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Road trips can be fun, but they often appear to go slower the closer you get to your destination. I thought up this puzzle while on a recent trip. Thought it would be good food for thought. Curious about the different approaches to solving it.

Suppose you have D miles until you reach your destination. The rule is that the speed at which you travel is equal to the distance to your destination. So when you are 60 miles from your destination your speed must be 60 mph; 50 miles from destination, 50 mph; etc.

How long until you reach your destination?

EDIT: I'm pretty sure that the answer is infinity—you will never get to your destination because you will always be one hour away. I'm curious about how people come up with their solutions. So far, very entertaining.

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    Have you tried formulating this as a function? So distance = speed x time, in this case speed = distance etc.2012-11-27
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    Reminds me of the [Zeno's paradox](http://en.wikipedia.org/wiki/Zeno's_paradoxes#Achilles_and_the_tortoise). Very different though.2012-11-27
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    Note, since speed and distance use different units, this is heavily dependent on your units.2012-11-27
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    Luckily, infinity does not depend on units.2012-11-27
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    You might find the ending of Billy Jonas's song "Wichita" to be of interest. Lyrics at http://www.billyjonas.com/index.php?page=songs&display=57 .2012-11-27
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    @Michael: Amazing! :-)2012-11-27
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    So, I find that so long as you're under something like 5 miles, this remains true for "one hour away", however, you're consuming distance the entire time, and given the average walking speed of a human is greater than 3 mph, then at the 3 mile marker, you're going to either be there in less than an hour, or you're going to piss a lot of people off. Especially given as you can walk there faster than that. Or am I missing the point? Also, as with the dichotomy paradox, the fact that you have introduced a minimum length (Planck, for starters) the infinite indivisible is removed.2012-11-27
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    There is a bottom limit to how infinitesimally small the distances can be, so the equations do not continue forever. You must reach your destination, because you are in a car.2012-11-27
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    Insofar as "how long will it take you to reach your destination as you slowly decrease your rate of travel varying with your distance from the destination?" I believe the answer (intuitively) is something like 2.7 hours away, if you start out 60 miles away, because I recall that the limit of 1 + 1/1 + 1/2 + 1/4 ... is e, and intuitively this sounds like the same "area under the curve" problem as before. However, I'm too mired at work to bother figuring it out, and it doesn't seem like it's much of a curve, more a linear line down. If done accurately, it's a 45 deg angle from (0,60) to (60,0)2012-11-27
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    So it would be the area under the curve of a straight line, no? Ok, I may come back and revisit this later ...2012-11-27
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    @jcolebrand: The sequence (1, 1/2, 1/4, 1/8, ..) represents the remaining normalized distance to the destination at regular time intervals from the current time. The solution is when this sequence reaches zero...2012-11-27
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    almost a duplicate of my recent question: http://math.stackexchange.com/questions/238076/time-required-to-reach-the-goal-when-an-object-will-be-slowing-down-incrementall see also answers there :)2012-11-27
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    @Marek Your recent question was posted one day after I conceived my question. Very odd. I'll be checking the answers there.2012-11-27
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    @MichaelLugo Great find on the lyrics. Strange coincidence that so many are thinking the same thing.2012-11-27
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    This reminds me of a joke I use to begin my classes in differential equations. Somewhere in the USA (where AFAIK the road signs actually have text on them!) a driver sees a sign telling "SPEED LIMIT 60". He slows down to 60mph, and after some time sees a "SPEED LIMIT 50" sign. He slows down etc... Finally he sees a sign saying "WELCOME TO SPEED LIMIT!"2012-11-27
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    US road signs do have text on them, so if there were a town called "Speed Limit" this could theoretically happen.2012-11-28
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    Note that this type of question often gets great different conclusion comparing the theoretical situation and the real situation.2012-11-28
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    @Briguy37 but you have to have atomically sized intervals, they can't be infinitesimally small.2012-11-28
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    @jcolebrand: Yes, our definition of zero in the real world is normally "anything below a sensible minimum distance for the task at hand", so we would eventually "reach" our destination in that respect, whereas in the mathematical world where things are infinitesimally divisible we would never get there.2012-11-28
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    Yeah, that's all I'm saying. If this were Zeno's and you could have zero width, then yes, the trip never ends. But if that's the case, isn't this then just a modern retelling of one of Zeno's?2012-11-28
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    @jcolebrand: The difference is that in Zeno's "paradoxes" (e.g. "Achilles and the Tortoise" and "The Dichotomy Paradox"), the characters travel at a constant speed.2012-11-28
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    I never considered speed to be required for the dichotomy paradox.2012-11-28
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    As long as you get close enough for all practical purposes.2014-05-28

7 Answers 7

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I believe the answer is simply no time at all (with a speed of zero mph). If you're not moving (according to your rules) you are already at your destination. So, (as long as your car is stationary) you are already there and it takes no time to get there.

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    The question asks how long until you reach your destination, so a speed does not answer the question.2012-11-28
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    Thanks for pointing that out, I changed it.2012-11-28
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    No time at all would be correct if you were already there. However, that wouldn't be much of a road trip.2012-11-28
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    Of course not, but it's much better than an infinite road trip. :P2012-11-28
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Your speed is strictly decreasing, so at any time, you know that it takes you at least one hour which would be the arrival time at present speed. So, you cannot reach the destination which is always more than an hour away.

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    ...though you will eventually reach a point where you could get out of your car, take one step and you'd be there.2012-11-27
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    Yes, you might even give the car a little push.2012-11-27
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    As no distance shorter than the Planck length is meaningful, we could instead calculate how much time it takes to be within one Planck length of the destination. Then, we, for all practical purposes, did arrive. So you cannot say you never reach the destination :)2012-11-27
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    As all cars should have a self-distance and should not be a point, and the positions of any objects should be measured from the middle, the front of the car will reach the final position first and you will accept the car "reachs the final position" , provided that the car has sufficient fuel. So no need to consider the issue about the Planck length.2012-11-28
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    @doraemonpaul sure, but I feel like you said the same thing as vsz?2012-11-28
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Put a car following the same rules but which is exactly in the middle between you and your destination, at $D/2$ miles from the destination. It is moving at half of your speed so it stays exactly at half the distance between you and your destination, at all times. So, supposing your journey ends, the other car will arrive exactly at the same time as you at the destination.

However you quickly realize that, since you follow the same rules, the total duration of your trip is the time it takes you to cover half the distance to your destination + the total duration of his trip. So you will arrive strictly after him.

So supposing that the journey ends gives a contradiction : you will stay on the road forever.

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    I like the way you think.2012-11-27
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    Until you hit the other car...2012-11-28
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The existing answers are very good and don't require calculus; nevertheless it seems worthwhile to also show how this would be solved using calculus.

If your position at time $t$ is $x(t)$, your velocity (in appropriate units) is $\dot x(t)=-x(t)$. The general solution of this linear first-order ordinary differential equation is $x(t)=c\,\mathrm e^{-t}$, with arbitrary constant $c$. Thus you get arbitrarily close to your destination, but your speed decreases exponentially and you never reach the destination.

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    You might want to add that your answer proves that we *do* reach the destination "for all practical purposes".2012-11-27
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    If you put in a variable for "this is close enough", I'm thinking you could actually construct an equation describing the time it takes to travel any distance.2012-11-28
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The problem can be written as linear ODE of order 1:

Lets say that $s(t)$ is the driven distance, and $v(t)$ is the speed. Then we have $v(t)=s'(t)$. On the other hand, we have the relation $v(t)=60-s(t)$ and therefore $$s'(t)=60-s(t).$$ This is a linear ODE of first order with constant coefficients, and its solution is $$s(t)=60-60e^{-t}.$$ Now you want $s(t)=60$, so we have $$60=60-60e^{-t}$$ and therefore $$e^{-t}=0.$$ There is no value $t\in\mathbb R$ that fulfills this equation, only the limit $\lim_{t\rightarrow\infty}e^{-t}=0$.

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You are always moving forward as long as the distance is non-zero. Of course, your speed keeps slowing down with distance. So your travel time keeps increasing and asymptotically approaches infinity as your distance asymptotically approaches zero. Others have said "always one hour away" ... to me that is "never" or "infinite time".

Of course, you would have run out of gas far before that and your fellow passengers would have mocked you into shame.

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Set up DE $\dfrac{dx}{dt} = \dfrac{a - x}{T}$, where $a$ and $T$ are constants. Asymptotic behavior with respect to time.

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    Don't sign your answers please. They are automatically signed.2012-11-27