- Benefits & Drawbacks
- Public Key Infrastructure
- Cryptography Digital signatures
- Message Authentication
- Cryptography Hash functions
- Data Integrity in Cryptography
- Public Key Encryption
- Block Cipher Modes of Operation
- Advanced Encryption Standard
- Triple DES
- Data Encryption Standard
- Feistel Block Cipher
- Block Cipher
- Modern Symmetric Key Encryption
- Traditional Ciphers
- Attacks On Cryptosystem
- Cryptosystems
- Modern Cryptography
- Origin of Cryptography
- Cryptography Tutorial Home
Cryptography Useful Resources
Selected Reading
- Who is Who
- Computer Glossary
- HR Interview Questions
- Effective Resume Writing
- Questions and Answers
- UPSC IAS Exams Notes
Advanced Encryption Standard
The more popular and widely adopted symmetric encryption algorithm pkely to be encountered nowadays is the Advanced Encryption Standard (AES). It is found at least six time faster than triple DES.
A replacement for DES was needed as its key size was too small. With increasing computing power, it was considered vulnerable against exhaustive key search attack. Triple DES was designed to overcome this drawback but it was found slow.
The features of AES are as follows −
Symmetric key symmetric block cipher
128-bit data, 128/192/256-bit keys
Stronger and faster than Triple-DES
Provide full specification and design details
Software implementable in C and Java
Operation of AES
AES is an iterative rather than Feistel cipher. It is based on ‘substitution–permutation network’. It comprises of a series of pnked operations, some of which involve replacing inputs by specific outputs (substitutions) and others involve shuffpng bits around (permutations).
Interestingly, AES performs all its computations on bytes rather than bits. Hence, AES treats the 128 bits of a plaintext block as 16 bytes. These 16 bytes are arranged in four columns and four rows for processing as a matrix −
Unpke DES, the number of rounds in AES is variable and depends on the length of the key. AES uses 10 rounds for 128-bit keys, 12 rounds for 192-bit keys and 14 rounds for 256-bit keys. Each of these rounds uses a different 128-bit round key, which is calculated from the original AES key.
The schematic of AES structure is given in the following illustration −
Encryption Process
Here, we restrict to description of a typical round of AES encryption. Each round comprise of four sub-processes. The first round process is depicted below −
Byte Substitution (SubBytes)
The 16 input bytes are substituted by looking up a fixed table (S-box) given in design. The result is in a matrix of four rows and four columns.
Shiftrows
Each of the four rows of the matrix is shifted to the left. Any entries that ‘fall off’ are re-inserted on the right side of row. Shift is carried out as follows −
First row is not shifted.
Second row is shifted one (byte) position to the left.
Third row is shifted two positions to the left.
Fourth row is shifted three positions to the left.
The result is a new matrix consisting of the same 16 bytes but shifted with respect to each other.
MixColumns
Each column of four bytes is now transformed using a special mathematical function. This function takes as input the four bytes of one column and outputs four completely new bytes, which replace the original column. The result is another new matrix consisting of 16 new bytes. It should be noted that this step is not performed in the last round.
Addroundkey
The 16 bytes of the matrix are now considered as 128 bits and are XORed to the 128 bits of the round key. If this is the last round then the output is the ciphertext. Otherwise, the resulting 128 bits are interpreted as 16 bytes and we begin another similar round.
Decryption Process
The process of decryption of an AES ciphertext is similar to the encryption process in the reverse order. Each round consists of the four processes conducted in the reverse order −
Add round key
Mix columns
Shift rows
Byte substitution
Since sub-processes in each round are in reverse manner, unpke for a Feistel Cipher, the encryption and decryption algorithms needs to be separately implemented, although they are very closely related.
AES Analysis
In present day cryptography, AES is widely adopted and supported in both hardware and software. Till date, no practical cryptanalytic attacks against AES has been discovered. Additionally, AES has built-in flexibipty of key length, which allows a degree of ‘future-proofing’ against progress in the abipty to perform exhaustive key searches.
However, just as for DES, the AES security is assured only if it is correctly implemented and good key management is employed.
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