Sure, it sounds like all you'd need to do would be to numerically integrate the acceleration twice to get the distance traveled. For instance, look at
http://stackoverflow.com/questions/153507/calculate-the-position-of-an-accelerating-body-after-a-certain-time

Note that you'll have to subtract gravity from the measured acceleration to get the kinetic acceleration, which is what you should integrate. As for how to do that, re: GoatRider's comment: I might try storing the last measured acceleration whose magnitude was equal to gravity (I think that's 1 in iPhone units?). Then for each acceleration measurement you make whose magnitude is greater than 1, subtract the last known acceleration of gravity - this will need to be a vector subtraction - and use that as the kinetic acceleration. Of course, this assumes that the user keeps the phone in the same orientation throughout the swipe, which I think would be approximately true.

Unfortunately, there's no technique you can use to distinguish between gravitational acceleration and kinetic acceleration in general - that is, a determined user could always find a way to fool whatever algorithm you might come up with. (Trivia: that's called the *equivalence principle*, and it's the foundation of Einstein's theory of general relativity)