Originally posted by Mario S Caner
got4boyz,
Your question can't be answered without some more information. What was your dive profile like, how many dives over how many days... all this matters. It could be 12-24 hours. A computer is great in getting you the info you need accurately.
From John Lipmans book 'Deeper into diving', I read the chapter on flying after diving, and got the distinct impression that all the computers used different methods of calculating no fly time, and the vast majority were WAG's (wild assed guesses). Some wait to complete desaturation, some use long tissue campartments, others mid range tissue compartments, they even use different definitions as to when its safe to fly.
If I've said it once, I've said it 1000 times.
Don't blindly follow a computer.
I have copied from
here some more technical information. for those interested.
On a personal note, I tend to wait 24 hours after diving to fly if at all possible, to allow as much N2 to disperse, any longer and it starts getting unfeasable.
Jon T
5. Flying after diving
In flying we confront a situation where the ambient pressure drops rapidly after the airplane takes off. If the allowable partial pressure in any of the tissues is overstepped by this drop in pressure, symptoms of decompression sickness are likely to arise.
To avoid this situation, the "do not fly" time must be observed after diving. Most dive computers calculate and display this waiting period, which may correspond to the period required for complete desaturation. However, there is considerable variation in the "do not fly" period calculated by different dive computers for the same dive profile. This raises the question of how this waiting period is calculated, and why significant differences are found between the calculations of different dive computers.
According to Bühlmann, the "do not fly" period is the time span after which even the slowest tissue has decompressed sufficiently that even an instantaneous drop in ambient pressure to a specific level will not exceed the partial pressure tolerance of this tissue
- quite a mouthful !
-
This "specific level" in question is the usual cabin pressure of a commercial airliner, equivalent to atmospheric pressure at an altitude of 6000 feet. However, in an emergency, this pressure can drop to ambient levels, and therefore an altitude of 13000 feet may be used to provide a further safety factor. The Aladin dive computers go even further and use an altitude of 15000 feet. But . . .
To further confuse you (or make you think !) here's a small example: after a given dive, the Aladin Air X showed a "do not fly" time of 9 hours, while my buddy's Scubapro DC12 showed 24 hours. TAUSIM, using the same dive profile, calculated a "do not fly" period of 17 hours. (But when a cabin pressure of 6000 feet was stipulated, this dropped to only 13 minutes !) What's the right answer ?
To deepen the confusion even more, it must be noted that the 17 hours "do not fly" time generated by TAUSIM is not accurate either - not even within the framework of the ZH-L16 model ! This is due to the fact that with longer and/or deeper dive simulations the slower tissues show negative values for the argument of the logarithm due to mathematical limitations of the Bühlmann model. Since negative arguments for the algorithm are not allowed, these tissues can't be used in the calculation of the "do not fly" time, and so it is determined using the slowest tissue that still shows a positive value for the argument of the logarithm. This means that the real "do not fly" time is longer than that shown by TAUSIM.
Because of this, one must take as a given, on longer dives, that the actual "do not fly" time is longer than that shown (because the slower tissues have saturated further on such a dive). And this is why TAUSIM also reports, when giving the "do not fly" time, which tissues were included in the calculation. Whenever less than 16 tissues produce a positive argument for the logarithm, then the real "do not fly" time is significantly greater than shown.
Yet we previously mentioned that the Aladin dive computer uses a cabin pressure of 15000 feet for extra safety. How can its "do not fly" time be so much shorter at 9 hours, when one would expect it to be longer compared to times calculated on a cabin pressure of 13000 feet ? It's due to the fact that Aladin dive computers use a mid-range tissue instead of the slowest tissue for the calculation.
Experience has shown that the symptoms of decompression sickness produced by flying to soon occur (predominantly or only ???) in the mid-range (for half-time) tissues.
Thus Uwatec can advertise seemingly more safety with its "do not fly" calculations based on a 15000 feet cabin pressure, while keeping the "do not fly" time quite short. Since the ZH-L8ADT model is safer (more conservative, especially for repetitive dives) than the ZH-L16 model according to Uwatec, one would hardly suspect that the "do not fly" time calculated by the Aladin dive computers might be a bit skimpy! Unfortunately, there is no indication in the user's manual of the Aladin dive computer of the actual compartments used in this calculation. :-(
How does the Scubapro DC12 deal with this situation ? It simply gives the time to complete decompression as the "do not fly" time. Since in using the ZH-L16 model practically every dive profile results in unuseable data for the 4 slowest tissues, the actual "do not fly" time is always longer than that produced by TAUSIM. Simply using the time to complete desaturation as the "do not fly" time assures that one is always safe ! However, it also means that the "do not fly" time resulting from two, three - or sometimes even more ! - dives per day over a period of several days can significantly exceed 24 hours. How many divers would choose to give up diving during the last two days of a week-long dive vacation ?
How do other dive computer manufacturers handle this problem ? On this subject they either plead "trade secrecy" or offer such useless descriptions as "modified Haldane algorithm", without providing any details of the "modification" (in principle the Bühlmann model is a haldanian model, too. - May be, all the different dive computers use the Bühlmann model . . . ???
). This is the dark side of dive computers, which constitutes a significant risk for divers. :-(
Max Hahn has stated that the "do not fly" times of some dive computers are more a product of the influence of strict US product liability considerations informed by the position of the US-dominated Undersea and Hyperbaric Medical Society (UHMS) than of experimental data. According to Hahn, the earlier "do not fly" periods of Bühlmann are too short. A reliable rule of thumb for safe "do not fly" times would be to take 60% of the "do not fly" time shown by the DC12/TRAC.
According to Hahn, the "total decompression" time (ie. all tissues clear of N2 excess pressure) calculated by various dive computers is equally unreliable, because it is dependent on the number of bits used to store a value by each computer. Careful review of all the experimental data led Max Hahn to come up with the rule : To fly you must be nitrogen "clean".
Why does flying matter if you are in a pressurized cabin as all commercial flights have? Just curious! 
