# How can I calculate an optimal UDP packet size for a datastream?

Short radio link with a data source attached with a needed throughput of 1280 Kbps over IPv6 with a UDP Stop-and-wait protocol, no other clients or noticeable noise sources in the area. How on earth can I calculate what the best packet size is to minimise overhead?

UPDATE

I thought it would be an idea to show my working so far: IPv6 has a 40 byte header, so including ACK responses, that's 80 bytes overhead per packet. To meet the throughput requirement, 1280 K/p packets need to be sent a second, where p is the packet payload size.

So by my reckoning that means that the total overhead is (1280 K/p)*(80), and throwing that into Wolfram gives a function with no minima, so no 'optimal' value.

I did a lot more math trying to shoehorn bit error rate calculations into there but came up against the same thing; if there's no minima, how do I choose the optimal value?

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Your probably looking for calculations of this sort: sd.wareonearth.com/~phil/net/overhead , also how much bandwidth do you have? –  Binary Nerd May 12 '10 at 1:46
The assumption is that its 802.11, so working with 4,11,22,and 54 Mbps data rates, but I found an example from another college (dutta.csc.ncsu.edu/csc570_fall08/wrap/hw3_sol.pdf) (Question 5) that deals with the question from another angle but does not take bit error rates or data rates into consideration, and when I add these factors in myself, the function is hyperbolic so i cant find minima! Can't win! –  Bolster May 12 '10 at 1:52
So far Ive attempted 3 numerical methods (Timing based assuming a set distance radio link, and packet size based as described above with and without taking loss and retransmission into account) and unless anyone comes up with any nice ideas, I'm out. :( Thanks for the attempt folks. –  Bolster May 12 '10 at 3:00

Your best bet is to use a simulation framework for networks. This is a hard problem, and doesn't have an easy answer.

NS2 or SimPy can help you devise a discrete event simulation to find optimal conditions, if you know your model in terms of packet loss.

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