| title: “Most Harmful Weather Events” author: “Kumar Aditya” date: “11 April 2026” output: html_document |
|---|
| Across the United States, tornadoes, excessive heat, and flash floods are most harmful with respect to population health. |
| Across the United States, tornadoes, thunderstorm winds, and flash floods have the greatest economic consequences. |
| Our raw data are taken from [National Weather Service Instruction 10-1605][1]. The events in the database start in the year 1950 and end in November 2011. Fatalities, injuries, and property damage (in dollars) are totalled over that time. |
| [1]: https://d396qusza40orc.cloudfront.net/repdata%2Fpeer2_doc%2Fpd01016005curr.pdf “National Weather Service Instruction 10-1605” |
| Data Processing |
We load our data.
storm.data <- read.csv("repdata_data_StormData.csv", header = TRUE)
We don’t need all the columns.
reduced.storm.data <-
storm.data[,c("EVTYPE", "FATALITIES", "INJURIES", "PROPDMG")]
Normalize event names.
reduced.storm.data$EVTYPE <-
gsub("^HEAT$", "EXCESSIVE HEAT", reduced.storm.data$EVTYPE)
reduced.storm.data$EVTYPE <-
gsub("^TSTM WIND$", "THUNDERSTORM WIND", reduced.storm.data$EVTYPE)
reduced.storm.data$EVTYPE <-
gsub("^THUNDERSTORM WIND$", "THUNDERSTORM WINDS", reduced.storm.data$EVTYPE)
First we aggregate data on fatalities and find which events are the top 10 causes of fatalities.
agg.fatalities.data <-
aggregate(
reduced.storm.data$FATALITIES,
by=list(reduced.storm.data$EVTYPE), FUN=sum, na.rm=TRUE)
colnames(agg.fatalities.data) = c("event.type", "fatality.total")
fatalities.sorted <-
agg.fatalities.data[order(-agg.fatalities.data$fatality.total),]
top.fatalities <- fatalities.sorted[1:10,]
top.fatalities$event.type <-
factor(
top.fatalities$event.type, levels=top.fatalities$event.type,
ordered=TRUE)
We next do the same for injuries.
agg.injuries.data <-
aggregate(
reduced.storm.data$INJURIES,
by=list(reduced.storm.data$EVTYPE), FUN=sum, na.rm=TRUE)
colnames(agg.injuries.data) = c("event.type", "injury.total")
injuries.sorted <- agg.injuries.data[order(-agg.injuries.data$injury.total),]
top.injuries <- injuries.sorted[1:10,]
top.injuries$event.type <-
factor(
top.injuries$event.type, levels=top.injuries$event.type,
ordered=TRUE)
Finally we do the same for property damage.
agg.prop.dmg.data <-
aggregate(
reduced.storm.data$PROPDMG,
by=list(reduced.storm.data$EVTYPE), FUN=sum, na.rm=TRUE)
colnames(agg.prop.dmg.data) = c("event.type", "prop.dmg.total")
prop.dmg.sorted <- agg.prop.dmg.data[order(-agg.prop.dmg.data$prop.dmg.total),]
top.prop.dmg <- prop.dmg.sorted[1:10,]
top.prop.dmg$event.type <-
factor(
top.prop.dmg$event.type, levels=top.prop.dmg$event.type,
ordered=TRUE)
We graph the top 10 causes of fatalities.
library(ggplot2)
ggplot(data=top.fatalities, aes(x=event.type, y=fatality.total)) +
geom_bar(stat="identity") + xlab("Event type") + ylab("Total fatalities") +
ggtitle("Fatalities By Event Type") +
theme(axis.text.x = element_text(angle = 45, hjust = 1))
We do the same for injuries.
ggplot(data=top.injuries, aes(x=event.type, y=injury.total)) +
geom_bar(stat="identity") + xlab("Event type") + ylab("Total injuries") +
ggtitle("Injuries By Event Type") +
theme(axis.text.x = element_text(angle = 45, hjust = 1))
Finally we do so for property damage.
ggplot(data=top.prop.dmg, aes(x=event.type, y=prop.dmg.total)) +
geom_bar(stat="identity") + xlab("Event type") +
ylab("Total property damage") + ggtitle("Property Damage By Event Type") +
theme(axis.text.x = element_text(angle = 45, hjust = 1))