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I have a time series for which I want to intelligently interpolate the missing values. The value at a particular time is influenced by a multi-day trend, as well as its position in the daily cycle.

Here is an example in which the tenth observation is missing from myzoo

start <- as.POSIXct("2010-01-01") 
freq <- as.difftime(6, units = "hours") 
dayvals <- (1:4)*10 
timevals <- c(3, 1, 2, 4) 
index <- seq(from = start, by = freq, length.out = 16)
obs <- (rep(dayvals, each = 4) + rep(timevals, times = 4))
myzoo <- zoo(obs, index)
myzoo[10] <- NA

If I had to implement this, I'd use some kind of weighted mean of close times on nearby days, or add a value for the day to a function line fitted to the larger trend, but I hope there already exist some package or functions that apply to this situation?

EDIT: Modified the code slightly to clarify my problem. There are na.* methods that interpolate from nearest neighbors, but in this case they do not recognize that the missing value is at the time that is the lowest value of the day. Maybe the solution is to reshape the data to wide format and then interpolate, but I wouldn't like to completely disregard the contiguous values from the same day. It is worth noting that diff(myzoo, lag = 4) returns a vector of 10's. The solution may lie with some combination of reshape, na.spline, and diff.inv, but I just can't figure it out.

Here are three approaches that don't work: enter image description here

EDIT2. Image produced using the following code.

myzoo <- zoo(obs, index)
myzoo[10] <- NA # knock out the missing point
plot(myzoo, type="o", pch=16) # plot solid line
points(na.approx(myzoo)[10], col = "red")
points(na.locf(myzoo)[10], col = "blue")
points(na.spline(myzoo)[10], col = "green")
myzoo[10] <- 31 # replace the missing point
lines(myzoo, type = "o", lty=3, pch=16) # dashed line over the gap
legend(x = "topleft", 
       legend = c("na.spline", "na.locf", "na.approx"), 
       col=c("green","blue","red"), pch = 1)
share|improve this question
This code does not run. index and obs are not defined. na.approx, na.spline, na.locf and other na.* functions in the zoo package can fill in NA values. –  G. Grothendieck Feb 11 '11 at 0:38
Thanks, pasted the correct block. –  J. Won. Feb 11 '11 at 0:40
Please show the code you used to create the plot and explain what "don't work" means. –  G. Grothendieck Feb 11 '11 at 3:54
@G. Grothendieck: These three interpolation methods do not work because they are based only on neighbors in the time series, without respect to the daily pattern. –  J. Won. Feb 11 '11 at 4:07

2 Answers 2

up vote 9 down vote accepted

Try this:

x <- ts(myzoo,f=4)
fit <- ts(rowSums(tsSmooth(StructTS(x))[,-2]))
tsp(fit) <- tsp(x)

The idea is to use a basic structural model for the time series, which handles the missing value fine using a Kalman filter. Then a Kalman smooth is used to estimate each point in the time series, including any omitted.

I had to convert your zoo object to a ts object with frequency 4 in order to use StructTS. You may want to change the fitted values back to zoo again.

share|improve this answer
Thanks, that does it almost exactly. But here's something strange: the plot shows the first point of fit is pretty far off (by .85), and the sum of (x-fit)^2 is ~0.96. But, if you replace x with x <- ts(rev(myzoo), f = 4) the fit becomes perfect. Any idea what happened? –  J. Won. Feb 11 '11 at 20:13

In this case, I think you want a seasonality correction in the ARIMA model. There's not enough date here to fit the seasonal model, but this should get you started.

start <- as.POSIXct("2010-01-01") 
freq <- as.difftime(6, units = "hours") 
dayvals <- (1:4)*10 
timevals <- c(3, 1, 2, 4) 
index <- seq(from = start, by = freq, length.out = 16)
obs <- (rep(dayvals, each = 4) + rep(timevals, times = 4))
myzoo <- myzoo.orig <- zoo(obs, index)
myzoo[10] <- NA

myzoo.fixed <- na.locf(myzoo)

myarima.resid <- arima(myzoo.fixed, order = c(3, 0, 3), seasonal = list(order = c(0, 0, 0), period = 4))$residuals
myzoo.reallyfixed <- myzoo.fixed
myzoo.reallyfixed[10] <- myzoo.fixed[10] + myarima.resid[10]


In my tests the ARMA(3, 3) is really close, but that's just luck. With a longer time series you should be able to calibrate the seasonal correction to give you good predictions. It would be helpful to have a good prior on what the underlying mechanisms for both the signal and the seasonal correction to get better out of sample performance.

share|improve this answer
added an image. plotting is no trouble: points(na.locf(myzoo)[10], col = "blue") –  J. Won. Feb 11 '11 at 3:09
@jonw -- Oh! I misunderstood. I thought the problem was getting a point. The problem is getting good estimate with this "seasonality", which is really a daily seasonality. I should have tried plotting (I just tried ?points.zoo). –  Richard Herron Feb 11 '11 at 3:47

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