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I have gas meter readings over three years which I'm trying to graph in R, to highlight the changing daily usage over the months in a year, and to compare different years' usage.

Data sample:

Date,Gas  
02/01/2010,4460.9  
13/01/2010,4543  
04/02/2010,4656  
16/02/2010,4733  
07/03/2010,4842  
26/03/2010,4933.8  

I can calculate the average daily usage from the periodic readings, and plot the whole of the data across several years as a single data series:

A <- read.table("energy.csv", header=TRUE, fill=TRUE, sep=',')
A$Dates <- as.Date(A$Date, format="%d/%m/%Y")
for (j in 2:length(A$Gas)) {
  A$GasDiff[j-1] = A$Gas[j] - A$Gas[j-1]
}
plot(A$Dates, A$GasDiff, type="o", lty=1, pch=20, ylab="Daily Consumption",
     main="Gas Consumption")

But I can't figure out how to get R to automatically split the data into different ?frames? for each year, so that I can plot separate lines for each year. I can manually create different input files with just the data for each year, but it's inelegant, and will need the code changed every year.

I'm sure it's a simple question, but I've stared at manuals, and can't figure it out.

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2 Answers 2

There's no need to split the data into data-frames by year; you can use the ggplot2 package quite easily to differentiate the plots by year. First I'll make up some data:

dts <- as.Date("20050101", '%Y%m%d') + seq(0,1000,15)
A <- data.frame( Dates = dts, Gas = 4000 + cumsum(abs( rnorm(length(dts), 100, 30))))

Next I'll add two columns to A: DayOfYear which is the "day-number" within the year, and the GasDiff column (same as yours but generated more easily, with no loops!):

A <- transform( A,               
               Year = format(Dates, '%Y'),
               DayOfYear = as.numeric( format(Dates, '%j')),
               GasDiff = c(diff( Gas ),NA))

Next we use ggplot2 to first plot all the years one after the other, but with different colors:

require(ggplot2)
ggplot(A, aes(Dates, GasDiff)) + geom_line( aes(colour = Year))

which gives you this: alt text

Alternatively you can plot the different years in a vertical grid:

ggplot(A, aes(DayOfYear, GasDiff)) + geom_line( )  + facet_grid(Year ~ .)

and you get this: alt text

UPDATE: A third way is to plot all the years on the same plot with different colors/points, which may be useful if you are looking for seasonal patterns (but looks bad in my case because I made up random data).

ggplot(A, aes(DayOfYear, GasDiff)) + 
  geom_line( aes(colour = Year) )  + 
  geom_point( aes(shape = Year))

alt text

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Try ggsave(), as in ggsave("/tmp/image.png", width=5, height=4, dpi=72) -- I use it all the time on my Mac instead of saving as PDF, converting, uploading, etc. –  Jeffrey Breen Jan 10 '11 at 2:17
    
@Jeffrey Ah yes of course, that's the way to do it, thanks for pointing it out! –  Prasad Chalasani Jan 10 '11 at 3:07
    
@Prasad - that was quick, and so helpful, giving me just what I'm after. –  jgc Jan 10 '11 at 8:21
    
@Jeffrey, I will also check out ggsave as you suggest. –  jgc Jan 10 '11 at 8:21
    
Updated the plots using ggsave( '*.png') –  Prasad Chalasani Jan 10 '11 at 14:06

Here are the plots corresponding to Prasad's ggplot examples (1) done using xyplot in lattice. (2) After that we show how to do it using xyplot.zoo from the zoo package and then (3) we show how to do each yet again using the plot.zoo which uses the zoo package's classic graphics facilities.

In each of these cases we also show a 4th style which is based on xblocks.

First lets repeat Prasad's setup:

dts <- as.Date("20050101", '%Y%m%d') + seq(0,1000,15)
A <- data.frame( Dates = dts, Gas = 4000 + cumsum(abs( rnorm(length(dts), 100, 30))))

A <- transform( A,               
               Year = format(Dates, '%Y'),
               DayOfYear = as.numeric( format(Dates, '%j')),
               GasDiff = c(diff( Gas ),NA))

Now lets try using lattice

library(lattice) # xyplot
library(latticeExtra) # layer_, panel.xblocks
library(gridExtra) # grid.arrange
library(RColorBrewer) # brewer.pal

png("png1.png")
p1 <- xyplot(GasDiff ~ Dates, group = Year, A, type = "l",
    par.settings = list(superpose.line = list(col = 1:nlevels(A$Year))),
    auto.key = list(lines = TRUE, points = FALSE))

p2 <- xyplot(GasDiff ~ DayOfYear | Year, A, type = "l", layout = c(1, 3))

p3 <- xyplot(GasDiff ~ DayOfYear, A, group = Year, type = "l",
    auto.key = list(lines = TRUE, points = FALSE))

# and here is another style:

myPalette <- brewer.pal(nlevels(A$Year), "Set3")
p4 <- xyplot(GasDiff ~ Dates, A, type = "l", col = 1) + 
    layer_(panel.xblocks(A$Dates, myPalette[A$Year]))

grid.arrange(nrow = 2, p1, p2, p3, p4)
dev.off()

This gives these 4 plots:

alt text

and now lets repeat this using using zoo in conjunction with the lattice and the other packages:

png("png2.png")
library(zoo)
library(lattice)
library(latticeExtra) # layer_, panel.xblocks
library(gridExtra) # grid.arrange
library(RColorBrewer) # brewer.pal

z <- with(A, zoo(GasDiff, Dates))
year <- format(time(z), "%Y")

# split years into separate columns and plot
P1 <- xyplot(do.call("merge", split(z, year)), screen = 1, col = 1:3)

# split years into separate columns and use day.of.year as time
day.of.year <- function(x) as.numeric(format(x, "%j"))
zz <- read.zoo(A[c(1, 5, 3)], FUN = day.of.year, split = 3)
colnames(zz) <- unique(year)
P2 <- xyplot(na.approx(zz, na.rm = FALSE))

P3 <- xyplot(na.approx(zz, na.rm = FALSE), screen = 1, col = 1:3, auto.key = TRUE)

pal <- brewer.pal(nlevels(factor(year)), "Set3")
P4 <- xyplot(z, screen = 1) + layer_(panel.xblocks(time(z), pal[factor(year)]))

grid.arrange(nrow = 2, P1, P2, P3, P4)
dev.off()

Here is the output:

alt text

A third set of ways is to use classic graphics with zoo where we use the same z, zz and pal calculated above:

library(zoo)
library(RColorBrewer) # brewer.pal

png("png3a.png")
plot(do.call("merge", split(z, year)), screen = 1, col = 1:3)
dev.off()
png("png3b.png")
plot(na.approx(zz, na.rm = FALSE))
dev.off()
png("png3c.png")
plot(na.approx(zz, na.rm = FALSE), screen = 1, col = 1:3)
legend("topleft", colnames(zz), lty = 1, col = 1:3, bty = "n")
dev.off()
png("png3d.png")
plot(z, type = "n")
xblocks(time(z), pal[factor(year)])
lines(z)
dev.off()

and here is the output

alt text

alt text

alt text

alt text

share|improve this answer
    
Thanks, @G.G, that's lots of new ways to improve my charting output. Suddenly the lattices etc. don't seem so daunting. –  jgc Jan 10 '11 at 8:23
    
+1 wow nice illustration of multiple plotting method! –  Prasad Chalasani Jan 10 '11 at 11:40
    
G, shouldn't the above na.approx(zz) be na.approx(zz, na.rm = FALSE)? –  bill_080 Jan 10 '11 at 18:45
    
@bill_080, yes you are right. I will fix that. (We only lose a couple of points off the beginning if we don't do it.) –  G. Grothendieck Jan 10 '11 at 23:37

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