Assuming we're dealing with a sequential integer vector 1:n. This may help you:

```
## Given
V <- 1:10e8
n <- length(V)
## To get median,
median <- ifelse(n %% 2 == 0, mean(V [(n/2):((n/2) + 1)]), V [(n + 1)/2])
median
OUTPUT: 5e+08
## To get mean,
sum_series <- n*(n + 1) / 2 # Mathematical Fact
mean <- sum_series / n
mean
OUTPUT: 5e+08
```

For large random vectors, the median still works the same. The mean you can estimate if it doesn't have a closed formula:

```
### Estimation via Repeated Sampling ###
est_mean <- function (V, k, size) {
# k: Number of means to use in estimation
# size: Sample size of each estimation
est <- rep(NA, k)
samp <- matrix(NA, nrow = size, ncol = k)
for (j in 1:k) samp [, j] <- sample(V, size, replace = TRUE)
for (j in 1:k) est [j] <- mean(samp [, j])
est <- sort(est)
return(est [ceiling(length(est)/2)])
}
### Time Complexity of Estimation ###
# samp + est = k*size + k
# If size, k ~ 30 --> Enough to get normal mean distribution
# iterate amount*(create sample vector + store) = k*(size + size)
# --> 2*k*size
# Total = k + 3*k*size --> constant
### Time Complexity of Base R Mean () ###
# Assuming it's this: mean (V) <- sum(V)/length(V)
# sum N items + find length + 1 division + 1 return = N + 3
### Example ###
set.seed(0)
V <- sort(sample(0:10e8, 10e7, replace = TRUE))
start1 <- Sys.time()
est_mu <- est_mean(V, 1000, 30)
end1 <- Sys.time()
diff1 <- end1 - start1
start2 <- Sys.time()
r_mu <- mean (V)
end2 <- Sys.time()
diff2 <- end2 - start2
diff1
OUTPUT: Time difference of 0.08370018 secs
diff2
OUTPUT: Time difference of 0.5321879 secs
print(paste("% Difference = ", abs(r_mu - est_mu)/r_mu))
OUTPUT: "% Difference = 0.00678363793285072"
```

`1:n`

? – F. Privé Aug 10 at 21:35