![Ri-1 and an 8-bit input Ki and produces a 6-bit
output which will be described later.
The output of the ith round is defined as:
Li = Ri-1 and Ri = Li-1 XOR f(Ri-1,Ki)
The decryption is the reverse of encryption.
[Ln] [Rn XOR f(Ln, Kn)] = … =[Rn-1] [Ln-1]](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-6-320.jpg)
![Encryption
[1
]](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-10-320.jpg)
![Encryption (Round)
[1
]
(Key
Generation)](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-14-320.jpg)
![Encryption (Round) (cont.)
F
S-box
[1
]](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-16-320.jpg)
![Encryption (Round) (cont.)
S-box
[1
]](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-19-320.jpg)
![Key Generation
[1
]
(Encryption)](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-20-320.jpg)
![Decryption
The same algorithm as e
ncryption.
Reversed the order of key
(Key16, Key15, … Key1).
For example:
IP undoes IP-1
step of
encryption.
1st round with SK16
undoes 16th encrypt round.
[1
]](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-23-320.jpg)
![References
[1] William Stallings, Cryptography and
Network Security, 1999.](https://image.slidesharecdn.com/ch4-241126032700-e45ecb9a/85/DATA-ENCRYPTION-STANDARD-ALGORITHM-PPT-27-320.jpg)
DATA ENCRYPTION STANDARD ALGORITHM , PPT
- 2. Outline History Encryption Key Generation Decryption Strength of DES Ultimate
- 3. History In 1971, IBM developed an algorithm, named LUCIFER which operates on a block of 64 bits, using a 128-bit key Walter Tuchman, an IBM researcher, refined LUCIFER and reduced the key size to 56-bit, to fit on a chip.
- 4. History In 1977, the results of Tuchman’s project of IBM was adopted as the Data Encryption Standard by NSA (NIST).
- 5. A Simplified DES-Type Algorithm Suppose that a message has 12 bits and is w ritten as L0R0 , where L0 consists of the first 6 bits and R0 consists of the last 6 bits. The key K has 9 bits. The ith round of the alg orithm transforms an input Li-1Ri-1 to the output LiRi using an 8-bit key Ki derived from K. The main part of the encryption process is a f unction f(Ri-1,Ki) that takes a 6-bit input
- 6. Ri-1 and an 8-bit input Ki and produces a 6-bit output which will be described later. The output of the ith round is defined as: Li = Ri-1 and Ri = Li-1 XOR f(Ri-1,Ki) The decryption is the reverse of encryption. [Ln] [Rn XOR f(Ln, Kn)] = … =[Rn-1] [Ln-1]
- 7. The Operations of f Function E(Li)=E(011001)=E(01010101) (Expander) S-boxes S1 101 010 001 110 011 100 111 000 001 100 110 010 000 111 101 011 S2 100 000 110 101 111 001 011 010 101 011 000 111 110 010 001 100 The input for an S-box has 4 bits. The first bit specifies which row will be used: 0 for 1st
- 8. The other 3 bits represent a binary number that specifies the column: 000 for the 1st column, 00 1 for the 2nd column, … 111 for the 7th column. For example, an input 1010 for S1 box will yield the output 110. The key K consists of 9 bits. Ki is the key for the ith round starting with the ith bit of K. Let K=010 011001, then K4=01100101.
- 9. Ri-1=100110 and Ki=01100101 E(Ri-1) XOR Ki =10101010 XOR 01100101 = 11001111 S1(1100)=000 S2(1111)=100 Thus, Ri = f(Ri-1,Ki)=000100, Li =Ri-1 =100110 Li-1Ri-1 = 011100100110 → (?) LiRi 100110011000
- 10. Encryption [1 ]
- 11. Encryption (cont.) Inversion of Initial Permutation (IP-1 ) Key i 64-bit plaintext (X) 32-bit Switch (SW) Initial Permutation (IP) Round (i) 64-bit ciphertext (Y) Key Generation (KeyGen) 64-bit key (K)
- 12. Encryption (cont.) Plaintext: X Initial Permutation: IP( ) Roundi: 1≤ i ≤ 16 32-bit switch: SW( ) Inverse IP: IP-1 ( ) Ciphertext: Y 1 ( ( ( ( ), ))) i i Y IP SW Round IP X Key
- 13. Encryption (IP, IP-1 ) Bit 0 1 2 3 4 5 6 7 1 58 50 42 34 26 18 10 2 9 60 52 44 36 28 20 12 4 17 62 54 46 38 30 22 14 6 25 64 56 48 40 32 24 16 8 33 57 49 41 33 25 17 9 1 41 59 51 43 35 27 19 11 3 49 61 53 45 37 29 21 13 5 57 63 55 47 39 31 23 15 7 IP Bit 0 1 2 3 4 5 6 7 1 40 8 48 16 56 24 64 32 9 39 7 47 15 55 23 63 31 17 38 6 46 14 54 22 62 30 25 37 5 45 13 53 21 61 29 33 36 4 44 12 52 20 60 28 41 35 3 43 11 51 19 59 27 49 34 2 42 10 50 18 58 26 57 33 1 41 9 49 17 57 25 IP-1 Note: IP(IP-1 ) = IP-1 (IP) = I
- 15. Encryption (Round) (cont.) Li Permutation (P) Expansion/permutation (E_table) Substitution/choice (S-box) XOR Ri Li-1 Ri-1 XOR Ki F
- 17. Encryption (Round) (cont.) Separate plaintext as L0R0 L0: left half 32 bits of plaintext R0: right half 32 bits of plaintext Expansion/permutation: E( ) Substitution/choice: S-box( ) Permutation: P( ) 1 1 ( _ ( ( ) ~ )) ~ i i i i R L P S box E R Key 1 i i L R F
- 18. Encryption (Round) (cont.) 32 1 2 3 4 5 4 5 6 7 8 9 8 9 10 11 12 13 12 13 14 45 16 17 16 17 18 19 20 21 20 21 22 23 24 25 24 25 26 27 28 29 28 29 30 31 32 1 16 7 20 21 29 12 28 17 1 15 23 26 5 18 31 10 2 8 24 14 32 27 3 9 9 13 30 6 22 11 4 25 E P Expansion Expansion
- 19. Encryption (Round) (cont.) S-box [1 ]
- 21. Key Generation (cont.) D0 C0 Input Key Permuted Choice One (PC-1) Permuted Choice Two (PC- 2) Schedule of Left Shifts Di-1 Ci-1 Di Ci ▪ ▪ ▪ ▪ ▪ ▪ Keyi
- 22. Key Generation (cont.) Original Key: Key0 Permuted Choice One: PC_1( ) Permuted Choice Two: PC_2( ) Schedule of Left Shift: SLS( ) 0 0 0 ( , ) _ 1( ) C D PC Key 1 1 ( , ) ( , ) i i i i C D SLS C D 1 1 _ 2( ( , )) i i i Key PC SLS C D
- 23. Decryption The same algorithm as e ncryption. Reversed the order of key (Key16, Key15, … Key1). For example: IP undoes IP-1 step of encryption. 1st round with SK16 undoes 16th encrypt round. [1 ]
- 24. Strength of DES Criticism Reduction in key size of 72 bits Too short to withstand with brute-force attack S-boxes were classified. Weak points enable NSA to decipher without key. 56-bit keys have 256 = 7.2 x 1016 values Brute force search looks hard. A machine performing one DES encryption per micros econd would take more than a thousand year to break the cipher.
- 25. Strength of DES (cont.) Avalanche effect in DES If a small change in either the plaintext or the key, the ciphertext should change markedly. DES exhibits a strong avalanche effect.
- 26. Ultimate DES was proved insecure In 1997 on Internet in a few months in 1998 on dedicated h/w (EFF) in a few days In 1999 above combined in 22hrs!
- 27. References [1] William Stallings, Cryptography and Network Security, 1999.