After reading chapter 3, analyze the history of Caesar Cypher and its impact on cryptography. You must use at least one scholarly res
After reading chapter 3, analyze the history of Caesar Cypher and its impact on cryptography. You must use at least one scholarly resource. Every discussion posting must be properly APA formatted.
Detailed research is needed.
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Title: Cryptography and Network Security
Authors: Stallings, Williams
Publisher: Pearson
Publication Date: 2018
Edition: 8th
Cryptography and Network Security:
Principles and Practice Eighth Edition
Chapter 3
Classical Encryption Techniques
Copyright © 2020 Pearson Education, Inc. All Rights Reserved.
Copyright © 2020 Pearson Education, Inc. All Rights Reserved.
Definitions (1 of 2)
• Plaintext
– An original message
• Ciphertext
– The coded message
• Enciphering/encryption
– The process of converting from plaintext to ciphertext
• Deciphering/decryption
– Restoring the plaintext from the ciphertext
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Definitions (2 of 2)
• Cryptography
– The area of study of the many schemes used for
encryption
• Cryptographic system/cipher
– A scheme
• Cryptanalysis
– Techniques used for deciphering a message without
any knowledge of the enciphering details
• Cryptology
– The areas of cryptography and cryptanalysis
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Figure 3.1 Simplified Model of
Symmetric Encryption
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Symmetric Cipher Model
• There are two requirements for secure use of conventional
encryption:
– A strong encryption algorithm
– Sender and receiver must have obtained copies of the
secret key in a secure fashion and must keep the key
secure
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Figure 3.2 Model of Symmetric
Cryptosystem
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Cryptographic Systems
• Characterized along three independent dimensions:
• The type of operations used for transforming plaintext to
ciphertext
– Substitution
– Transposition
• The number of keys used
– Symmetric, single-key, secret-key, conventional
encryption
– Asymmetric, two-key, or public-key encryption
• The way in which the plaintext is processed
– Block cipher
– Stream cipher
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Cryptanalysis and Brute-Force Attack
• Cryptanalysis
– Attack relies on the nature of the algorithm plus some
knowledge of the general characteristics of the
plaintext
– Attack exploits the characteristics of the algorithm to
attempt to deduce a specific plaintext or to deduce the
key being used
• Brute-force attack
– Attacker tries every possible key on a piece of
ciphertext until an intelligible translation into plaintext is
obtained
– On average, half of all possible keys must be tried to
achieve success
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Table 3.1 Types of Attacks on
Encrypted Messages
Type of Attack Known to Cryptanalyst
Ciphertext Only • Encryption algorithm
• Ciphertext
Known Plaintext • Encryption algorithm
• Ciphertext
• One or more plaintext–ciphertext pairs formed with the secret key
Chosen Plaintext • Encryption algorithm
• Ciphertext
• Plaintext message chosen by cryptanalyst, together with its corresponding
ciphertext generated with the secret key
Chosen Ciphertext • Encryption algorithm
• Ciphertext
• Ciphertext chosen by cryptanalyst, together with its corresponding decrypted
plaintext generated with the secret key
Chosen Text • Encryption algorithm
• Ciphertext
• Plaintext message chosen by cryptanalyst, together with its corresponding
ciphertext generated with the secret key
• Ciphertext chosen by cryptanalyst, together with its corresponding decrypted
plaintext generated with the secret key
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Encryption Scheme Security
• Unconditionally secure
– No matter how much time an opponent has, it is
impossible for him or her to decrypt the ciphertext
simply because the required information is not there
• Computationally secure
– The cost of breaking the cipher exceeds the value of
the encrypted information
– The time required to break the cipher exceeds the
useful lifetime of the information
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Brute-Force Attack
• Involves trying every possible key until an intelligible
translation of the ciphertext into plaintext is obtained
• On average, half of all possible keys must be tried to
achieve success
• To supplement the brute-force approach, some degree of
knowledge about the expected plaintext is needed, and
some means of automatically distinguishing plaintext from
garble is also needed
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Strong Encryption
• The term strong encryption refers to encryption schemes
that make it impractically difficult for unauthorized persons
or systems to gain access to plaintext that has been
encrypted
• Properties that make an encryption algorithm strong are:
– Appropriate choice of cryptographic algorithm
– Use of sufficiently long key lengths
– Appropriate choice of protocols
– A well-engineered implementation
– Absence of deliberately introduced hidden flaws
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Substitution Technique
• Is one in which the letters of plaintext are replaced by other
letters or by numbers or symbols
• If the plaintext is viewed as a sequence of bits, then
substitution involves replacing plaintext bit patterns with
ciphertext bit patterns
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Caesar Cipher
• Simplest and earliest known use of a substitution cipher
• Used by Julius Caesar
• Involves replacing each letter of the alphabet with the
letter standing three places further down the alphabet
• Alphabet is wrapped around so that the letter following Z
is A
plain: meet me after the toga party
cipher: PHHW PH DIWHU WKH WRJD SDUWB
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Caesar Cipher Algorithm
• Can define transformation as:
a b c d e f g h i j k l m n o p q r s t u v w x y z
D E F G H I J K L M N O P Q R S T U V W X Y Z A B C
• Mathematically give each letter a number
a b c d e f g h i j k l m n o p q r s t u v w x y z
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25
• Algorithm can be expressed as:
c = E(3, p) = (p + 3) mod (26)
• A shift may be of any amount, so that the general Caesar algorithm is:
C = E(k , p ) = (p + k ) mod 26
• Where k takes on a value in the range 1 to 25; the decryption algorithm is
simply:
p = D(k , C ) = (C − k ) mod 26
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Figure 3.3 Brute-Force Cryptanalysis
of Caesar Cipher
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Sample of Compressed Text
Figure 3.4 Sample of Compressed Text
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Monoalphabetic Cipher
• Permutation
– Of a finite set of elements S is an ordered sequence of
all the elements of S , with each element appearing
exactly once
• If the “cipher” line can be any permutation of the 26
alphabetic characters, then there are 26! or greater than
4 x 1026 possible keys
– This is 10 orders of magnitude greater than the key
space for DES
– Approach is referred to as a monoalphabetic
substitution cipher because a single cipher alphabet is
used per message
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Figure 3.5 Relative Frequency of
Letters in English Text
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Monoalphabetic Ciphers
• Easy to break because they
reflect the frequency data of the
original alphabet
• Countermeasure is to provide
multiple substitutes
(homophones) for a single letter
• Digram
– Two-letter combination
– Most common is th
• Trigram
– Three-letter combination
– Most frequent is the
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Playfair Cipher
• Best-known multiple-letter encryption cipher
• Treats digrams in the plaintext as single units and
translates these units into ciphertext digrams
• Based on the use of a 5 × 5 matrix of letters constructed
using a keyword
• Invented by British scientist Sir Charles Wheatstone in
1854
• Used as the standard field system by the British Army in
World War I and the U.S. Army and other Allied forces
during World War II
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Playfair Key Matrix
• Fill in letters of keyword (minus duplicates) from left to right
and from top to bottom, then fill in the remainder of the
matrix with the remaining letters in alphabetic order
• Using the keyword MONARCHY:
M O N A R
C H Y B D
E F G I/J K
L P Q S T
U V W X Z
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Figure 3.6 Relative Frequency of
Occurrence of Letters
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Hill Cipher
• Developed by the mathematician Lester Hill in 1929
• Strength is that it completely hides single-letter frequencies
– The use of a larger matrix hides more frequency
information
– A 3 x 3 Hill cipher hides not only single-letter but also
two-letter frequency information
• Strong against a ciphertext-only attack but easily broken
with a known plaintext attack
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Polyalphabetic Ciphers
• Polyalphabetic substitution cipher
– Improves on the simple monoalphabetic technique by
using different monoalphabetic substitutions as one
proceeds through the plaintext message
• All these techniques have the following features in
common:
– A set of related monoalphabetic substitution rules is
used
– A key determines which particular rule is chosen for a
given transformation
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Vigenère Cipher
• Best known and one of the simplest polyalphabetic
substitution ciphers
• In this scheme the set of related monoalphabetic
substitution rules consists of the 26 Caesar ciphers with
shifts of 0 through 25
• Each cipher is denoted by a key letter which is the
ciphertext letter that substitutes for the plaintext letter a
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Example of Vigenère Cipher
• To encrypt a message, a key is needed that is as long as
the message
• Usually, the key is a repeating keyword
• For example, if the keyword is deceptive, the message “we
are discovered save yourself” is encrypted as:
key: deceptivedeceptivedeceptive
plaintext: wearediscoveredsaveyourself
ciphertext: ZICVTWQNGRZGVTWAVZHCQYGLMGJ
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Vigenère Autokey System
• A keyword is concatenated with the plaintext itself to
provide a running key
• Example:
key: deceptivewearediscoveredsav
plaintext: wearediscoveredsaveyourself
ciphertext: ZICVTWQNGKZEIIGASXSTSLVVWLA
• Even this scheme is vulnerable to cryptanalysis
– Because the key and the plaintext share the same
frequency distribution of letters, a statistical technique
can be applied
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Vernam Cipher
Figure 3.7 Vernam Cipher
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One-Time Pad
• Improvement to Vernam cipher
proposed by an Army Signal
Corp officer, Joseph
Mauborgne
• Use a random key that is as
long as the message so that
the key need not be repeated
• Key is used to encrypt and
decrypt a single message and
then is discarded
• Each new message requires a
new key of the same length as
the new message
• Scheme is unbreakable
– Produces random output
that bears no statistical
relationship to the
plaintext
– Because the ciphertext
contains no information
whatsoever about the
plaintext, there is simply
no way to break the code
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Difficulties
• The one-time pad offers complete security but, in practice, has two
fundamental difficulties:
– There is the practical problem of making large quantities of
random keys
▪ Any heavily used system might require millions of random
characters on a regular basis
– Mammoth key distribution problem
▪ For every message to be sent, a key of equal length is needed
by both sender and receiver
• Because of these difficulties, the one-time pad is of limited utility
– Useful primarily for low-bandwidth channels requiring very high
security
• The one-time pad is the only cryptosystem that exhibits perfect
secrecy (see Appendix F)
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Rail Fence Cipher
• Simplest transposition cipher
• Plaintext is written down as a sequence of diagonals and
then read off as a sequence of rows
• To encipher the message “meet me after the toga party”
with a rail fence of depth 2, we would write:
m e m a t r h t g p r y
e t e f e t e o a a t
Encrypted message is:
MEMATRHTGPRYETEFETEOAAT
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Row Transposition Cipher
• Is a more complex transposition
• Write the message in a rectangle, row by row, and read the
message off, column by column, but permute the order of
the columns
– The order of the columns then becomes the key to the
algorithm
Key: 4 3 1 2 5 6 7
Plaintext: a t t a c k p
o s t p o n e
d u n t i l t
w o a mx y z
Ciphertext: TTNAAPTMTSUOAODWCOIXKNLYPETZ
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Summary
• Present an overview of the main concepts of symmetric
cryptography
• Explain the difference between cryptanalysis and brute-
force attack
• Understand the operation of a monoalphabetic substitution
cipher
• Understand the operation of a polyalphabetic cipher
• Present an overview of the Hill cipher
Copyright © 2020 Pearson Education, Inc. All Rights Reserved.
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