# Simulating multiple Poisson processes

I have N processes and a different Poisson rate for each. I would like to simulate arrival times from all N processes. If N =1 I can do this

``````t = 0
N = 1
for i in range(1,10):
t+= random.expovariate(15)
print N, t
``````

However if I have `N = 5` and a list of rates

``````rates =  [10,1,15,4,2]
``````

I would like somehow for the loop to output the arrival times of all N processes in the right order. That is I would still like only two numbers per line (the ID of the process and the arrival time) but globally sorted by arrival time.

I could just make N lists and merge them afterwards but I would like the arrival times to be outputted in the right order in the first place.

Update. One problem is that if you just sample a fixed number of arrivals from each process, you get only early times from the high rate processes. So I think I need to sample from a fixed time interval for each process so the number of samples varies depending on the rate.

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If I'm understanding you correctly:

``````import random
import itertools

def arrivalGenerator(rate):
t = 0
while True:
t += random.expovariate(rate)
yield t

rates = [10, 1, 15, 4, 2]
t = [(i, 0) for i in range(0, len(rates))]
arrivals = []
for i in range(len(rates)):
t = 0
generator = arrivalGenerator(rates[i])
arrivals += [(i, arrival) \
for arrival in itertools.takewhile(lambda t: t < 100, generator)]

sorted_arrivals = sorted(arrivals, key=lambda x: x[1])
for arrival in sorted_arrivals:
print arrival[0], arrival[1]
``````

Note that your initial logic was generating a fixed number of arrivals for each process. What you really want is a specific time window, and to keep generating for a given process until you exceed that time window.

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Thanks but each line should have just two numbers. The ID of the process (a number between 0 and N-1) and the latest arrival time for it. – user2171391 Jul 5 '13 at 14:54
Oh, okay, but in sorted order by arrival time? – jason Jul 5 '13 at 14:56
Yes that is right. The idea being that those IDs with low rates won't appear much at all compared to those with high rates. – user2171391 Jul 5 '13 at 14:57
@felix: I got you. Give me a minute, that's easily derivable from what we already have. – jason Jul 5 '13 at 14:57
@felix: See it now? – jason Jul 5 '13 at 15:02

Following http://www.columbia.edu/~ks20/4703-Sigman/4703-07-Notes-PP-NSPP.pdf I think there is a more efficient answer.

You do roughly:

``````total_rate = sum(rates)
probabilities = [ r/total_rate for r in rates ]

arrivals = []
t = 0
while t < T:
t += random.expovariate(total_rate)
i = weighted_random(probabilities)
arrivals += (i, t)
``````

This method eliminates the need to keep coroutine state around for a large number of different arrival processes. There's just a single "net" arrival process. The distribution will be the same.

Note that I have not given an implementation for weighted_random above, but I assume my intention is clear. It is left as an exercise for the reader ;-) -- or see e.g. http://eli.thegreenplace.net/2010/01/22/weighted-random-generation-in-python.

You can also do:

``````arrivals = []
t = 0
while t < T:
dt_list = [ random.expovariate(r) for r in rates ]
(dt,i) = min((tau,i) for i,tau in enumerate(dt_list))
t += dt
arrivals += (i, t)
``````

i.e., you actually do generate separate interarrival times for all processes, but you do not need to "remember" the states of the processes. Note that the minimum of two independent exponentially-distributed random variables with rates r1 and r2 is itself exponentially distributed with rate r1+r2 (per http://ocw.mit.edu/courses/mathematics/18-440-probability-and-random-variables-spring-2011/lecture-notes/MIT18_440S11_Lecture20.pdf), so this is actually quite similar to the previous code snippet.

Of the two methods I have given here, I think the first is better:

• The first is O( len(arrivals) * log(len(rates)) ) whereas the second is O( len(arrivals) * len(rates) )
• The first requires 2 random numbers from the underlying generator per arrival, whereas the second requires len(rates) random numbers per arrival.
• The first requires 1 evaluation of log (I assume this is how the exponential random variable is generated) per arrival, whereas the second requires O(len(rates)) evaluations of log per arrival.

Also, take all of the above Python syntax with a grain of salt (I have not run it, and I am rusty with Python), and eliminate temporary lists if you like. This is meant as "pseudocode" really; for a fast Monte Carlo simulation you'd probably use C++ (and/or CUDA) anyway.

I know you're probably well past the point of needing this answer, but I hope it can be helpful to others who find this post.

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