Egg Drop Problems: They Are All They Are Cracked Up To Be!
Abstract
We illustrate how to invite and excite students about research by exploring higher-dimensional generalizations of the classical egg drop problem, in which the goal is to locate a critical breaking point using the fewest number of trials. Beginning with the one-dimensional case, we prove that with k eggs and N floors, the minimal number of drops in the worst case satisfies P1(k) ≤ k N1/k . We then extend the recursive algorithm to two and three dimensions, proving similar formulas: P2(k) ≤ (k-1)(M+N)1/(k-1) in 2D and P3(k) ≤ (k-2)(L+M+N)1/(k-2) in 3D, and conjecture a general formula for the d-dimensional case. Beyond the critical point problems, we then study the critical line problems, where the breaking condition occurs along x+y=V (with slope -1) or, more generally, α x+β y=V (with the slope of the line unknown). We discuss how one frequently has to pivot from the original problem, which is intractable, to something that can be solved; in our case, using induction and recursion, two standard proof techniques.
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