Cyclic code explained

In coding theory, a cyclic code is a block code, where the circular shifts of each codeword gives another word that belongs to the code. They are error-correcting codes that have algebraic properties that are convenient for efficient error detection and correction.

Definition

Let

l{C}

be a linear code over a finite field (also called Galois field)

GF(q)

of block length

l{C}

is called a cyclic code if, for every codeword

c=(c_1,\ldots,c_n)

from

l{C}

, the word

(c_n,c_1,\ldots,c_n-1)

GF(q)ⁿ

obtained by a cyclic right shift of components is again a codeword. Because one cyclic right shift is equal to

n-1

cyclic left shifts, a cyclic code may also be defined via cyclic left shifts. Therefore, the linear code

l{C}

is cyclic precisely when it is invariant under all cyclic shifts.

Cyclic codes have some additional structural constraint on the codes. They are based on Galois fields and because of their structural properties they are very useful for error controls. Their structure is strongly related to Galois fields because of which the encoding and decoding algorithms for cyclic codes are computationally efficient.

Algebraic structure

Cyclic codes can be linked to ideals in certain rings. Let

R=A[x]/(x^n-1)

be a polynomial ring over the finite field

A=GF(q)

. Identify the elements of the cyclic code

with polynomials in

such that

(c_0,\ldots,c_n-1)

maps to the polynomial

c₀+c_1x+ … +c_n-1x^n-1

thus multiplication by

corresponds to a cyclic shift. Then

is an ideal in

, and hence principal, since

is a principal ideal ring. The ideal is generated by the unique monic element in

of minimum degree, the generator polynomial

.This must be a divisor of

x^n-1

. It follows that every cyclic code is a polynomial code.If the generator polynomial

has degree

then the rank of the code

n-d

The idempotent of

is a codeword

such that

e²=e

(that is,

is an idempotent element of

) and

is an identity for the code, that is

e ⋅ c=c

for every codeword

. If

and

are coprime such a word always exists and is unique; it is a generator of the code.

An irreducible code is a cyclic code in which the code, as an ideal is irreducible, i.e. is minimal in

, so that its check polynomial is an irreducible polynomial.

Examples

For example, if

A=F₂

and

n=3

, the set of codewords contained in cyclic code generated by

(1,1,0)

is precisely

((0,0,0),(1,1,0),(0,1,1),(1,0,1))

It corresponds to the ideal in

	3-1)
F
	2[x]/(x

generated by

(1+x)

The polynomial

(1+x)

is irreducible in the polynomial ring, and hence the code is an irreducible code.

The idempotent of this code is the polynomial

x+x²

, corresponding to the codeword

(0,1,1)

Trivial examples

Trivial examples of cyclic codes are

Aⁿ

itself and the code containing only the zero codeword. These correspond to generators

and

x^n-1

respectively: these two polynomials must always be factors of

x^n-1

Over

GF(2)

the parity bit code, consisting of all words of even weight, corresponds to generator

x+1

. Again over

GF(2)

this must always be a factor of

x^n-1

Quasi-cyclic codes and shortened codes

Before delving into the details of cyclic codes first we will discuss quasi-cyclic and shortened codes which are closely related to the cyclic codes and they all can be converted into each other.

Definition

Quasi-cyclic codes:

(n,k)

quasi-cyclic code is a linear block code such that, for some

which is coprime to

, the polynomial

x^bc(x)\pmod{x^n-1}

is a codeword polynomial whenever

c(x)

is a codeword polynomial.

Here, codeword polynomial is an element of a linear code whose code words are polynomials that are divisible by a polynomial of shorter length called the generator polynomial. Every codeword polynomial can be expressed in the form

c(x)=a(x)g(x)

, where

g(x)

is the generator polynomial. Any codeword

(c_0,..,c_n-1)

of a cyclic code

can be associated with a codeword polynomial, namely,

	n-1
\sum
	i=0

	i
c
	ix*

. A quasi-cyclic code with

equal to

is a cyclic code.

Definition

Shortened codes:

(n,k)

linear code is called a proper shortened cyclic code if it can be obtained by deleting

positions from an

(n+b,k+b)

cyclic code.

In shortened codes information symbols are deleted to obtain a desired blocklength smaller than the design blocklength. The missing information symbols are usually imagined to be at the beginning of the codeword and are considered to be 0. Therefore,

−

is fixed, and then

is decreased which eventually decreases

. It is not necessary to delete the starting symbols. Depending on the application sometimes consecutive positions are considered as 0 and are deleted.

All the symbols which are dropped need not be transmitted and at the receiving end can be reinserted. To convert

(n,k)

cyclic code to

(n-b,k-b)

shortened code, set

symbols to zero and drop them from each codeword. Any cyclic code can be converted to quasi-cyclic codes by dropping every

th symbol where

is a factor of

. If the dropped symbols are not check symbols then this cyclic code is also a shortened code.

For correcting errors

Cyclic codes can be used to correct errors, like Hamming codes as cyclic codes can be used for correcting single error. Likewise, they are also used to correct double errors and burst errors. All types of error corrections are covered briefly in the further subsections.

g(x)=x³+x+1

. This polynomial has a zero in Galois extension field

GF(8)

at the primitive element

\alpha

, and all codewords satisfy

l{C}(\alpha)=0

. Cyclic codes can also be used to correct double errors over the field

GF(2)

. Blocklength will be

equal to

2^m-1

and primitive elements

\alpha

and

\alpha³

as zeros in the

GF(2^m)

because we are considering the case of two errors here, so each will represent one error.

The received word is a polynomial of degree

n-1

given as

v(x)=a(x)g(x)+e(x)

where

e(x)

can have at most two nonzero coefficients corresponding to 2 errors.

We define the syndrome polynomial,

S(x)

as the remainder of polynomial

v(x)

when divided by the generator polynomial

g(x)

i.e.

S(x)\equivv(x)\equiv(a(x)g(x)+e(x))\equive(x)\modg(x)

(a(x)g(x))\equiv0\modg(x)

For correcting two errors

Let the field elements

X₁

and

X₂

be the two error location numbers. If only one error occurs then

X₂

is equal to zero and if none occurs both are zero.

Let

S₁={v}(\alpha)

and

S₃={v}(\alpha³⁾

These field elements are called "syndromes". Now because

g(x)

is zero at primitive elements

\alpha

and

\alpha³

, so we can write

S₁=e(\alpha)

and

S₃=e(\alpha³⁾

. If say two errors occur, then

S₁=\alphaⁱ+\alpha^i'

and

S₃=\alpha³ⁱ+\alpha^3i'

And these two can be considered as two pair of equations in

GF(2^m)

with two unknowns and hence we can write

S₁=X₁+X₂

and

S₃=

	3
(X
	1)

	3
(X
	2)

. Hence if the two pair of nonlinear equations can be solved cyclic codes can used to correct two errors.

Hamming code

The Hamming(7,4) code may be written as a cyclic code over GF(2) with generator

1+x+x³

. In fact, any binary Hamming code of the form Ham(r, 2) is equivalent to a cyclic code, and any Hamming code of the form Ham(r,q) with r and q-1 relatively prime is also equivalent to a cyclic code. Given a Hamming code of the form Ham(r,2) with

r\ge3

, the set of even codewords forms a cyclic

[2^r-1,2^r-r-2,4]

-code.

Hamming code for correcting single errors

A code whose minimum distance is at least 3, have a check matrix all of whose columns are distinct and non zero. If a check matrix for a binary code has

rows, then each column is an

-bit binary number. There are

2^m-1

possible columns. Therefore, if a check matrix of a binary code with

d_min

at least 3 has

rows, then it can only have

2^m-1

columns, not more than that. This defines a

(2^m-1,2^m-1-m)

code, called Hamming code.

It is easy to define Hamming codes for large alphabets of size

. We need to define one H

matrix with linearly independent columns. For any word of size

there will be columns who are multiples of each other. So, to get linear independence all non zero

-tuples with one as a top most non zero element will be chosen as columns. Then two columns will never be linearly dependent because three columns could be linearly dependent with the minimum distance of the code as 3.

So, there are

(q^m-1)/(q-1)

nonzero columns with one as top most non zero element. Therefore, a Hamming code is a

[(q^m-1)/(q-1),(q^{m-1)/(q-1)-m]}

code.

Now, for cyclic codes, Let

\alpha

be primitive element in

GF(q^m)

, and let

\beta=\alpha^q-1

. Then

	(q^m-1)/(q-1)
\beta

and thus

\beta

is a zero of the polynomial

	(q^m-1)/(q-1)
x

-1

and is a generator polynomial for the cyclic code of block length

n=(q^m-1)/(q-1)

But for

q=2

\alpha=\beta

. And the received word is a polynomial of degree

n-1

given as

v(x)=a(x)g(x)+e(x)

where,

e(x)=0

xⁱ

where

represents the error locations.

But we can also use

\alphaⁱ

as an element of

GF(2^m)

to index error location. Because

g(\alpha)=0

, we have

v(\alpha)=\alphaⁱ

and all powers of

\alpha

from

2^m-2

are distinct. Therefore, we can easily determine error location

from

\alphaⁱ

unless

v(\alpha)=0

which represents no error. So, a Hamming code is a single error correcting code over

GF(2)

with

n=2^m-1

and

k=n-m

For correcting burst errors

From Hamming distance concept, a code with minimum distance

2t+1

can correct any

errors. But in many channels error pattern is not very arbitrary, it occurs within very short segment of the message. Such kind of errors are called burst errors. So, for correcting such errors we will get a more efficient code of higher rate because of the less constraints. Cyclic codes are used for correcting burst error. In fact, cyclic codes can also correct cyclic burst errors along with burst errors. Cyclic burst errors are defined as

A cyclic burst of length

is a vector whose nonzero components are among

(cyclically) consecutive components, the first and the last of which are nonzero.

In polynomial form cyclic burst of length

can be described as

e(x)=x^ib(x)\mod(xⁿ-1)

with

b(x)

as a polynomial of degree

t-1

with nonzero coefficient

b₀

. Here

b(x)

defines the pattern and

xⁱ

defines the starting point of error. Length of the pattern is given by deg

b(x)+1

. The syndrome polynomial is unique for each pattern and is given by

s(x)=e(x)\modg(x)

A linear block code that corrects all burst errors of length

or less must have at least

check symbols. Proof: Because any linear code that can correct burst pattern of length

or less cannot have a burst of length

or less as a codeword because if it did then a burst of length

could change the codeword to burst pattern of length

, which also could be obtained by making a burst error of length

in all zero codeword. Now, any two vectors that are non zero in the first

components must be from different co-sets of an array to avoid their difference being a codeword of bursts of length

. Therefore, number of such co-sets are equal to number of such vectors which are

q^2t

. Hence at least

q^2t

co-sets and hence at least

check symbol.

This property is also known as Rieger bound and it is similar to the Singleton bound for random error correcting.

Fire codes as cyclic bounds

In 1959, Philip Fire^[1] presented a construction of cyclic codes generated by a product of a binomial and a primitive polynomial. The binomial has the form

x^c+1

for some positive odd integer

.^[2] Fire code is a cyclic burst error correcting code over

GF(q)

with the generator polynomial

g(x)=(x^2t-1-1)p(x)

where

p(x)

is a prime polynomial with degree

not smaller than

and

p(x)

does not divide

x^2t-1-1

. Block length of the fire code is the smallest integer

such that

g(x)

divides

x^n-1

A fire code can correct all burst errors of length t or less if no two bursts

b(x)

and

x^jb'(x)

appear in the same co-set. This can be proved by contradiction. Suppose there are two distinct nonzero bursts

b(x)

and

x^jb'(x)

of length

or less and are in the same co-set of the code. So, their difference is a codeword. As the difference is a multiple of

g(x)

it is also a multiple of

x^2t-1-1

. Therefore,

b(x)=x^jb'(x)\mod(x^2t-1-1)

This shows that

is a multiple of

2t-1

, So

b(x)=x^l(2t-1)b'(x)

for some

. Now, as

l(2t-1)

is less than

and

is less than

q^m-1

(x^l(2t-1)b(x)

is a codeword. Therefore,

(x^l(2t-1)b(x)=a(x)(x^2t-1-1)p(x)

Since

b(x)

degree is less than degree of

p(x)

cannot divide

b(x)

. If

is not zero, then

p(x)

also cannot divide

x^l(2t-1)-1

is less than

q^m-1

and by definition of

p(x)

divides

x^l(2t-1)-1

for no

smaller than

q^m-1

. Therefore

and

equals to zero. That means both that both the bursts are same, contrary to assumption.

Fire codes are the best single burst correcting codes with high rate and they are constructed analytically. They are of very high rate and when

and

are equal, redundancy is least and is equal to

3t-1

. By using multiple fire codes longer burst errors can also be corrected.

For error detection cyclic codes are widely used and are called

t-1

cyclic redundancy codes.

On Fourier transform

Applications of Fourier transform are widespread in signal processing. But their applications are not limited to the complex fields only; Fourier transforms also exist in the Galois field

GF(q)

. Cyclic codes using Fourier transform can be described in a setting closer to the signal processing.

Fourier transform over finite fields

Fourier transform over finite fields The discrete Fourier transform of vector

v=v_0,v_1,....,v_n-1

is given by a vector

V=V_0,V_1,.....,V_n-1

where,

V_k

	n-1
\Sigma
	i=0

	-j2\pin^-1ik
e

v_i

where,

k=0,.....,n-1

where exp(

-j2\pi/n

) is an

th root of unity. Similarly in the finite field

th root of unity is element

\omega

of order

. Therefore

v=(v_0,v_1,....,v_n-1)

is a vector over

GF(q)

, and

\omega

be an element of

GF(q)

of order

, then Fourier transform of the vector

is the vector

V=(V_0,V_1,.....,V_n-1)

and components are given by

V_j

	n-1
\Sigma
	i=0

\omega^ijv_i

where,

k=0,.....,n-1

Here

is time index,

is frequency and V

is the spectrum. One important difference between Fourier transform in complex field and Galois field is that complex field

\omega

exists for every value of

while in Galois field

\omega

exists only if

divides

q-1

. In case of extension fields, there will be a Fourier transform in the extension field

GF(q^m)

divides

q^m-1

for some

. In Galois field time domain vector

is over the field

GF(q)

but the spectrum V

may be over the extension field

GF(q^m)

Spectral description

Any codeword of cyclic code of blocklength

can be represented by a polynomial

c(x)

of degree at most

n-1

. Its encoder can be written as

c(x)=a(x)g(x)

. Therefore, in frequency domain encoder can be written as

C_j=A_jG_j

. Here codeword spectrum

C_j

has a value in

GF(q^m)

but all the components in the time domain are from

GF(q)

. As the data spectrum

A_j

is arbitrary, the role of

G_j

is to specify those

where

C_j

will be zero.

Thus, cyclic codes can also be defined as

Given a set of spectral indices,

A=(j_1,....,j_n-k)

, whose elements are called check frequencies, the cyclic code

is the set of words over

GF(q)

whose spectrum is zero in the components indexed by

j_1,...,j_n-k

. Any such spectrum

will have components of the form

A_jG_j

So, cyclic codes are vectors in the field

GF(q)

and the spectrum given by its inverse fourier transform is over the field

GF(q^m)

and are constrained to be zero at certain components. But every spectrum in the field

GF(q^m)

and zero at certain components may not have inverse transforms with components in the field

GF(q)

. Such spectrum can not be used as cyclic codes.

Following are the few bounds on the spectrum of cyclic codes.

BCH bound

be a factor of

(q^m-1)

for some

. The only vector in

GF(q)ⁿ

of weight

d-1

or less that has

d-1

consecutive components of its spectrum equal to zero is all-zero vector.

Hartmann-Tzeng bound

be a factor of

(q^m-1)

for some

, and

an integer that is coprime with

. The only vector

GF(q)ⁿ

of weight

d-1

or less whose spectral components

V_j

equal zero for

j=\ell₁+\ell_2b(\modn)

, where

\ell₁=0,....,d-s-1

and

\ell₂=0,....,s-1

, is the all zero vector.

Roos bound

be a factor of

q^m-1

for some

and

GCD(n,b)=1

. The only vector in

GF(q)ⁿ

of weight

d-1

or less whose spectral components

V_j

equal to zero for

j=l₁+l_2b(\modn)

, where

l₁=0,...,d-s-2

and

l₂

takes at least

s+1

values in the range

0,....,d-2

, is the all-zero vector.

Quadratic residue codes

When the prime

is a quadratic residue modulo the prime

there is a quadratic residue code which is a cyclic code of length

, dimension

(p+1)/2

and minimum weight at least

\sqrt{p}

over

GF(l)

Generalizations

A constacyclic code is a linear code with the property that for some constant λ if (c₁,c₂,...,c_n) is a codeword then so is (λc_n,c₁,...,c_n-1). A negacyclic code is a constacyclic code with λ=-1. A quasi-cyclic code has the property that for some s, any cyclic shift of a codeword by s places is again a codeword. A double circulant code is a quasi-cyclic code of even length with s=2. Quasi-twisted codes and multi-twisted codes are further generalizations of constacyclic codes.^[3] ^[4]

External links

John Gill's (Stanford) class notes - Notes #3, October 8, Handout #9, EE 387.
Jonathan Hall's (MSU) class notes - Chapter 8. Cyclic codes - pp. 100 - 123

Notes and References

P. Fire, E, P. (1959). A class of multiple-error-correcting binary codes for non-independent errors. Sylvania Reconnaissance Systems Laboratory, Mountain View, CA, Rept. RSL-E-2, 1959.
Wei Zhou, Shu Lin, Khaled Abdel-Ghaffar. Burst or random error correction based on Fire and BCH codes. ITA 2014: 1-5 2013.
Aydin . Nuh . Siap . Irfan . K. Ray-Chaudhuri . Dijen . The Structure of 1-Generator Quasi-Twisted Codes and New Linear Codes . Designs, Codes and Cryptography . 2001 . 24 . 3 . 313–326. 10.1023/A:1011283523000 . 17376783 .
Aydin . Nuh . Halilović . Ajdin . A generalization of quasi-twisted codes: multi-twisted codes . Finite Fields and Their Applications . 2017 . 45 . 96–106. 10.1016/j.ffa.2016.12.002 . 7694655 . free . 1701.01044 .

Cyclic code explained

Definition

Algebraic structure

Examples

Trivial examples

Quasi-cyclic codes and shortened codes

Definition

Definition

For correcting errors

For correcting two errors

Hamming code

Hamming code for correcting single errors

For correcting burst errors

Fire codes as cyclic bounds

On Fourier transform

Fourier transform over finite fields

Spectral description

BCH bound

Hartmann-Tzeng bound

Roos bound

Quadratic residue codes

Generalizations

See also

Further reading

External links

Notes and References