I came across the following question in this course:

Consider a variation of the Knapsack problem where we have two knapsacks, with integer capacities 𝑊1 and 𝑊2. As usual, we are given 𝑛 items with positive values and positive integer weights. We want to pick subsets 𝑆1,𝑆2 with maximum total value such that the total weights of 𝑆1 and 𝑆1 are at most 𝑊1 and 𝑊2, respectively. Assume that every item fits in either knapsack. Consider the following two algorithmic approaches.

(1) Use the algorithm from lecture to pick a max-value feasible solution 𝑆1 for the first knapsack, and then run it again on the remaining items to pick a max-value feasible solution 𝑆2 for the second knapsack.

(2) Use the algorithm from lecture to pick a max-value feasible solution for a knapsack with capacity 𝑊1+𝑊2, and then split the chosen items into two sets 𝑆1+𝑆2 that have size at most 𝑊1 and 𝑊2, respectively.

Which of the following statements is true?

Algorithm (1) is guaranteed to produce an optimal feasible solution to the original problem provided 𝑊1=𝑊2.

Algorithm (1) is guaranteed to produce an optimal feasible solution to the original problem but algorithm (2) is not.

Algorithm (2) is guaranteed to produce an optimal feasible solution to the original problem but algorithm (1) is not.

Neither algorithm is guaranteed to produce an optimal feasible solution to the original problem.

The "algorithm from lecture" is on YouTube. https://www.youtube.com/watch?v=KX_6OF8X6HQ, which is 0-1 knapsack problem for one bag.

The correct answer to this question is option 4. This, this and this post present solutions to the problem. However, I'm having a hard time finding counterexamples showing that options 1 through 3 are incorrect. Can you cite any?

**Edit:**
The accepted answer doesn't provide a counterexample for option 1; see 2 knapsacks with same capacity - Why can't we just find the max-value twice for that.