The problem with your question is that the input is larger than the output and unique. If you're expecting a unique output as well, it won't happen. The reason behind this that if you have an input space of say 22 numeric digits (10^22 possibilities) and an output space of hexadecimal digits with a length of 11 digits (16^11 possibilities), you end up with more input possibilities than output possibilities.

The graph below shows that you would need a an output space of 19 hexadecimal digits and a perfect one-to-one function, otherwise you will have collisions pretty often (more than 50% of the time). I assume this is something you do not want, but you did not specify.

Since what you want cannot be done, I would suggest rethinking your design or using a checksum such as the cyclic redundancy check (CRC). CRC-64 will produce a 64 bit output and when encoded with any base64 algorithm, will give you something along the lines of what you want. This does not provide cryptographic strength like SHA-1, so it should never be used in anything related to information security.

However, if you were able to change your criteria to allow for long hash outputs, then I would strongly suggest you look at SHA-512, as it will provide high quality outputs with an extremely low chance of duplication. By a low chance I mean that no two inputs have yet been found to equal the same hash in the history of the algorithm.

If both of these suggestions still are not great for you, then your last alternative is probably just going with only base64 on the input data. It will essentially utilize the standard English alphabet in the best way possible to represent your data, thus reducing the number of characters as much as possible while retaining a complete representation of the input data. This is not a hash function, but simply a method for encoding binary data.

caninsert 4.7^21 unique entries. I'd say that, for all intents and purposes, that's a fairly reasonably expectation. – eouw0o83hf Apr 18 '12 at 19:34