more acceptable number of data columns (54 vs. 160) we look at the overall data.</p>

<pre><code class="r">library(reshape)
library(ggplot2,quietly=T)

hdat &lt;- melt(ntrn)
ggplot(hdat, aes(x=value)) + facet_wrap(~variable, scales=&quot;free&quot;,ncol=6) + geom_histogram()
</code></pre>

<p><img 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" alt="plot of chunk unnamed-chunk-4"/> 
There are 19622 observations of 160 columns in our dataset. Here we look at the distribution of grades by participant.</p>

<pre><code class="r">ggplot(otrn,aes(x=classe))+geom_histogram(fill=c(&quot;darkgreen&quot;,&quot;darkred&quot;,&quot;darkred&quot;,&quot;darkred&quot;,&quot;darkred&quot;)) +
   ggtitle(&quot;Participants and Exercise Grade&quot;) + facet_grid( . ~ user_name ) +
   labs(x=&quot;Grade/Class&quot;,y=&quot;Count&quot;)
</code></pre>

<p><img src="data:image/png;base64,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" alt="plot of chunk unnamed-chunk-5"/> </p>

<h2>Model Selection</h2>

<p>We discovered:</p>

<ul>
<li>the randomForest in the randomForest package executed quite quickly on our data</li>
<li>Both the boosting tree and the random forest that are called in the caret package were painfully slow - although probably more sophisticated.</li>
</ul>

<p>This led us to concentrate on the randomForest package implementation since we can try out more in this learning environment.</p>

<p>We then investigated the trade offs between accuracy and validation set size, as well as how these change with the number of variables. </p>

<p>First we selected a set of the most 3 important and then the most 7 important variables. We did this by doing a random forest on the training
set using all the variables. </p>

<pre><code class="r">library(ElemStatLearn,quietly=T)
library(randomForest,quietly=T)
library(caret,quietly=T)

set.seed(2718)
rffit1 &lt;- randomForest(classe ~ ., ntrn, importance=T)

varImpPlot(rffit1)
</code></pre>

<p><img 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" alt="plot of chunk unnamed-chunk-6"/> </p>

<p>The variables we selected were:</p>

<ul>
<li>1. yaw_belt</li>
<li>2. roll_belt</li>
<li>3. pitch_belt</li>
<li>4. roll_arm</li>
<li>5. pitch_forearm</li>
<li>6. magnet_dumbbell_y</li>
<li>7. magnet_dumbbell_z</li>
</ul>

<p>To investigate the trade offs we executed a large number of randomForest calls with different sizes of training/validation set splits, different number of variables, and recorded the accuracy on each run. 
Specifically:</p>

<ul>
<li>we varied the randomForest calls for 3 variable, 7 variable, and 54 variable subsets.</li>
<li>varied the training/validation set split from 0.05% to 0.95% in 0.05% steps</li>
<li>we ran the resulting randomForest fit against the validation set and recorded the accuracy.
The code for this can be found in the appendix.</li>
</ul>

<p>This was done with 3 runs (one per variable subset) which contained 57 calls to randomForest each.</p>

<p>The results of the trade-off analysis can be seen here:</p>

<pre><code class="r">dfva &lt;- read.csv(&quot;dftest54v-3it.csv&quot;)
dfva$varnum &lt;- &quot;54 vars&quot;

dfv7 &lt;- read.csv(&quot;dftest7v-3it.csv&quot;)
dfv7$varnum &lt;- &quot;7 vars&quot;

dfv3 &lt;- read.csv(&quot;dftest3v-3it.csv&quot;)
dfv3$varnum &lt;- &quot;3 vars&quot;

dfall &lt;- merge(dfv3,dfv7,all=T)
dfall &lt;- merge(dfall,dfva,all=T)
dfall &lt;- transform(dfall, varnum=factor(varnum,levels=c(&quot;3 vars&quot;,&quot;7 vars&quot;,&quot;54 vars&quot;) ))

qplot(prob,acc,data=dfall) + geom_smooth(method=loess) + facet_grid( . ~ varnum ) +
  ggtitle(&quot;Accuracy vs. Training Percentage&quot;) + labs(x=&quot;Training Percentage&quot;,y=&quot;Accuracy&quot;)
</code></pre>

<p><img src="data:image/png;base64,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" alt="plot of chunk unnamed-chunk-7"/> </p>

<p>The time to create these datasets was as follows (see appendix and datasets for more details):</p>

<ul>
<li> 3 var subset - dftest3v-3it.csv  - 57 rf-calls in  304.22 secs ( 5.3 secs per iteration)</li>
<li> 7 var subset - dftest7v-3it.csv  - 57 rf-calls in  429.98 secs ( 7.7 secs per iteration)</li>
<li>54 var subset - dftest54v-3it.csv - 57 rf-calls in 2668.50 secs (46.8 secs per iteration)</li>
</ul>

<p>In the end we chose to go with the model using 7 variables and a 75% training/validation split since it: </p>

<ul>
<li> Had very good accuracy.</li>
<li> Had performance much better than the 54 variable set. </li>
</ul>

<p>From these plots <strong>we expect the out of sample error to be around 98.8% for 7 vars amd 75% split.</strong></p>

<h1>Model and Analysis</h1>

<h2>Train and Validation Splits</h2>

<p>There was some debate in the discussion forums as to whether or not data should be split into testing and validation sets should be used with a randomForest approach. </p>

<p>The arguments against were:</p>

<ul>
<li>randomForest is not prone to overfitting, thus the more data the better</li>
<li>internally a splitting of the data into validation and testing sets is done anyway when computing the weights.</li>
</ul>

<p>However there are also good arguments to do a validation, namely:</p>

<ul>
<li>since this is a training exercise it is good to demonstrate that we can do it.</li>
<li>in a real world consulting situation the customer will probably want to see this.</li>
<li>most interestingly, our data above shows that the limiting accuracy is not 100 percent, rather something less than 98 percent.</li>
</ul>

<p>The following code performs this split.</p>

<pre><code class="r">      set.seed(3141)
      ntrn0 &lt;- ntrn
      trnidx &lt;- createDataPartition(y=ntrn0$classe,p=0.75,list=F)
      ntrndf &lt;- data.frame(ntrn0)
      nvld &lt;- ntrndf[-trnidx,]
      ntrn &lt;- ntrndf[trnidx,]
      print(sprintf(&quot;Validation set has %d and training set has %d rows&quot;,nrow(nvld),nrow(ntrn)))
</code></pre>

<pre><code>## [1] &quot;Validation set has 4904 and training set has 14718 rows&quot;
</code></pre>

<h2>Model Fitting</h2>

<p>We fit a model to the data using the &ldquo;Random Forests&rdquo; algorithm from the random Forest library. We then evaluate the importance of the
various variable and assess the overall accuracy of the model using the Confusion Matrix.</p>

<p>As can be seen from the Confusion Matrix below, the model accuracy on the training data set is 100%, however the accuracy on the validation set is somewhat less (see below)</p>

<p>Here we fit the model after setting the random number seed so that we can reproduce our results.</p>

<pre><code class="r">set.seed(2718)
rffit &lt;- randomForest(classe ~ yaw_belt + pitch_belt + roll_belt + roll_arm + pitch_forearm + 
                        magnet_dumbbell_y + magnet_dumbbell_z, ntrn, importance=T)
</code></pre>

<h2>Validation Analysis</h2>

<p>Now we check the results against the training set, not surprisingly it is 100 percent correct.</p>

<pre><code class="r">prftrn &lt;- predict(rffit, ntrn)
confusionMatrix(prftrn, ntrn$classe)
</code></pre>

<pre><code>## Confusion Matrix and Statistics
## 
##           Reference
## Prediction    A    B    C    D    E
##          A 4185    0    0    0    0
##          B    0 2848    0    0    0
##          C    0    0 2567    0    0
##          D    0    0    0 2412    0
##          E    0    0    0    0 2706
## 
## Overall Statistics
##                                 
##                Accuracy : 1     
##                  95% CI : (1, 1)
##     No Information Rate : 0.284 
##     P-Value [Acc &gt; NIR] : &lt;2e-16
##                                 
##                   Kappa : 1     
##  Mcnemar&#39;s Test P-Value : NA    
## 
## Statistics by Class:
## 
##                      Class: A Class: B Class: C Class: D Class: E
## Sensitivity             1.000    1.000    1.000    1.000    1.000
## Specificity             1.000    1.000    1.000    1.000    1.000
## Pos Pred Value          1.000    1.000    1.000    1.000    1.000
## Neg Pred Value          1.000    1.000    1.000    1.000    1.000
## Prevalence              0.284    0.194    0.174    0.164    0.184
## Detection Rate          0.284    0.194    0.174    0.164    0.184
## Detection Prevalence    0.284    0.194    0.174    0.164    0.184
## Balanced Accuracy       1.000    1.000    1.000    1.000    1.000
</code></pre>

<p>Now we check the results against our validation set which is 25% of our original data. There are 7+15+7+2+10+3+4+3+2+1+5 = 59 incorrect classifications out of 1388+922+845+798+892+59 = 4904 cases implying an accuracy of %98.797. Thus we have an an <strong>out-of-sample error of 1.203%</strong>.</p>

<pre><code class="r">prfvld &lt;- predict(rffit, nvld)
confusionMatrix(prfvld, nvld$classe)
</code></pre>

<pre><code>## Confusion Matrix and Statistics
## 
##           Reference
## Prediction    A    B    C    D    E
##          A 1388   10    0    0    0
##          B    7  922    3    2    5
##          C    0   15  845    4    1
##          D    0    2    7  798    3
##          E    0    0    0    0  892
## 
## Overall Statistics
##                                         
##                Accuracy : 0.988         
##                  95% CI : (0.985, 0.991)
##     No Information Rate : 0.284         
##     P-Value [Acc &gt; NIR] : &lt;2e-16        
##                                         
##                   Kappa : 0.985         
##  Mcnemar&#39;s Test P-Value : NA            
## 
## Statistics by Class:
## 
##                      Class: A Class: B Class: C Class: D Class: E
## Sensitivity             0.995    0.972    0.988    0.993    0.990
## Specificity             0.997    0.996    0.995    0.997    1.000
## Pos Pred Value          0.993    0.982    0.977    0.985    1.000
## Neg Pred Value          0.998    0.993    0.998    0.999    0.998
## Prevalence              0.284    0.194    0.174    0.164    0.184
## Detection Rate          0.283    0.188    0.172    0.163    0.182
## Detection Prevalence    0.285    0.191    0.176    0.165    0.182
## Balanced Accuracy       0.996    0.984    0.992    0.995    0.995
</code></pre>

<h1>Prediction</h1>

<p>And finally for completeness sake, we use the model we generated to predict the values needed on the submission entry for this project. </p>

<pre><code class="r">prftst &lt;- predict(rffit, ntst)
prftst
</code></pre>

<pre><code>##  1  2  3  4  5  6  7  8  9 10 11 12 13 14 15 16 17 18 19 20 
##  B  A  B  A  A  E  D  B  A  A  B  C  B  A  E  E  A  B  B  B 
## Levels: A B C D E
</code></pre>

<h1>Appendix A - Tradeoff curve code</h1>

<p>The following code was used to generate the trade off curves of validation set size vs. accuracy that were used in this analysis to help determine the variables that we fitted and the size of the validation set.</p>

<pre><code class="r">library(data.table)
library(ElemStatLearn)
library(randomForest)
library(caret)

# Data Processing
## Load the data

otrn &lt;- data.table(read.csv(&quot;pml-training.csv&quot;))
otst &lt;- data.table(read.csv(&quot;pml-testing.csv&quot;))

## Create new tables without of all non-numeric columns not present in both datasets
cnstst &lt;- colnames(otrn)[7:160]
ntrn &lt;- data.table(user_name=otrn[[&quot;user_name&quot;]],classe=otrn[[&quot;classe&quot;]])
ntst &lt;- data.table(user_name=otst[[&quot;user_name&quot;]])

for (i in 1:length(cnstst))
{
  cn &lt;- cnstst[[i]]
  if (cn==&quot;num_window&quot;) next
 # if (cn==&quot;user_name&quot;) next
  clstst &lt;- class(otst[[cn]])
  clstrn &lt;- class(otrn[[cn]])
  if (clstst!=&quot;numeric&quot; &amp;&amp; clstst !=&quot;integer&quot;) next
  if (clstrn!=&quot;numeric&quot; &amp;&amp; clstrn !=&quot;integer&quot;) next
  ntrn[[cn]] &lt;- otrn[[cn]]
  ntst[[cn]] &lt;- otst[[cn]]
}

# Check the quality

ona &lt;- sum(is.na(otrn))
nna &lt;- sum(is.na(ntrn))
msg &lt;- sprintf(&quot;Original training na count:%d  - After processing:%d&quot;,ona,nna)
print(msg)
ntrn0 &lt;- ntrn

# Iterate
baseprobseq &lt;- seq( 0.05, 0.95, 0.05 )
#baseprobseq &lt;- seq( 0.1, 0.9, 0.2 )
nsamp &lt;- 3

pvec &lt;- c()
avec &lt;- c()
tvec &lt;- c()
evec &lt;- c()
wvec &lt;- c()

for (i in 1:20)
{
  vcmd &lt;- sprintf(&quot;v%d = c()&quot;,i)
  eval(parse(text=vcmd))
}
elap &lt;- 0
welap &lt;- 0
ntodo &lt;- length(baseprobseq)*nsamp
idone &lt;- 0
iprobdone &lt;- 0
eta &lt;- 0
acc &lt;- 0
sttime &lt;- proc.time()
for (prob in baseprobseq)
{
   for (j in 1:nsamp)
   {
      jsttime &lt;- proc.time()
      celap &lt;- (jsttime-sttime)[&quot;elapsed&quot;]
      if (idone&gt;0)
      {
          eta &lt;- ntodo*celap/idone
      }
      msg &lt;- sprintf(&quot;it:%d/%d prob:%5.2f last-acc:%5.3f lelap:%6.1f eta-sec:%6.1f wall-sec:%6.1f&quot;,
                     idone,ntodo,prob,acc,elap,eta,welap)
     # msg &lt;- sprintf(&quot;it:%d/%d prob:%5.2f&quot;,idone,ntodo,prob)
      print(msg)

      trnidx &lt;- createDataPartition(y=ntrn0$classe,p=prob,list=F)
      ntrndf &lt;- data.frame(ntrn0)
      nvld &lt;- ntrndf[-trnidx,]
      ntrn &lt;- ntrndf[trnidx,]

      #rffit &lt;- randomForest(classe ~ ., ntrn, importance=T)
      rffit &lt;- randomForest(classe ~ yaw_belt + pitch_belt + roll_belt, ntrn, importance=T)
      #rffit &lt;- randomForest(classe ~ yaw_belt + pitch_belt + roll_belt + roll_arm + 
      #pitch_forearm + magnet_dumbbell_y + magnet_dumbbell_z, ntrn, importance=T)

      prfvld &lt;- predict(rffit, nvld)
      cm &lt;- confusionMatrix(prfvld, nvld$classe)
      acc &lt;- cm$overall[&quot;Accuracy&quot;]
      pvec &lt;- c(pvec,prob)
      avec &lt;- c(avec,acc)
      prftst &lt;- predict(rffit, ntst)
      for (i in 1:20)
      {
        vcmd1 &lt;- sprintf(&quot;vtmp = as.character(prftst[[%d]])&quot;,i)
        eval(parse(text=vcmd1))
        vcmd2 &lt;- sprintf(&quot;v%d = c(v%d,vtmp)&quot;,i,i) 
        eval(parse(text=vcmd2))
      }
      elap &lt;- (proc.time() - jsttime)[&quot;elapsed&quot;]
      evec &lt;- c(evec,elap)

      welap &lt;- (proc.time() - sttime)[&quot;elapsed&quot;]
      wvec &lt;- c(wvec,welap)

      plot(pvec,avec)

      idone &lt;- idone+1
   }
   iprobdone &lt;- iprobdone+1
}
qplot(pvec,avec) + geom_smooth()

df &lt;- data.frame(prob=pvec,acc=avec,elap=evec,welap=wvec)
for (i in 1:20)
{
  vcmd3 &lt;- sprintf(&quot;df$v%d &lt;- v%d&quot;,i,i)
  eval(parse(text=vcmd3))
}
write.csv(df,&quot;dftest3v-3it.csv&quot;)
</code></pre>

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