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<HTML><HEAD>
<TITLE> Creating a Parity Check Matrix </TITLE>
</HEAD><BODY>
<H1> Creating a Parity Check Matrix </H1>
<P>This software deals only with linear block codes for binary (ie,
modulo-2, GF(2)) vectors. The set of valid codewords for a linear
code can be specified by giving a <I>parity check matrix</I>,
<B>H</B>, with <I>M</I> rows and <I>N</I> columns. The valid
codewords are the vectors, <B>x</B>, of length <I>N</I>, for which
<B>Hx</B>=<B>0</B>, where all arithmetic is done modulo-2. Each row
of <B>H</B> represents a parity check on a subset of the bits in
<B>x</B>; all these parity checks must be satisfied for <B>x</B> to be
a codeword. Note that the parity check matrix for a given code (ie,
for a given set of valid codewords) is not unique, even after
eliminating rows of <B>H</B> that are redundant because they are
linear combinations of other rows.
<P>This software stores parity check matrices in files in a sparse
format. These parity-check files are <I>not</I> human-readable
(except by using the <A HREF="#print-pchk"><TT>print-pchk</TT></A>
program). However, they <I>are</I> readable on a machine with a
different architecture than they were written on.
<P>Some LDPC software by David MacKay and others uses the
<A HREF="http://www.inference.phy.cam.ac.uk/mackay/codes/alist.html">alist
format</A> for parity check matrices. Two programs for converting
between this format and the format for sparse parity check matrices
used by this software are provided.
<A NAME="ldpc"><H2>Methods for constructing LDPC codes</H2></A>
<P>This software is primarily intended for experimentation with Low
Density Parity Check (LDPC) codes. These codes can be constructed by
various methods, which generally involve some random selection of
where to put 1s in a parity check matrix. Any such method for
constructing LDPC codes will have the property that it produces parity
check matrices in which the number of 1s in a column is approximately
the same (perhaps on average) for any size parity check matrix. For a
given code rate, these matrices therefore become increasingly sparse
as the length of a codeword, and hence the number of parity checks,
increases.
<P>Many methods for constructing LDPC matrices are described in the
<A HREF="refs.html">references</A>. Two simple methods are currently
implemented by this software, both of which operate according to the
following scheme:
<OL>
<LI> Create a preliminary parity check matrix by one of the methods.
<LI> Add 1s to the parity check matrix in order to avoid rows that have no
1s in them, and hence are redundant, or which have only one 1 in them,
in which case the corresponding codeword bits will always be zero.
The places within such a row to add these 1s are selected randomly.
<LI> If the preliminary parity check matrix constructed in step (1) had
an even number of 1s in each column, add further 1s to avoid the problem
that this will cause the rows to add to zero, and hence at least
one check will be redundant. Up to two 1s are added (since it is also
undesirable for the sum of the rows to have only one 1 in it), at
positions selected randomly from the entire matrix. However, the
number of 1s to add in this step is reduced by the number already added
in step (2). (Note that although redundant checks are not disastrous,
they are better avoided; see the discussion of <A HREF="dep-H.html">linear
dependence in parity check matrices</A>.)
<LI> If requested, try to eliminate
situations where a pair of columns both have 1s in a particular pair of
rows, which correspond to cycles of length four in the factor graph of
the parity check matrix. When such a situation is detected, one of the
1s involved is moved randomly within its column. This continues until
no such situations remain, or until 10 passes over all columns have
failed to eliminate all such situations.
</OL>
<P>The <I>evencol</I> method is the simplest way of performing step
(1) of the above procedure. For each column of the parity check
matrix, independently, it places a specified number of 1s in positions
selected uniformly at random, with the only constraint being that
these 1s be in distinct rows. Note that despite the name, the columns
do not have to have the same number of 1s - a distribution over
several values for the number of 1s in a column can be specified
instead. Such codes with different-weight columns are sometimes
better than codes in which every column has the same weight.
<P>The <I>evenboth</I> method also puts a specified number of 1s in
each column, but it tries as well to keep the numbers of 1s in the
rows approximately the same. Initially, it creates indicators for all
the 1s that will be required, and assigns these 1s to rows as evenly
as it can, favouring earlier rows if an exactly even split is not
possible. It then assigns 1s to successive columns by selecting
randomly, without replacement, from this initial supply of 1s, subject
only to the constraint that the 1s assigned to a column must be in
distinct rows. If at some point it is impossible to put the required
number of 1s in a column by picking from the 1s remaining, a 1 is set
in that column without reference to other columns, creating a possible
unevenness.
<P>Note that regardless of how evenly 1s are distributed in the
preliminary parity check matrix created in step (1), steps (2) and (3)
can make the numbers of 1s in the both rows and columns be uneven, and
step (4), if done, can make the numbers of 1s in rows be uneven.
<P><A NAME="make-pchk"><HR><B>make-pchk</B>: Make a parity check
matrix by explicit specification.
<BLOCKQUOTE><PRE>
make-pchk <I>pchk-file n-checks n-bits row</I>:<I>col ...</I>
</PRE></BLOCKQUOTE>
<P>Creates a file named <TT><I>pchk-file</I></TT> in
which it stores a parity check matrix with <TT><I>n-checks</I></TT>
rows and <TT><I>n-bits</I></TT> columns. This parity check matrix
consists of all 0s except for 1s at the <I>row</I>:<I>col</I>
positions listed. Rows and columns are numbered starting at zero.
This program is intended primarily for testing and demonstration
purposes.
<P><B>Example:</B> The well-known Hamming code with codewords of
length <I>N</I>=7 and with <I>M</I>=3 parity checks can be can be
created as follows:
<UL><PRE>
<LI>make-pchk ham7.pchk 3 7 0:0 0:3 0:4 0:5 1:1 1:3 1:4 1:6 2:2 2:4 2:5 2:6
</PRE></UL>
<P><A NAME="alist-to-pchk"><HR><B>alist-to-pchk</B>: Convert a parity
check matrix from alist format to the sparse matrix format used by
this software.
<BLOCKQUOTE><PRE>
alist-to-pchk [ -t ] <I>alist-file pchk-file</I>
</PRE></BLOCKQUOTE>
<P>Converts a parity check matrix in
<A HREF="http://www.inference.phy.cam.ac.uk/mackay/codes/alist.html">alist
format</A> stored in the file named <TT><I>alist-file</I></TT> to
the sparse matrix format used by this software, storing it in the
file named <TT><I>pchk-file</I></TT>.
<P>If the <B>-t</B> option is given, the transpose of the parity check
matrix in <TT><I>alist-file</I></TT> is stored in the
<TT><I>pchk-file</I></TT>.
<P>Any zeros indexes in the alist file are ignored, so that alist files
with zero padding (as required in the specification) are accepted,
but files without this zero padding are also accepted. Newlines
are ignored by <TT>alist-to-pchk</TT>, so no error is reported if
the set of indexes in a row or column description are not those
on a single line.
<P><A NAME="pchk-to-alist"><HR><B>pchk-to-alist</B>: Convert a parity
check matrix to alist format.
<BLOCKQUOTE><PRE>
pchk-to-alist [ -t ] [ -z ] <I>pchk-file alist-file</I>
</PRE></BLOCKQUOTE>
<P>Converts a parity check matrix stored in the sparse matrix format
used by this software, in the file named <TT><I>pchk-file</I></TT>, to
the <A
HREF="http://www.inference.phy.cam.ac.uk/mackay/codes/alist.html">alist
format</A>, storing it in the file named <TT><I>alist-file</I></TT>.
<P>If the <B>-t</B> option is given, the transpose of the parity check
matrix is converted to alist format.
<P>If the number of 1s is not
the same for each row or each column, the alist format specification
says that the list of indexes of 1s for each row or column should
be padded with zeros to the maximum number of indexes. By default,
<TT>pchk-to-alist</TT> does this, but output of these 0s can be
suppressed by specifying the <B>-z</B> option. (The <TT>alist-to-pchk</TT>
program will accept alist files produced with or without the <B>-z</B>
option.)
<P><A NAME="print-pchk"><HR><B>print-pchk</B>: Print a parity check matrix.
<BLOCKQUOTE><PRE>
print-pchk [ -d ] [ -t ] <I>pchk-file</I>
</PRE></BLOCKQUOTE>
<P>Prints a human-readable representation of the parity check matrix stored
in <TT><I>pchk-file</I></TT>.
The <B>-d</B> option causes the matrix to be printed in a dense
format, even though parity check matrices are always stored in the
file in a sparse format. If the <B>-t</B> option is present, what is
printed is the transpose of the parity check matrix.
<P>The sparse display format consists of one line for every row of the
matrix, consisting of the row number, a colon, and the column numbers
at which 1s are located (possibly none). Row and columns numbers
start at zero. No attempt is made to wrap long lines.
<P>The dense display is the obvious array of 0s and 1s. Long lines
are not wrapped.
<P><B>Example</B>: The parity check matrix for the Hamming code created
by the example for <A HREF="#make-pchk"><TT>make-pchk</TT></A> would print
as follows:
<UL><PRE>
<LI>print-pchk ham7.pchk
Parity check matrix in ham7.pchk (sparse format):
0: 0 3 4 5
1: 1 3 4 6
2: 2 4 5 6
<LI>print-pchk -d ham7.pchk
Parity check matrix in ham7.pchk (dense format):
1 0 0 1 1 1 0
0 1 0 1 1 0 1
0 0 1 0 1 1 1
</PRE></UL>
<P><A NAME="make-ldpc"><HR><B>make-ldpc</B>: Make a low density parity
check matrix, by random generation.
<BLOCKQUOTE><PRE>
make-ldpc <I>pchk-file n-checks n-bits seed method</I>
</PRE>
<BLOCKQUOTE>
where <TT><I>method</I></TT> is one of the following:
<BLOCKQUOTE><PRE>
evencol <I>checks-per-col</I> [ no4cycle ]
evencol <I>checks-distribution</I> [ no4cycle ]
evenboth <I>checks-per-col</I> [ no4cycle ]
evenboth <I>checks-distribution</I> [ no4cycle ]
</PRE></BLOCKQUOTE>
</BLOCKQUOTE>
</BLOCKQUOTE>
<P>Creates a Low Density Parity Check matrix with
<TT><I>n-checks</I></TT> rows and <TT><I>n-bits</I></TT> columns. The
parity check matrix will be generated pseudo-randomly by the indicated
method, using a pseudo-random number stream determined by <TT><I>seed</I></TT>.
The actual random number seed used is 10 times <TT><I>seed</I></TT> plus 1,
so as to avoid using the same stream as any of the other programs.
<P>Two methods are currently available for creating the LDPC matrix,
specified by <TT>evencol</TT> or <TT>evenboth</TT>. Both methods
produce a matrix in which the number of 1s in each column is
approximately <TT><I>checks-per-col</I></TT>, or varies from column
to column according the the <TT><I>checks-distribution</I></TT>.
The <TT>evenboth</TT> method also tries to make the number of checks per row be
approximately uniform; if this is not achieved, a message saying that
how many bits were placed unevenly is displayed on standard error.
<P>For both methods, the <TT>no4cycle</TT> option will cause cycles of
length four in the factor graph representation of the code to be
eliminated (if possible). A message is displayed on standard error if
this is not achieved.
<P>A <TT><I>checks-distribution</I></TT> has the form
<BLOCKQUOTE><PRE>
<I>prop</I>x<I>count</I>/<I>prop</I>x<I>count</I>/...
</PRE></BLOCKQUOTE>
Here, <TT><I>prop</I></TT> is a proportion of columns that have the
associated <TT><I>count</I></TT>. The proportions need not sum to one,
since they will be automatically normalized. For example, <TT>0.3x4/0.2x5</TT>
specifies that 60% of the columns will contain four 1s and 40% will
contain five 1s.
<P>See the <A HREF="#ldpc">discussion above</A> for more details
on how these methods construct LDPC matrices.
<P><B>Example 1:</B> The <TT>make-ldpc</TT> command below creates
a 20 by 40 low density parity check matrix with three 1s per
column and six 1s per row, using random seed 1. The matrix
is then printed in sparse format
using <A HREF="#print-pchk">print-pchk</A>.
<UL><PRE>
<LI>make-ldpc ldpc.pchk 20 40 1 evenboth 3
<LI>print-pchk ldpc.pchk
Parity check matrix in ldpc.pchk (sparse format):
0: 10 14 18 27 38 39
1: 2 3 5 11 27 30
2: 15 19 20 21 24 26
3: 2 4 25 28 32 38
4: 7 9 12 22 33 34
5: 5 6 21 22 26 32
6: 1 4 13 24 25 28
7: 1 14 28 29 30 36
8: 11 13 22 23 32 37
9: 6 8 13 20 31 33
10: 0 3 24 29 31 38
11: 7 12 15 16 17 23
12: 3 16 29 34 35 39
13: 0 8 10 18 36 37
14: 6 11 18 20 35 39
15: 0 7 14 16 25 37
16: 2 4 9 19 30 31
17: 5 9 10 17 19 23
18: 8 15 17 21 26 27
19: 1 12 33 34 35 36
</PRE></UL>
<P><B>Example 2:</B> The two <TT>make-ldpc</TT> commands
below both create a 20 by 40 low density parity check matrix with 30%
of columns with two 1s, 60% of columns with three 1s, and 10% of
columns with seven 1s. The transpose of the parity check matrix
is then printed in sparse format.
<UL><PRE>
<LI>make-ldpc ldpc.pchk 20 40 1 evenboth 0.3x2/0.6x3/0.1x7
<LI>make-ldpc ldpc.pchk 20 40 1 evenboth 3x2/6x3/1x7
<LI>print-pchk -t ldpc.pchk
Transpose of parity check matrix in ldpc.pchk (sparse format):
0: 13 16
1: 9 18
2: 1 10
3: 3 15
4: 4 14
5: 14 17
6: 4 5
7: 1 8
8: 0 4
9: 9 14
10: 5 8
11: 6 16
12: 2 12 19
13: 3 17 18
14: 2 16 17
15: 2 11 18
16: 12 13 19
17: 7 13 18
18: 2 5 11
19: 10 12 14
20: 1 8 16
21: 10 18 19
22: 3 6 17
23: 7 11 12
24: 1 2 19
25: 0 6 7
26: 5 8 15
27: 1 4 7
28: 6 13 19
29: 3 4 11
30: 3 8 17
31: 4 5 9
32: 0 10 15
33: 7 11 13
34: 8 12 19
35: 0 2 10
36: 0 5 9 11 15 17 18
37: 0 1 2 6 7 14 16
38: 0 1 3 9 12 13 15
39: 3 6 9 10 14 15 16
</PRE></UL>
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