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611 lines
16 KiB
Plaintext
Executable File
611 lines
16 KiB
Plaintext
Executable File
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> x <- c (1 ,3 ,2 ,5)
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> x
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[1] 1 3 2 5
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Note that the > is not part of the command; rather, it is printed by R to
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indicate that it is ready for another command to be entered. We can also
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save things using = rather than <- :
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> x = c (1 ,6 ,2)
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> x
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[1] 1 6 2
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> y = c (1 ,4 ,3)
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Hitting the up arrow multiple times will display the previous commands,
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which can then be edited. This is useful since one often wishes to repeat
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a similar command. In addition, typing ?funcname will always cause R to
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open a new help file window with additional information about the function
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funcname .
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We can tell R to add two sets of numbers together. It will then add the
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first number from x to the first number from y , and so on. However, x and
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y should be the same length. We can check their length using the length()
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length()
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function.
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> length ( x )
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[1] 3
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> length ( y )
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[1] 3
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> x+y
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[1] 2 10 5
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The ls() function allows us to look at a list of all of the objects, such
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ls()
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as data and functions, that we have saved so far. The rm() function cSan be
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rm()
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used to delete any that we don’t want.
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> ls ()
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[1] " x " " y "
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> rm (x , y )
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> ls ()
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character (0)
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It’s also possible to remove all objects at once:
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> rm ( list = ls () )44
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2. Statistical Learning
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The matrix() function can be used to create a matrix of numbers. Before
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matrix()
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we use the matrix() function, we can learn more about it:
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> ? matrix
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The help file reveals that the matrix() function takes a number of inputs,
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but for now we focus on the first three: the data (the entries in the matrix),
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the number of rows, and the number of columns. First, we create a simple
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matrix.
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> x = matrix ( data = c (1 ,2 ,3 ,4) , nrow =2 , ncol =2)
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> x
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[ ,1] [ ,2]
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[1 ,]
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1
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3
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[2 ,]
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2
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4
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Note that we could just as well omit typing data= , nrow= , and ncol= in the
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matrix() command above: that is, we could just type
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> x = matrix ( c (1 ,2 ,3 ,4) ,2 ,2)
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and this would have the same effect. However, it can sometimes be useful to
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specify the names of the arguments passed in, since otherwise R will assume
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that the function arguments are passed into the function in the same order
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that is given in the function’s help file. As this example illustrates, by
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default R creates matrices by successively filling in columns. Alternatively,
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the byrow=TRUE option can be used to populate the matrix in order of the
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rows.
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> matrix ( c (1 ,2 ,3 ,4) ,2 ,2 , byrow = TRUE )
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[ ,1] [ ,2]
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[1 ,]
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1
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2
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[2 ,]
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3
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4
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Notice that in the above command we did not assign the matrix to a value
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such as x . In this case the matrix is printed to the screen but is not saved
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for future calculations. The sqrt() function returns the square root of each
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sqrt()
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element of a vector or matrix. The command x^2 raises each element of x
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to the power 2 ; any powers are possible, including fractional or negative
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powers.
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> sqrt ( x )
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[ ,1]
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[1 ,] 1.00
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[2 ,] 1.41
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> x ^2
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[ ,1]
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[1 ,]
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1
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[2 ,]
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4
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[ ,2]
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1.73
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2.00
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[ ,2]
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9
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16
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The rnorm() function generates a vector of random normal variables,
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rnorm()
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with first argument n the sample size. Each time we call this function, we
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will get a different answer. Here we create two correlated sets of numbers,
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x and y , and use the cor() function to compute the correlation between
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cor()
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them.2.3 Lab: Introduction to R
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45
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> x = rnorm (50)
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> y = x + rnorm (50 , mean =50 , sd =.1)
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> cor ( x , y )
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[1] 0.995
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By default, rnorm() creates standard normal random variables with a mean
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of 0 and a standard deviation of 1. However, the mean and standard devi-
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ation can be altered using the mean and sd arguments, as illustrated above.
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Sometimes we want our code to reproduce the exact same set of random
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numbers; we can use the set.seed() function to do this. The set.seed()
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set.seed()
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function takes an (arbitrary) integer argument.
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> set . seed (1303)
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> rnorm (50)
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[1] -1.1440
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1.3421
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. . .
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2.1854
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0.5364
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0.0632
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0.5022 -0.0004
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We use set.seed() throughout the labs whenever we perform calculations
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involving random quantities. In general this should allow the user to re-
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produce our results. However, it should be noted that as new versions of
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R become available it is possible that some small discrepancies may form
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between the book and the output from R .
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The mean() and var() functions can be used to compute the mean and
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mean()
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variance of a vector of numbers. Applying sqrt() to the output of var() var()
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will give the standard deviation. Or we can simply use the sd() function.
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sd()
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> set . seed (3)
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> y = rnorm (100)
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> mean ( y )
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[1] 0.0110
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> var ( y )
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[1] 0.7329
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> sqrt ( var ( y ) )
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[1] 0.8561
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> sd ( y )
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[1] 0.8561
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2.3.2 Graphics
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The plot() function is the primary way to plot data in R . For instance,
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plot()
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plot(x,y) produces a scatterplot of the numbers in x versus the numbers
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in y . There are many additional options that can be passed in to the plot()
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function. For example, passing in the argument xlab will result in a label
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on the x-axis. To find out more information about the plot() function,
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type ?plot .
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>
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>
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>
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>
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x = rnorm (100)
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y = rnorm (100)
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plot (x , y )
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plot (x ,y , xlab =" this is the x - axis " , ylab =" this is the y - axis " ,
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main =" Plot of X vs Y ")46
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2. Statistical Learning
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We will often want to save the output of an R plot. The command that we
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use to do this will depend on the file type that we would like to create. For
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instance, to create a pdf, we use the pdf() function, and to create a jpeg,
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pdf()
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we use the jpeg() function.
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jpeg()
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> pdf (" Figure . pdf ")
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> plot (x ,y , col =" green ")
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> dev . off ()
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null device
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1
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The function dev.off() indicates to R that we are done creating the plot.
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dev.off()
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Alternatively, we can simply copy the plot window and paste it into an
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appropriate file type, such as a Word document.
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The function seq() can be used to create a sequence of numbers. For
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seq()
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instance, seq(a,b) makes a vector of integers between a and b . There are
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many other options: for instance, seq(0,1,length=10) makes a sequence of
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10 numbers that are equally spaced between 0 and 1 . Typing 3:11 is a
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shorthand for seq(3,11) for integer arguments.
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> x = seq (1 ,10)
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> x
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[1] 1 2 3 4 5 6 7
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> x =1:10
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> x
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[1] 1 2 3 4 5 6 7
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> x = seq ( - pi , pi , length =50)
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8 9 10
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8 9 10
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We will now create some more sophisticated plots. The contour() func-
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contour()
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tion produces a contour plot in order to represent three-dimensional data; contour plot
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it is like a topographical map. It takes three arguments:
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1. A vector of the x values (the first dimension),
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2. A vector of the y values (the second dimension), and
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3. A matrix whose elements correspond to the z value (the third dimen-
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sion) for each pair of ( x , y ) coordinates.
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As with the plot() function, there are many other inputs that can be used
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to fine-tune the output of the contour() function. To learn more about
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these, take a look at the help file by typing ?contour .
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>
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>
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>
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>
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>
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>
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y=x
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f = outer (x ,y , function (x , y ) cos ( y ) /(1+ x ^2) )
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contour (x ,y , f )
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contour (x ,y ,f , nlevels =45 , add = T )
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fa =( f - t ( f ) ) /2
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contour (x ,y , fa , nlevels =15)
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The image() function works the same way as contour() , except that it
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image()
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produces a color-coded plot whose colors depend on the z value. This is2.3 Lab: Introduction to R
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47
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known as a heatmap, and is sometimes used to plot temperature in weather heatmap
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forecasts. Alternatively, persp() can be used to produce a three-dimensional
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persp()
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plot. The arguments theta and phi control the angles at which the plot is
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viewed.
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>
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>
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>
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>
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>
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>
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image (x ,y , fa )
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persp (x ,y , fa )
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persp (x ,y , fa , theta =30)
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persp (x ,y , fa , theta =30 , phi =20)
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persp (x ,y , fa , theta =30 , phi =70)
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persp (x ,y , fa , theta =30 , phi =40)
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2.3.3 Indexing Data
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We often wish to examine part of a set of data. Suppose that our data is
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stored in the matrix A .
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> A = matrix (1:16 ,4 ,4)
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> A
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[ ,1] [ ,2] [ ,3] [ ,4]
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[1 ,]
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1
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5
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9
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13
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[2 ,]
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2
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6
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10
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14
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[3 ,]
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3
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7
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11
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15
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[4 ,]
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4
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8
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12
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16
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Then, typing
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> A [2 ,3]
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[1] 10
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will select the element corresponding to the second row and the third col-
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umn. The first number after the open-bracket symbol [ always refers to
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the row, and the second number always refers to the column. We can also
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select multiple rows and columns at a time, by providing vectors as the
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indices.
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> A [ c (1 ,3) , c (2 ,4) ]
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[ ,1] [ ,2]
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[1 ,]
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5
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13
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[2 ,]
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7
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15
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> A [1:3 ,2:4]
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[ ,1] [ ,2] [ ,3]
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[1 ,]
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5
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9
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13
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[2 ,]
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6
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10
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14
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[3 ,]
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7
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11
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15
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> A [1:2 ,]
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[ ,1] [ ,2] [ ,3] [ ,4]
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[1 ,]
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1
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5
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9
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13
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[2 ,]
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2
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6
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10
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14
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> A [ ,1:2]
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[ ,1] [ ,2]
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[1 ,]
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1
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5
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[2 ,]
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2
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648
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2. Statistical Learning
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[3 ,]
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[4 ,]
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3
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4
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7
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8
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The last two examples include either no index for the columns or no index
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for the rows. These indicate that R should include all columns or all rows,
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respectively. R treats a single row or column of a matrix as a vector.
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> A [1 ,]
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[1] 1 5
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9 13
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The use of a negative sign - in the index tells R to keep all rows or columns
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except those indicated in the index.
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> A [ - c (1 ,3) ,]
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[ ,1] [ ,2] [ ,3] [ ,4]
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[1 ,]
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2
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6
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10
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14
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[2 ,]
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4
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8
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12
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16
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> A [ - c (1 ,3) ,-c (1 ,3 ,4) ]
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[1] 6 8
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The dim() function outputs the number of rows followed by the number of
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dim()
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columns of a given matrix.
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> dim ( A )
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[1] 4 4
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2.3.4 Loading Data
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For most analyses, the first step involves importing a data set into R . The
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read.table() function is one of the primary ways to do this. The help file
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read.table()
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contains details about how to use this function. We can use the function
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write.table() to export data.
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write.
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Before attempting to load a data set, we must make sure that R knows table()
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to search for the data in the proper directory. For example on a Windows
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system one could select the directory using the Change dir. . . option under
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the File menu. However, the details of how to do this depend on the op-
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erating system (e.g. Windows, Mac, Unix) that is being used, and so we
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do not give further details here. We begin by loading in the Auto data set.
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This data is part of the ISLR library (we discuss libraries in Chapter 3) but
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to illustrate the read.table() function we load it now from a text file. The
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following command will load the Auto.data file into R and store it as an
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object called Auto , in a format referred to as a data frame. (The text file data frame
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can be obtained from this book’s website.) Once the data has been loaded,
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the fix() function can be used to view it in a spreadsheet like window.
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However, the window must be closed before further R commands can be
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entered.
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> Auto = read . table (" Auto . data ")
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> fix ( Auto )2.3 Lab: Introduction to R
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49
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Note that Auto.data is simply a text file, which you could alternatively
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open on your computer using a standard text editor. It is often a good idea
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to view a data set using a text editor or other software such as Excel before
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loading it into R .
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This particular data set has not been loaded correctly, because R has
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assumed that the variable names are part of the data and so has included
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them in the first row. The data set also includes a number of missing
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observations, indicated by a question mark ? . Missing values are a common
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occurrence in real data sets. Using the option header=T (or header=TRUE ) in
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the read.table() function tells R that the first line of the file contains the
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variable names, and using the option na.strings tells R that any time it
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sees a particular character or set of characters (such as a question mark),
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it should be treated as a missing element of the data matrix.
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> Auto = read . table (" Auto . data " , header =T , na . strings ="?")
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> fix ( Auto )
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Excel is a common-format data storage program. An easy way to load such
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data into R is to save it as a csv (comma separated value) file and then use
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the read.csv() function to load it in.
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> Auto = read . csv (" Auto . csv " , header =T , na . strings ="?")
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> fix ( Auto )
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> dim ( Auto )
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[1] 397 9
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> Auto [1:4 ,]
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The dim() function tells us that the data has 397 observations, or rows, and
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dim()
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nine variables, or columns. There are various ways to deal with the missing
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data. In this case, only five of the rows contain missing observations, and
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so we choose to use the na.omit() function to simply remove these rows.
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na.omit()
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> Auto = na . omit ( Auto )
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> dim ( Auto )
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[1] 392
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9
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Once the data are loaded correctly, we can use names() to check the
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names()
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variable names.
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> names ( Auto )
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[1] " mpg "
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[5] " weight "
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[9] " name "
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" cylinders "
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" d i s p l a c e m e n t " " horsepower "
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" a c c e l e r a t i o n " " year "
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" origin "
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2.3.5 Additional Graphical and Numerical Summaries
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We can use the plot() function to produce scatterplots of the quantitative
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variables. However, simply typing the variable names will produce an error
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message, because R does not know to look in the Auto data set for those
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variables.
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scatterplot50
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2. Statistical Learning
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> plot ( cylinders , mpg )
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Error in plot ( cylinders , mpg ) : object ’ cylinders ’ not found
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To refer to a variable, we must type the data set and the variable name
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joined with a $ symbol. Alternatively, we can use the attach() function in
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attach()
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order to tell R to make the variables in this data frame available by name.
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> plot ( Auto$cylinders , Auto$mpg )
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> attach ( Auto )
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> plot ( cylinders , mpg )
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The cylinders variable is stored as a numeric vector, so R has treated it
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as quantitative. However, since there are only a small number of possible
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values for cylinders , one may prefer to treat it as a qualitative variable.
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The as.factor() function converts quantitative variables into qualitative
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as.factor()
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variables.
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> cylinders = as . factor ( cylinders )
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If the variable plotted on the x-axis is categorial, then boxplots will
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automatically be produced by the plot() function. As usual, a number
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of options can be specified in order to customize the plots.
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>
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>
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>
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>
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>
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plot ( cylinders ,
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plot ( cylinders ,
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plot ( cylinders ,
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plot ( cylinders ,
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plot ( cylinders ,
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ylab =" MPG ")
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mpg )
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mpg ,
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mpg ,
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mpg ,
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mpg ,
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boxplot
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col =" red ")
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col =" red " , varwidth = T )
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col =" red " , varwidth =T , horizontal = T )
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col =" red " , varwidth =T , xlab =" cylinders " ,
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The hist() function can be used to plot a histogram. Note that col=2
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hist()
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has the same effect as col="red" .
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histogram
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> hist ( mpg )
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> hist ( mpg , col =2)
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> hist ( mpg , col =2 , breaks =15)
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The pairs() function creates a scatterplot matrix i.e. a scatterplot for every
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pair of variables for any given data set. We can also produce scatterplots
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for just a subset of the variables.
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scatterplot
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matrix
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> pairs ( Auto )
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> pairs (∼ mpg + d i s p l a c e m e n t + horsepowe r + weight +
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acceleration , Auto )
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In conjunction with the plot() function, identify() provides a useful
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identify()
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interactive method for identifying the value for a particular variable for
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points on a plot. We pass in three arguments to identify() : the x-axis
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variable, the y-axis variable, and the variable whose values we would like
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to see printed for each point. Then clicking on a given point in the plot
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will cause R to print the value of the variable of interest. Right-clicking on
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the plot will exit the identify() function (control-click on a Mac). The
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numbers printed under the identify() function correspond to the rows for
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the selected points.2.3 Lab: Introduction to R
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51
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> plot ( horsepower , mpg )
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> identify ( horsepower , mpg , name )
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The summary() function produces a numerical summary of each variable in
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summary()
|
||
a particular data set.
|
||
> summary ( Auto )
|
||
mpg
|
||
Min .
|
||
: 9.00
|
||
1 st Qu .:17.00
|
||
Median :22.75
|
||
Mean
|
||
:23.45
|
||
3 rd Qu .:29.00
|
||
Max .
|
||
:46.60
|
||
cylinders
|
||
Min .
|
||
:3.000
|
||
1 st Qu .:4.000
|
||
Median :4.000
|
||
Mean
|
||
:5.472
|
||
3 rd Qu .:8.000
|
||
Max .
|
||
:8.000
|
||
horsepower
|
||
Min .
|
||
: 46.0
|
||
1 st Qu .: 75.0
|
||
Median : 93.5
|
||
Mean
|
||
:104.5
|
||
3 rd Qu .:126.0
|
||
Max .
|
||
:230.0 weight
|
||
Min .
|
||
:1613
|
||
1 st Qu .:2225
|
||
Median :2804
|
||
Mean
|
||
:2978
|
||
3 rd Qu .:3615
|
||
Max .
|
||
:5140
|
||
year
|
||
Min .
|
||
:70.00
|
||
1 st Qu .:73.00
|
||
Median :76.00
|
||
Mean
|
||
:75.98
|
||
3 rd Qu .:79.00
|
||
Max .
|
||
:82.00 origin
|
||
Min .
|
||
:1.000
|
||
1 st Qu .:1.000
|
||
Median :1.000
|
||
Mean
|
||
:1.577
|
||
3 rd Qu .:2.000
|
||
Max .
|
||
:3.000
|
||
displacement
|
||
Min .
|
||
: 68.0
|
||
1 st Qu .:105.0
|
||
Median :151.0
|
||
Mean
|
||
:194.4
|
||
3 rd Qu .:275.8
|
||
Max .
|
||
:455.0
|
||
acceleration
|
||
Min .
|
||
: 8.00
|
||
1 st Qu .:13.78
|
||
Median :15.50
|
||
Mean
|
||
:15.54
|
||
3 rd Qu .:17.02
|
||
Max .
|
||
:24.80
|
||
name
|
||
amc matador
|
||
: 5
|
||
ford pinto
|
||
: 5
|
||
toyota corolla
|
||
: 5
|
||
amc gremlin
|
||
: 4
|
||
amc hornet
|
||
: 4
|
||
chevrolet chevette : 4
|
||
( Other )
|
||
:365
|
||
For qualitative variables such as name , R will list the number of observations
|
||
that fall in each category. We can also produce a summary of just a single
|
||
variable.
|
||
> summary ( mpg )
|
||
Min . 1 st Qu .
|
||
9.00
|
||
17.00
|
||
Median
|
||
22.75
|
||
Mean 3 rd Qu .
|
||
23.45
|
||
29.00
|
||
Max .
|
||
46.60
|
||
Once we have finished using R , we type q() in order to shut it down, or
|
||
q()
|
||
quit. When exiting R , we have the option to save the current workspace so
|
||
workspace
|
||
that all objects (such as data sets) that we have created in this R session
|
||
will be available next time. Before exiting R , we may want to save a record
|
||
of all of the commands that we typed in the most recent session; this can
|
||
be accomplished using the savehistory() function. Next time |