A data file contains a sequence of 8-bit characters such that all 256 characters are about as common: the maximum character frequency is less than twice the minimum character frequency. Prove that Huffman coding in this case is not more efficient than using an ordinary 8-bit fixed-length code.
closed as not a real question by FelipeAls, Öö Tiib, sgar91, Steven Penny, Matt Fenwick Feb 22 '13 at 1:43
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The proof is direct. Assume w.l.o.g. that the characters are sorted in ascending order of frequency. We know that f(1) and f(2) will be joined first into f'(1), and since f(2) >= f(1) and 2*f(1) > f(256), this won't be joined until after f(256) is joined with something. By the same token, f(3) and f(4) will be joined into f'(2) with f'(2) >= f'(1) > f(256). Continuing thusly, we get f(253) and f(254) joined into f'(127) >= ... >= f'(1) > f(256). Finally, f(255) and f(256) are joined into f'(128) >= f'(127) >= ... >= f'(1). We now recognize that since f(256) < 2*f(1) <= f'(1) and f'(128) <= 2*f(256), f'(128) <= 2*f(256) < 4*f(1) <= 2*f'(1). Ergo, f'(128) < 2*f'(1), the same condition that held for the first round of the Huffman algorithm.
Since the condition holds on this round, it is straightforward to argue that it will similarly hold on all rounds. Huffman will perform 8 rounds until all nodes are joined to one, the root (128, 64, 32, 16, 8, 4, 2, 1), at which point the algorithm will terminate. Since at each stage each node is joined to another one which has, to that point, received the same treatment by the Huffman algorithm, each branch of the tree will have the same length: 8.
This is somewhat informal, more of a sketch than a proof, really, but it should be more than enough for you to write something more formal.