User:Jftsang/Bomber problem

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In operations research, the bomber problem asks the following: Suppose that a bomber must travel a further t discrete time steps before reaching its target to drop its bombs. At each step, there is a probability p that it will encounter an enemy fighter. The bomber carries n air-to-air missiles. If it fires k missiles when it encounters a fighter, then it has a probability ${\displaystyle 1-\alpha ^{k}}$ of surviving the encounter (each missile has a probability ${\displaystyle \alpha }$ of missing the fighter). If the bomber encounters a fighter at a given state ${\displaystyle (n,t)}$, let ${\displaystyle k(n,t)}$ be the optimal number of missiles to fire in order to maximise the probability ${\displaystyle V(n,t)}$ that the bomber will reach its target (where ${\displaystyle V(n,0)=1}$). ^[1]

Conjecture

Richard R. Weber has proved that ${\displaystyle k(n,t)}$ is nonincreasing in n and that ${\displaystyle n-k(n,t)}$ is nondecreasing in n. He has also conjectured and attempted to prove that ${\displaystyle k(n,t)}$ is also nondecreasing in n. ^[1]

References

1. Weber, Richard R. "The Bomber Problem". Retrieved 24 June 2012.