If your IDs are relatively short (15 bytes or less) then I suggest encrypting them with a block cipher, namely the AES. The AES uses a secret key *K*, which has length 128, 192 or 256 bits (128 bits are enough). Since AES processes a block of exactly 16 bytes, you have to pad your ID a bit. The "usual" padding (known as "PKCS#5") consists in adding *n* bytes (*n >= 1*), all of them having value *n*, such that the resulting length is appropriate (here, you want a length of 16).

So the transformation of *ID* (the sensitive data) into *S* (the scrambled string which can be shown to the public at large) is: *S = AESencrypt_K(pad(ID))*. The reverse operation is: *ID = unpad(AESdecrypt_K(S))*. If *ID* is 16 bytes or more, then encryption will use several invocations of AES, and there are subtleties with regards to how those invocations are linked together. The keyword is *chaining mode* and the usual answer is "CBC".

Knowledge of the secret key *K* (the same *K*) is needed for both operations. This means that whoever can compute *S* from *ID* can also compute *ID* from *S*, and vice versa.

Now if you need some entities to be able to compute *S* from *ID* without giving them the power to do the reverse operation, then things are more complex. In particular, you must not have a deterministic process: if there is a single *S* which can be computed from *ID* then anybody can try an exhaustive search on the possible values of *ID* until a match with a given *S* is found. So you have to relax the model, in that a given *ID* may yield a great number of possible scrambled strings *S'*, such that all those *S'* may be converted back into *ID* by someone who has the "right" secret value. This is what you would get from asymmetric encryption. The usual asymmetric encryption algorithm is RSA. With a 1024-bit RSA key (a typical size for proper security), *ID* could have a size up to 117 bytes, and *S'* will be 128-byte long (the size increase corresponds to the injected random data which makes the process non-deterministic). If 128 bytes are too much, you can get shorter encrypted messages with El-Gamal encryption over elliptic curves (down to about 40 bytes or so, for an up-to-20-byte *ID*), but you may have a hard time finding an existing implementation.