Ok, let me try to solve your problem. As a foreword: I can think of no application where it is sensible to do what you are doing. However, that is for you to judge (non the less I would be interested in the application...)
First, note that the mean of the weighted sums equals the weighted sum of the means, as:
Let's generate some sample data:
timeseries.df <- data.frame(matrix(runif(1000, 1, 10), ncol=40))
n <- 4 # number of items in the convex combination
replications <- 100 # number of replications
Thus, we may first compute the mean of all columns and do all further computations using this mean:
ts.means <- apply(timeseries.df, 2, mean)
Let's create some samples:
samples <- replicate(replications, sample(1:length(ts.means), n))
and the corresponding weights for those samples:
weights <- matrix(runif(replications*n), nrow=n)
# Now norm the weights so that each column sums up to 1:
weights <- weights / matrix(apply(weights, 2, sum), nrow=n, ncol=replications, byrow=T)
That part was a little bit tricky. Run the single functions on each own with a small number of replications to figure out what they are doing. Note that I took a different approach for generating the weights: First get uniformly distributed data and then norm them by their sum. The result should be identical to your approach, but with arbitrary resolution and much better performance.
Again a little bit trick: Get the means for each time series and multiply them with the weights just computed:
ts.weightedmeans <- matrix(ts.means[samples], nrow=n) * weights
# and sum them up:
weights.sum <- apply(ts.weightedmeans, 2, sum)
Now, we are basically done - all information are available and ready to use. The rest is just a matter of correctly formatting the data.frame.
result <- data.frame(t(matrix(names(ts.means)[samples], nrow=n)), t(weights), weights.sum)
# For perfectness, use better names:
colnames(result) <- c(paste("Sample", 1:n, sep=''), paste("Weight", 1:n, sep=''), "WeightedMean")
I would assume this approach to be rather fast - on my system the code took 1.25 seconds with the amount of repetitions you stated.
Final word: You were in luck that I was looking for something that kept me thinking for a while. Your question was not asked in a way to encourage users to think about your problem and give good answers. The next time you have a problem, I would suggest you to read www.whathaveyoutried.com before and try to break down the problem as far as you are able to. The more concrete your problem, the faster and of higher quality your answers will be.
You mentioned correctly that the weights generated above are not uniformly distributed over the whole range of values. (I still have to object that even (0.9, 0.05, 0.025, 0.025) is possible, but it is very unlikely).
Now we are playing in a different league, though. I am pretty sure that the approach you took is not uniformly distributed as well - the probability of the last value being 0.9 is far less than the probability of the first one being that large. Honestly I do not have a good idea ready for you concerning the generation of uniformly distributed random numbers on the unit sphere according to the L_1 distance. (Actually, it is not really a unit sphere, but both problems should be identical).
Thus, I have to give up on this.
I would suggest you to raise a new question at stats.stackexchange.com concerning the generation of those random vectors. It probably is fairly simple using the correct technique. However, I doubt that this question with that heading and a fairly long answer will attract a potential responder... (If you ask the question over there, I would appreciate a link, as I would like to know the solution ;)
Concerning the variance: I do not fully understand which standard deviation you want to compute. If you just want to compute the standard deviation of each time series, why do you not use the built-in function
sd? In the computation above you could just replace
mean by it.
Bootstrapping: That is a whole new question. Separate different topics by starting new questions.