Biol20N02 2016
Course Description
With rapid accumulation of genome sequences and digitalized health data, biomedicine is becoming a data-intensive science. This course is a hands-on, computer-based workshop on how to visualize and analyze large quantities of biological data. The course introduces R, a modern statistical computing language and platform. Students will learn to use R to make scatter plots, bar plots, box plots, and other commonly used data-visualization techniques. The course will review statistical methods including hypothesis testing, analysis of frequencies, and correlation analysis. Student will apply these methods to the analysis of genomic and health data such as whole-genome gene expressions and SNP (single-nucleotide polymorphism) frequencies.
This 3-credit experimental course fulfills elective requirements for Biology Major I. Hunter pre-requisites are BIOL100, BIOL102 and STAT113.
Learning Goals
- Be able to use R as a plotting tool to visualize large-scale biological data sets
- Be able to use R as a statistical tool to summarize data and make biological inferences
- Be able to use R as a programming language to automate data analysis
Textbooks
- R Studio (Required): Learning RStudio for R Statistical Computing
- Digital textbook (Required): Data Analysis for the Life Sciences
Exams & Grading
- Attendance (or a note in case of absence) is required
- In-Class Exercises (50 pts).
- Assignments. All assignments should be handed in as hard copies only. Email submission will not be accepted. Late submissions will receive 10% deduction (of the total grade) per day.
- Three Mid-term Exams (3 X 30 pts each = 90 pts)
- Comprehensive Final Exam (50 pts)
- Bonus for active participation in classroom discussions
Course Outline
Feb 2. Introduction & tutorials for R/R studio
- Course overview
- Install R & RStudio on your home computers (Chapter 1. pg. 9)
- Tutorial 1: First R Session (pg. 12)
- Create a new project by navigating: File | New Project | New Directory. Name it project file "Abalone"
- Import abalone data set: Tools | Import DataSet | From Web URL, copy & paste this address: http://archive.ics.uci.edu/ml/machine-learning-databases/abalone/abalone.data
- Assign column names:
colnames(abalone) <- c("Sex", "Length", "Diameter", "Height", "Whole_Weight", "Shucked_weight", "Viscera_weight", "Shell_weight", "Rings")
- Save data into a file:
write.csv(abalone, "abalone.csv", row.names = FALSE)
- Create a new R script: File | New | R script. Type the following commands:
abalone <- read.csv("abalone.csv"); boxplot(Length ~ Sex, data = abalone)
- Save as "abalone.R" using File | Save
- Execute R script:
source("abalone.R")
- Install the notebook package:
install.packages("knitr")
- Compile a Notebook: File | Compile Notebook | HTML | Open in Browser
- Tutorial 2. Writing R Scripts (Chapter 2. pg. 21)
- Tutorial 3. Vector
Assignment #1. Due 2/16, Tuesday (Finalized) |
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Feb 9. No class (Friday Schedule)
Feb 16. Introduction & tutorials for R/R studio
- Tutorial 3: Vector (Continued)
x <- c(1,2,3,4,5) # construct a vector using the c() function
x # show x
2 * x + 1 # arithmetic operations, applied to each element
exp(x) # exponent function (base e)
x <- 1:5 # alternative way to construct a vector, if consecutive
x <- seq(from = -1, to = 14, by = 2) # use the seq() function to create a numeric series
x <- rep(5, times = 10) # use the rep() function to create a vector of same element
x <- rep(NA, times = 10) # pre-define a vector with unknown elements; Use no quotes
# Apply vector functions
length(x)
sum(x)
mean(x)
range(x)
# Access vector elements
x[1]
x[1:3]
x[-2]
# Character vectors
gender <- c("male", "female", "female", "male", "female")
gender[3]
# Logical vectors
is.healthy <- c(TRUE, TRUE, FALSE, TRUE, FALSE) # Use no quotes
is.male <- (gender == "male") # obtain a logic vector by a test
age <- c(60, 43, 72, 35, 47)
is.60 <- (age == 60)
less.60 <- (age <= 43)
is.female <- !is.male # use the logical negate operator (!)
# The which() function returns the indices of TRUE elements
ind.male <- which(is.male)
ind.young <- which(age < 45)
age[ind.young] # obtain ages of young individuals
- Tutorial 4: Matrix
BMI <- c(28, 32, 21, 27, 35) # a vector of body-mass index
bp <- c(124, 145, 127, 133, 140) # a vector of blood pressure
data.1 <- cbind(age, BMI, bp) # create a matrix using column bind function cbind(), individuals in rows
data.1
data.2 <- rbind(age, BMI, bp) # create a matrix using row bind function rbind()
t(data.1) # transpose a matrix: columns to rows & rows to columns
dim(data.1) # dimension of the matrix
colnames(data.1)
rownames(data.1) <- c("subject1", "subject2", "subject3", "subject4", "subject5")
data.1
data.1[3,1] # access the element in row 3, column 1
data.1[2,] # access all elements in row 2
data.1[,2] # access all elements in column 2
matrix(data = 1:12, nrow = 3, ncol =4) # create a matrix with three rows and four columns; filled by column
matrix(data = 1:12, nrow = 3, ncol =4, byrow = TRUE) # filled by row
mat <= matrix(data = NA, nrow = 2, ncol = 3) # create an empty matrix
mat[1,3] <- 5 # assign a value to a matrix element
- Tutorial 5. Data Frame
Assignment #2. Due 2/23, Tuesday |
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