Many times I have seen the set.seed
function in R, before starting the program. I know it's basically used for the random number generation. Is there any specific need to set this?

2This will answer it: stattrek.com/statistics/randomnumbergenerator.aspx – duffymo Nov 28 '12 at 12:40
The need is the possible desire for reproducible results, which may for example come from trying to debug your program, or of course from trying to redo what it does:
These two results we will "never" reproduce as I just asked for something "random":
R> sample(LETTERS, 5)
[1] "K" "N" "R" "Z" "G"
R> sample(LETTERS, 5)
[1] "L" "P" "J" "E" "D"
These two, however, are identical because I set the seed:
R> set.seed(42); sample(LETTERS, 5)
[1] "X" "Z" "G" "T" "O"
R> set.seed(42); sample(LETTERS, 5)
[1] "X" "Z" "G" "T" "O"
R>
There is vast literature on all that; Wikipedia is a good start. In essence, these RNGs are called Pseudo Random Number Generators because they are in fact fully algorithmic: given the same seed, you get the same sequence. And that is a feature and not a bug.

5Thanks Dirk, for such nice example..I have cleared it with 99%, but still question. 1. In your answer you have used set.seed with 42 as argument..is there any related reason for choosing this value ? – Vignesh Nov 29 '12 at 7:57

45For a normal RNG of decent quality, the value doesn't matter. "42" is a reference to a famous book; other people use their birthday or "123" or just "1". – Dirk Eddelbuettel Nov 30 '12 at 1:30

7The
char2seed
function in the TeachingDemos package allows you to set the seed (or choose a seed to pass intoset.seed
) based on a character string. For example you could have students use their name as the seed then each student has a unique dataset but the instructor can also create the same datasets for grading. – Greg Snow Dec 6 '12 at 22:26 
8It is possible to rerun the same code with different seeds until you get the "best" result (I have done this for examples). To guard against accusations of doing this it is best to choose a seed that has some obvious meaning, either always the same seed, or the date, or I use
char2seed
and the last name of the principle investigator on a project. – Greg Snow Dec 6 '12 at 22:28 
6@DirkEddelbuettel seed value can matter for noncomputational reasons, a friend of mine had problems with publishing his simulationbased results because the code started with
set.seed(666)
and the reviewers did not like the Devils seed in the code... – Tim Oct 23 '15 at 8:25
You have to set seed every time you want to get a reproducible random result.
set.seed(1)
rnorm(4)
set.seed(1)
rnorm(4)
Just adding some addition aspects. Need for setting seed: In the academic world, if one claims that his algorithm achieves, say 98.05% performance in one simulation, others need to be able to reproduce it.
?set.seed
Going through the help file of this function, these are some interesting facts:
(1) set.seed() returns NULL, invisible
(2) "Initially, there is no seed; a new one is created from the current time and the process ID when one is required. Hence different sessions will give different simulation results, by default. However, the seed might be restored from a previous session if a previously saved workspace is restored.", this is why you would want to call set.seed() with same integer values the next time you want a same sequence of random sequence.
Fixing the seed is essential when we try to optimize a function that involves randomly generated numbers (e.g. in simulation based estimation). Loosely speaking, if we do not fix the seed, the variation due to drawing different random numbers will likely cause the optimization algorithm to fail.
Suppose that, for some reason, you want to estimate the standard deviation (sd) of a meanzero normal distribution by simulation, given a sample. This can be achieved by running a numerical optimization around steps
 (Setting the seed)
 Given a value for sd, generate normally distributed data
 Evaluate the likelihood of your data given the simulated distributions
The following functions do this, once without step 1., once including it:
# without fixing the seed
simllh < function(sd, y, Ns){
simdist < density(rnorm(Ns, mean = 0, sd = sd))
llh < sapply(y, function(x){ simdist$y[which.min((x  simdist$x)^2)] })
return(sum(log(llh)))
}
# same function with fixed seed
simllh.fix.seed < function(sd,y,Ns){
set.seed(48)
simdist < density(rnorm(Ns,mean=0,sd=sd))
llh < sapply(y,function(x){simdist$y[which.min((xsimdist$x)^2)]})
return(sum(log(llh)))
}
We can check the relative performance of the two functions in discovering the true parameter value with a short Monte Carlo study:
N < 20; sd < 2 # features of simulated data
est1 < rep(NA,1000); est2 < rep(NA,1000) # initialize the estimate stores
for (i in 1:1000) {
as.numeric(Sys.time())> t; set.seed((t  floor(t)) * 1e8 > seed) # set the seed to random seed
y < rnorm(N, sd = sd) # generate the data
est1[i] < optim(1, simllh, y = y, Ns = 1000, lower = 0.01)$par
est2[i] < optim(1, simllh.fix.seed, y = y, Ns = 1000, lower = 0.01)$par
}
hist(est1)
hist(est2)
The resulting distributions of the parameter estimates are:
When we fix the seed, the numerical search ends up close to the true parameter value of 2 far more often.
basically set.seed() function will help to reuse the same set of random variables , which we may need in future to again evaluate particular task again with same random varibales
we just need to declare it before using any random numbers generating function.