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Exercises 12.5 Exercises

2.

Decode ZLOOA WKLVA EHARQ WKHA ILQDO, which was encoded using the cryptosystem in Example 12.1.

3.

Assuming that monoalphabetic code was used to encode the following secret message, what was the original message?

APHUO EGEHP PEXOV FKEUH CKVUE CHKVE APHUO
EGEHU EXOVL EXDKT VGEFT EHFKE UHCKF TZEXO
VEZDT TVKUE XOVKV ENOHK ZFTEH TEHKQ LEROF
PVEHP PEXOV ERYKP GERYT GVKEG XDRTE RGAGA

What is the significance of this message in the history of cryptography?

Hint.

Hint: V = E, E = X (also used for spaces and punctuation), K = R.

4.

What is the total number of possible monoalphabetic cryptosystems? How secure are such cryptosystems?

Hint.

\(26! - 1\)

5.

Prove that a \(2 \times 2\) matrix \(A\) with entries in \({\mathbb Z}_{26}\) is invertible if and only if \(\gcd( \det(A), 26 ) = 1\text{.}\)

6.

Given the matrix

\begin{equation*} A = \begin{pmatrix} 3 & 4 \\ 2 & 3 \end{pmatrix}\text{,} \end{equation*}

use the encryption function \(f({\mathbf p}) = A {\mathbf p} + {\mathbf b}\) to encode the message CRYPTOLOGY, where \({\mathbf b} = ( 2, 5)^\transpose\text{.}\) What is the decoding function?

7.

Encrypt each of the following RSA messages \(x\) so that \(x\) is divided into blocks of integers of length \(2\text{;}\) that is, if \(x = 142528\text{,}\) encode \(14\text{,}\) \(25\text{,}\) and \(28\) separately.

  1. \(\displaystyle n = 3551, E = 629, x = 31\)

  2. \(\displaystyle n = 2257, E = 47, x = 23\)

  3. \(\displaystyle n = 120979, E = 13251, x = 142371\)

  4. \(\displaystyle n = 45629, E = 781, x = 231561\)

Hint.

(a) \(2791\text{;}\) (c) \(112135 25032 442\text{.}\)

8.

Compute the decoding key \(D\) for each of the encoding keys in Exercise 12.5.7.

9.

Decrypt each of the following RSA messages \(y\text{.}\)

  1. \(\displaystyle n = 3551, D = 1997, y = 2791\)

  2. \(\displaystyle n = 5893, D = 81, y = 34\)

  3. \(\displaystyle n = 120979, D = 27331, y = 112135\)

  4. \(\displaystyle n = 79403, D = 671, y = 129381\)

Hint.

(a) \(31\) (c) \(14\text{.}\)

10.

For each of the following encryption keys \((n, E)\) in the RSA cryptosystem, compute \(D\text{.}\)

  1. \(\displaystyle (n, E) = (451, 231)\)

  2. \(\displaystyle (n, E) = (3053, 1921)\)

  3. \(\displaystyle (n, E) = (37986733, 12371)\)

  4. \(\displaystyle (n, E) = (16394854313, 34578451)\)

Hint.

(a) \(n = 11 \cdot 41\text{;}\) (c) \(n = 8779 \cdot 4327\text{.}\)

11.

Encrypted messages are often divided into blocks of \(n\) letters. A message such as THE WORLD WONDERS WHYmight be encrypted as JIW OCFRJ LPOEVYQ IOCbut sent as JIW OCF RJL POE VYQ IOC. What are the advantages of using blocks of \(n\) letters?

12.

Find integers \(n\text{,}\) \(E\text{,}\) and \(X\) such that

\begin{equation*} X^E \equiv X \pmod{n}\text{.} \end{equation*}

Is this a potential problem in the RSA cryptosystem?

13.

Every person in the class should construct an RSA cryptosystem using primes that are \(10\) to \(15\) digits long. Hand in \((n, E)\) and an encoded message. Keep \(D\) secret. See if you can break one another's codes.