The lion and the zebras

Question

The lion plays a deadly game against a group of 100 zebras that takes place in the steppe (= an infinite plane). The lion starts in the origin with coordinates $(0,0)$, while the 100 zebras may arbitrarily pick their 100 starting positions. The the lion and the group of zebras move alternately:

• In a lion move, the lion moves from its current position to a position at most 100 meters away.
• In a zebra move, one of the 100 zebras moves from its current position to a position at most 100 meters away.
• The lion wins the game as soon as he manages to catch one of the zebras.

Will the lion always win the game after a finite number of moves? Or is there a strategy for the zebras that helps them to survive forever?

Answer 1

Zebras win.

Here is the strategy:

The zebras choose 100 vertical strips on the steppe, each of width 300m. The strips do not intersect. Each zebra promises to stay horizontally centered on its own individual strip.

 

If the lion enters a strip, then the zebra in that strip flees vertically away from the lion until the lion leaves the strip.

It works because:  

The lion cannot kill a zebra on the turn it moves into a strip, because the strips are too wide. And if it is already inside a strip, then the zebra in that strip has just moved 100m away from it, so it cannot catch the zebra.

Answer 2

This is not an answer, but rather a counter to Micael Rize's answer. I don't intend for this to be picking on him, but it is too difficult to explain in a comment, and there are many arguments about his answer, so hopefully this will be persuasive.

In my example, I am going to use only 16 zebras, but it should be obvious that this is can extend to 100 zebras as well.

This is the starting configuration.

Now, lets say the lion chases the zebra to the east. After the first move, that zebra is the closest, so it will move directly away from the lion. Subsequent moves will bring the lion closer to the zebras adjacent to the zebra being chased, so they will have to move as well, always directly on a path from the origin according to the strategy. After a while (trillions of years), you will have the following setup.

Even though the lion looks close to the zebra, since the starting configuration was so immensely large, they are still light years apart and this zebra is in no danger of being eaten. The only reason the lion caught up is that the lion made many more moves than this zebra because the other zebras were forced to move at one point. Now, however, the zebra is able to move every time the lion moves, so can stay in front indefinitely.

In any event, this is where the lion changes tactics. Instead of chasing down the current zebra (pointless), he heads straight north. The zebra will continue to move outwards since it is still the closest. Eventually, you will get to the point where it is no longer the closest zebra, like so.

Now the lion turns back to the pack and chases the closest zebra in the circle (Red). According to the strategy, this zebra can only move outwards from the origin which gets closer to the lion obviously allowing the lion to capture it. The other option along this path is to move closer to the origin. While this is away from the lion, it will eventually meet and surpass the other zebra in red on the opposite side of the circle. Even if we ignore the fact that the other zebras will all move a bit as the lion runs through the centre of the circle, the lion is now chasing two zebras. According to the strategy, they can only move away from the origin, so they will always stay together. Thus, the lion is twice as fast as them and will catch one eventually.

There are probably different strategies that this zebra can take to avoid capture (e.g. taking different paths not directly from the origin), but the current answer is not sufficient to explain how to stay away from the lion.

Answer 3

Later: At the time, I was thinking of a solution similar to Lopsy's, but instead of vertical stripes I had an idea of circular sectors. Each zebra would thus have its own angle of 3,6°. Here is how I put it to words back then:

Zebras can win.

This is not a rigorous proof, but a good proof nonetheless.

The game is lost, if a lion can pick a new point $P$, such that at least two zebras are contained in a circle with a center at $P$ and radius of 100m. That is obvious, then only one zebra can escape in the next turn and at least one gets eaten.

So our objective is: after every zebra move, all zebras have to be more than 100m away from each other - this guarantees lion cannot make a move that would capture two zebras in the same 100m radius circle.

Since a zebra can move 100 meters, that just means it has to have some free space in some direction, e.g. it can move to a new point, not falling into 100m radius of another zebra.

This is easily achievable if we initially place zebras on the border of any convex shape, such as a circle of a square of an adequate size (adequate means each zebra is more than 50m apart).

Answer 4

Answer

Quick answer: The zebras would survive forever.

Simple explanation:

The key concept here is "infinite plane". Since the plane is infinite, positioning is irrelevant, except for the fact that the zebras are placed at great distances from each other and the lion. The closest zebra from the lion simply moves away from the lion in a direction that does not bring it near the path of another zebra. Because the plane is infinite, the zebras can be a nearly infinite distance from each other, thus making their escape paths very easy to avoid other zebras.