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Example of a Key Derivation Function chain as used in the Signal Protocol.The output of one KDF function is the input to the next KDF function in the chain. In cryptography, a key derivation function (KDF) is a cryptographic algorithm that derives one or more secret keys from a secret value such as a master key, a password, or a passphrase using a pseudorandom function (which typically uses a ...
[1] [2] [3] This shared secret may be directly used as a key, or to derive another key. The key, or the derived key, can then be used to encrypt subsequent communications using a symmetric-key cipher. It is a variant of the Diffie–Hellman protocol using elliptic-curve cryptography.
The shared secret can be used, for instance, as the key for a symmetric cipher, which will be, in essentially all cases, much faster. In an asymmetric key encryption scheme, anyone can encrypt messages using a public key, but only the holder of the paired private key can decrypt such a message.
In cryptography, a shared secret is a piece of data, known only to the parties involved, in a secure communication. This usually refers to the key of a symmetric cryptosystem . The shared secret can be a PIN code , a password , a passphrase , a big number, or an array of randomly chosen bytes.
Once Alice and Bob compute the shared secret they can use it as an encryption key, known only to them, for sending messages across the same open communications channel. Of course, much larger values of a , b , and p would be needed to make this example secure, since there are only 23 possible results of n mod 23.
The keys, in practice, represent a shared secret between two or more parties that can be used to maintain a private information link. [2] The requirement that both parties have access to the secret key is one of the main drawbacks of symmetric -key encryption, in comparison to public-key encryption (also known as asymmetric-key encryption).
The cipher family was chosen as a finalist of the CAESAR Competition [3] in February 2019. NIST had announced its decision on February 7, 2023 [3] with the following intermediate steps that would lead to the eventual standardization: [2] Publication of NIST IR 8454 describing the process of evaluation and selection that was used;
Iraqi Block Cipher (IBC) KASUMI – 64-bit block; based on MISTY1, adopted for next generation W-CDMA cellular phone security; KHAZAD – 64-bit block designed by Barretto and Rijmen; Khufu and Khafre – 64-bit block ciphers; Kuznyechik – Russian 128-bit block cipher, defined in GOST R 34.12-2015 and RFC 7801.