Problem Set 1

Visualization Process

Directions

During ANLY 512 we will be studying the theory and practice of data visualization. We will be using R and the packages within R to assemble data and construct many different types of visualizations. We begin by studying some of the theoretical aspects of visualization. To do that we must appreciate the actual steps in the process of making a visualization.

Most of us use softare to do this and have done so for so long that we have lost an appreciation for the mechanistic steps involved in accurately graphing data. We will fix that this week by creating a series of analog (meaning you draw them by hand) graphics. The visualizations you create must be numerically and visually accurate and precisely scaled. Because of that the data sets we visualize will be small.

• A couple of tips, remember that there is preprocessing involved in many graphics so you may have to do summaries or calculations to prepare, those should be included in your work.

• To ensure accuracy pay close attention to axes and labels, you will be evaluated based on the accuracy of your graphics.

The final product of your homework (this file) should include scanned or photographed images for each question below and a short summary of the process.

To submit this homework you will create the document in Rstudio, using the knitr package (button included in Rstudio) and then submit the document to your Rpubs account. Once uploaded your will submit the link to that document on Moodle.

Questions

Find the mtcars data in R. This is the dataset that you will use to create your graphics. Use that data to draw by hand graphics for the next 4 questions.

1. Draw a pie chart showing the proportion of cars from the mtcars data set that have different carb values.

library(jpeg)
library(grid)
img <- readJPEG("C:\\Users\\t\\Downloads\\q1.JPG")
 grid.raster(img)

"Took the count of rows by per carb, then divided it by the total row count to get the size of each slice. Multiplied it by 360 to get the coverage angle." 

## [1] "Took the count of rows by per carb, then divided it by the total row count to get the size of each slice. Multiplied it by 360 to get the coverage angle."

2. Draw a bar graph, that shows the number of each gear type in mtcars.

library(jpeg)
library(grid)
img <- readJPEG("C:\\Users\\t\\Downloads\\q2.JPG")
 grid.raster(img)

"Took the count of rows by per gear and plotted one bar for each gear. The height of each bar = number of row * 1 mm" 

## [1] "Took the count of rows by per gear and plotted one bar for each gear. The height of each bar = number of row * 1 mm"

3. Next show a stacked bar graph of the number of each gear type and how they are further divded out by cyl.

library(jpeg)
library(grid)
img <- readJPEG("C:\\Users\\t\\Downloads\\q3.JPG")
 grid.raster(img)

"Took the count of rows by per cylinder per gear and plotted one bar for each gear. The height of each stack = number of row per cylinder for that gear * 1 mm"

## [1] "Took the count of rows by per cylinder per gear and plotted one bar for each gear. The height of each stack = number of row per cylinder for that gear * 1 mm"

4. Draw a scatter plot showing the relationship between wt and mpg.

library(jpeg)
library(grid)
img <- readJPEG("C:\\Users\\t\\Downloads\\q4.JPG")
 grid.raster(img)

"Using weight as the x axis and mpg as the y axis. 1 inch= 1 unit weight and 1 cm = 2mpg"

## [1] "Using weight as the x axis and mpg as the y axis. 1 inch= 1 unit weight and 1 cm = 2mpg"

5. Design a visualization of your choice using the data.

library(jpeg)
library(grid)
img <- readJPEG("C:\\Users\\t\\Downloads\\q5.JPG")
 grid.raster(img)

"Relation between Gears and Avg Mpg"

## [1] "Relation between Gears and Avg Mpg"