So we assume this is a fresh design:
I am not really how much security you want/need and how processing power your device has...
I would make the firmware package consist of two parts - a header and the "real thing".
Both should be encrypted differently and then signed independently plus together (this is the public key cryptography part).
first check the outer signature
then check the signature of header (which must be calculated based on the header, header length plus the password)
The header is encrypted with the password you distribute and contains a list of hashes of the compatible hardware revisions (these hashes are calculated from the hardware revision + password).
The device decrypts the header, hashes its own revision from the EEPROM accordingly (again revision + password) and tries to find a match in the list.
IF it finds a match then it takes the hash of the list in the header.
with the hash of the list it check the signature of the the "real thing" (calculated on the encrypted content plus length plus password plus hash of the list)
if the signature is valid it proceeds decrypting the "real thing" (key would be password + hash of list)
For the signature part you create a cert, sign that cert with your root cert... the derived cert would be embedded into the devices... so you create the signatures with the private key of that cert and check them in the device with the public key.
The above is NOT 100% secure but provides several aspects:
- tampering with package would be always detectable (as long as you don't loose your private key that is)
- it won't be installable on any incompatible hardware revision
- figuring out the scheme wouldn't allow for installation on incompatble hardware revisions (except if your customer somehow modifies your hardware)
IF that is two much calculations etc. you could always simplify the scheme... at the bare minimum I would keep the outer signature and the password...
EDIT - after some discussion (see comments):
The base algorithms to create the "password" I suggest consists of 2 parts - a hashing algorithm and an encryption algorithm:
The respective firmware should be hashed ("good" algorithms are SHA-512, SHA-384, SHA-256, MD5 - "VERY WEAK" algorithm would be CRC32)
The password would be encrypted using either an asymetric algorithm (like RSA, EC etc.) or a symetric algorithm ("strong" ones are AES, Blowfisch etc. - "weak" ones are for example DES - "VERY WEAK" is for example XOR)
The scheme consists of the following steps:
hash the firmware with any of the above hashing algorithms
build a string consisting of part number/ revision number + firmware hash
encrypt the string with any of the above mentioned encryption algorithms (asymetric means you use the private key, symetric means you use the same key for encryption/decryption)
The device need to contain a secret key (which is either the public key if asymetric encryption is used or the key in case of symetric encryption) and the part number/revision number.
Checking the firmware against the password means decrypting the password, hashing the firmware and comparing the part number/revision number and firmware hash...
Security aspects versus processing requirements:
- asymetric encryption means handling big number (1024 bit or bigger)
IF the device is not capable of handling that you should perhaps take a symetric encryption.
- symetric encryption means that IF your customer reads out the key from your hardware he would be able to create "valid passwords" himself while in the asymetric case this won't be possible
- you could stick with hashing only (hash the firmware plus part numerb/revision number) and provide the result as a password but this leaves you open to a customer figuring the algorithm used out and then they can create themselves "valid passwords"
Some relevant links: