Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Asymptotically good binary code with efficient encoding & Justesen code Tomer Levinboim Error Correcting Codes Seminar (2008)

Published byRolf Norris Modified over 8 years ago

Similar presentations

Presentation on theme: "1 Asymptotically good binary code with efficient encoding & Justesen code Tomer Levinboim Error Correcting Codes Seminar (2008)"— Presentation transcript:

1 1 Asymptotically good binary code with efficient encoding & Justesen code Tomer Levinboim Error Correcting Codes Seminar (2008)

2 2 Outline Intro  codes  Singleton Bound Linear Codes Bounds  Gilbert-Varshamov  Hamming RS codes Code Concatention  Examples Wozencraft Ensemble Justesen Codes

3 3 Hamming Distance Hamming Distance between The Hamming Distance is a metric  Non negative  Symmetric  Triangle inequality  =

4 4 Weight The weight (wt) of Example (on board)

5 5 Code An (n,k,d) q code C is a function such that:   For every

6 6 Code (parameters) (n,k,d) q Parameters  n – block length  k – information length  d – minimum distance (actually, a lower bound)  q – size of alphabet  |C| = q k or k=log q |C|

7 7 Code (parameters div n) Asymptotic view of parameters as n  ∞ :  The rate  Relative minimum distance Thus an (n,k,d) q can be written as (1,R, δ ) q Notation: (n,k,d) q vs. [n,k,d] q – latter reserved for linear code (soon)

8 8 Trivial Code Example FEC3 = write each bit three time  R = ?  d = ? how many errors can we  Detect ? (d-1)  Correct ? t, where d=2t+1

9 9 Goal Would like to:  Maximize δ – correct more  Maximize R – send more information * conflicting goals - would like to be able to construct an [n,k,d] q code s.t. δ>0, R>0 and both are constant.  Minimize q – for practical reasons  Maximize number of codewords while minimizing n and keeping d large.

10 10 Singleton Bound Let C be an [n,k,d] q code then  k ≤ n – d + 1 equivalently  R ≤ 1 – δ + o(1) Proof: project C to first k-1 coordinates  On Board

11 11 Visual intuition On board... Ball q (x,r)  r:=d  r:=t (where d=2t+1) Vol q (n,r) = |Ball q (x,r)|

12 12 Linear Codes

13 13 Linear Codes An [n,k,d] q code C:F q K  F q n is linear when:  F q is a field  C is linear function (e.g., matrix) Linearity implies:  C(ax+by) = aC(x) + bC(y)  0 n member of C

14 14 Linear Codes (example) FEC3  [3,1,3] 2 Hadamard – longest linear code  [n,logn, n/2] 2  e.g., - [8,3,4] 2  (H - Matrix representation on board) Dimensions Asymptotic behavior

15 15 Linear Codes – minimum distance Lemma: if C:F q K  F q n is linear then Note: for clarity C x means C(x) Proof:  ≤ - trivial  ≥ - follows from linearity (on board)

16 16 Reed-Solomon code Idea: oversample a polynomial Let q be prime power and F q a finite field of size q. Let k<n and fix n elements of F q,  x 1,x 2,..x n Given a message m=(c 0..c k-1 ) interpret it has the coefficients of the polynomial p

17 17 RS Codes Thus (c 0..c k-1 ) is mapped to (p(x 1 ),..p(x n ))  Linear mapping (Vandermonde) Using linearity, can show for x≠0  RS meet the Singleton bound Proof: on board  (# of roots of a k-1 degree poly) Encoding time

18 18 Bounds

19 19 Gilbert-Varshamov Bound Preliminaries Binary Entropy Stirling Implying that:

20 20 Gilbert-Varshamov Bound Preliminaries Using the binary entropy we obtain On board

21 21 Gilbert-Varshamov Bound bound statement For every n and d<n/2 there is an (n,k,d) q (not necessarily linear) code such that: In terms of rate and relative min-distance:

22 22 Gilbert-Varshamov Bound Proof On Board Sketch of proof:  if C is maximal then:  And  Now use union bound and entropy to obtain result (we show for q=2, using binary entropy)

23 23 GV-Bound Gilbert proved this with a greedy construction Varshamov proved for linear codes  proved using random generator matrices – most matrices are good error correcting codes

24 24 Singleton / GV Plot 10.5 1 Singleton (upper) Gilbert-Varshamov (lower)

25 25 Hamming Bound (Upper) With similar reasoning to GV bound but using For q=2 can show that

26 26 Bounds plot *Madhu Sudan (Lecture 5, 2001)

27 27 Code Concatenation

28 28 Code Concatenation - Motivation RS codes imply we can construct good [n,k,d] q codes for any q=p k Practically would like to work with small q (2, 2 8 ) Consider the “obvious” idea for binary code generated from C – simply convert each symbol from Σ n to log 2 q, What’s the problem with this approach ? (write the new code!)

29 29 Code Concatenation Due to Forney (1966) Two codes:  Outer:C out = [N,K,D] Q  Inner: C in = [n,k,d] q Inner code should encode each symbol of outer code  k = log q Q

30 30 Code Concatenation How does it work ? * Luca Trevisan (Lecture 2)

31 31 Code Concatenation What is the new code ?  d con = dD Proof:  On board

32 32 Code Concatenation (Examples) Asymptotically  δ = ¼  R=logn/2n  0 

33 33 Good Codes Can we “explicitly” build asymptotically good (linear) codes ?  asymptotically good = constant R, δ > 0 as n  ∞  Explicit = polytime constructable / logspace constructible

34 34 Asymptotically Good Codes

35 35 Asymptotically Good Codes GV tells us that most linear functions of a certain size are good error-correcting codes  Can find a good code in brute-force Use brute force on inner-code, where the alphabet is exponentially smaller! Do we really need to search ?

36 36 Wozencraft Ensemble Consider the following set of codes: such that (  R=1/2) ( Notice that (on board)

37 37 Wozencraft Ensemble Lemma: There exists an ensemble of codes c 1,..c N of rate ½ where N = q k -1 such that for at least (1-ε)N value of i, the code C i has distance d i s.t. Proof (on board), outline:  Different codes have only 0 n in common  Let y=C α (x), then, If wt(y)<d  y in Ball(0 n, d)  there are at most Vol(n,d) “bad” codes  For large enough n=2k, we have Vol(n,d) ≤ εN

38 38 Wozencraft Ensemble Implications:  Can construct entire ensemble in O(2 k )=O(2 n )  There are many such good codes, but which one do we use ?

39 39 Justesen Code Concatenation of:  C out - RS code over  a set of inner codes Justesen Code: C * = C out (C 1, C 2,.. C N )  Each symbol of C out is encoded using a different inner code C j  If RS has rate R  C * has rate R/2

40 40 Justesen Code - δ Denote the outer RS code [N,K,D] Q Claim: C* has relative distance

41 41 Justesen Code Proof Intuition: like regular concatenation, but εN bad codes. for x≠y, the outer code induces S={j | x j ≠y j },  |S| ≥D There are at most εN j’s such that Cj is bad and therefore at least |S|- εN ≥ D- εN ≥ (1-R- ε)N good codes  since RS implies D=N-(K-1) Each good code has relative distance ≥ d d * ≥ (1-R- ε)Nd

42 42 Justesen Code The concatenated code C * is an asymptotically good code and has a “super” explicit construction Can take q=2 to get such a binary code

Download ppt "1 Asymptotically good binary code with efficient encoding & Justesen code Tomer Levinboim Error Correcting Codes Seminar (2008)"

Similar presentations

Mahdi Barhoush Mohammad Hanaysheh

Mahdi Barhoush Mohammad Hanaysheh
On Complexity, Sampling, and -Nets and -Samples. Range Spaces A range space is a pair, where is a ground set, it’s elements called points and is a family.

On Complexity, Sampling, and -Nets and -Samples. Range Spaces A range space is a pair, where is a ground set, it’s elements called points and is a family.
Cyclic Code.

Cyclic Code.
Applied Algorithmics - week7

Applied Algorithmics - week7
Error Control Code.

Error Control Code.
296.3Page1 296.3:Algorithms in the Real World Error Correcting Codes II – Cyclic Codes – Reed-Solomon Codes.

296.3Page :Algorithms in the Real World Error Correcting Codes II – Cyclic Codes – Reed-Solomon Codes.
L. J. Wang 1 Introduction to Reed-Solomon Coding ( Part I )

L. J. Wang 1 Introduction to Reed-Solomon Coding ( Part I )
Efficient Soft-Decision Decoding of Reed- Solomon Codes Clemson University Center for Wireless Communications SURE 2006 Presented By: Sierra Williams Claflin.

Efficient Soft-Decision Decoding of Reed- Solomon Codes Clemson University Center for Wireless Communications SURE 2006 Presented By: Sierra Williams Claflin.
1. 2 Overview Review of some basic math Review of some basic math Error correcting codes Error correcting codes Low degree polynomials Low degree polynomials.

1. 2 Overview Review of some basic math Review of some basic math Error correcting codes Error correcting codes Low degree polynomials Low degree polynomials.
May 24, 2005STOC 2005, Baltimore1 Limits to List Decoding Reed-Solomon Codes Venkatesan Guruswami Atri Rudra (University of Washington)

May 24, 2005STOC 2005, Baltimore1 Limits to List Decoding Reed-Solomon Codes Venkatesan Guruswami Atri Rudra (University of Washington)
15-853:Algorithms in the Real World

15-853:Algorithms in the Real World
Information and Coding Theory

Information and Coding Theory
Probabilistic verification Mario Szegedy, Rutgers www/cs.rutgers.edu/~szegedy/07540 Lecture 4.

Probabilistic verification Mario Szegedy, Rutgers www/cs.rutgers.edu/~szegedy/07540 Lecture 4.
CHANNEL CODING REED SOLOMON CODES.

CHANNEL CODING REED SOLOMON CODES.
Information Theory Introduction to Channel Coding Jalal Al Roumy.

Information Theory Introduction to Channel Coding Jalal Al Roumy.
Cellular Communications

Cellular Communications
Asymptotic Enumerators of Protograph LDPCC Ensembles Jeremy Thorpe Joint work with Bob McEliece, Sarah Fogal.

Asymptotic Enumerators of Protograph LDPCC Ensembles Jeremy Thorpe Joint work with Bob McEliece, Sarah Fogal.
Correcting Errors Beyond the Guruswami-Sudan Radius Farzad Parvaresh & Alexander Vardy Presented by Efrat Bank.

Correcting Errors Beyond the Guruswami-Sudan Radius Farzad Parvaresh & Alexander Vardy Presented by Efrat Bank.
DIGITAL COMMUNICATION Coding

DIGITAL COMMUNICATION Coding
EEE377 Lecture Notes1 EEE436 DIGITAL COMMUNICATION Coding En. Mohd Nazri Mahmud MPhil (Cambridge, UK) BEng (Essex, UK) Room 2.14.

EEE377 Lecture Notes1 EEE436 DIGITAL COMMUNICATION Coding En. Mohd Nazri Mahmud MPhil (Cambridge, UK) BEng (Essex, UK) Room 2.14.

Similar presentations

Ads by Google