Difference between revisions of "161-A2.1"

• Activity: Source Coding
• Instructions: In this activity, you are tasked to
  • Walk through the examples.
  • Write a short program to compress and decompress a redundant file.
• Should you have any questions, clarifications, or issues, please contact your instructor as soon as possible.

Example 1: Uniquely Decodable Codes

Let us try to encode a source with just four symbols in its alphabet, i.e. ${\displaystyle A=\{a_{1},a_{2},a_{3},a_{4}\}}$, with probability distribution ${\displaystyle P=\{0.5,0.25,0.125,0.125\}}$. We can calculate the entropy of this source as:

${\displaystyle H\left(S\right)=0.5\log _{2}\left({\frac {1}{0.5}}\right)+0.25\log _{2}\left({\frac {1}{0.25}}\right)+0.125\log _{2}\left({\frac {1}{0.125}}\right)+0.125\log _{2}\left({\frac {1}{0.125}}\right)=1.75\,\mathrm {bits} }$

(1)

Let us look at a few bit sequence assignments and see if they are uniquely decodable or not.

Symbol	Probability	Code 1	Code 2	Code 3	Code 4
${\displaystyle a_{1}}$	0.5	0	0	0	0
${\displaystyle a_{2}}$	0.25	0	1	10	01
${\displaystyle a_{3}}$	0.125	1	00	110	011
${\displaystyle a_{4}}$	0.125	10	11	111	0111
Average Code Length:		1.125	1.25	1.75	1.875

Recall that Shannon's Noiseless Coding Theorem states that ${\displaystyle H\left(S\right)\leq L=1.75\,\mathrm {bits} }$. Thus, codes 1 and 2 are not uniquely decodable since they have average code lengths less than ${\displaystyle L}$.

For code 1, since there are two symbols sharing an encoded symbol, we can say that it is not a distinct code, and therefore not uniquely decodable. We can check code 2 by taking a sequence of symbols encoded using this code: ${\displaystyle 0011}$. We can easily see that this message can be decoded in different ways, either as ${\displaystyle 0,0,1,1}$, or ${\displaystyle 00,11}$.

Code 3 has one of the most desirable properties of a code: having its average length equal to the entropy of the source, and according to Shannon, you cannot have a uniquely decodable code with an average length shorter than this. We can also see that for a sequence of symbols encoded using code 3, there is only one way you can decode the message, thus it is uniquely decodable.

Code 4 is also uniquely decodable, however, it is not instantaneous, since the decoder needs to see the start of the next symbol to determine the end of the current symbol. Also note that the average length of code 4 is longer than the ${\displaystyle H\left(S\right)}$.

We can use the Kraft-McMillan Inequality, ${\displaystyle K=\sum _{i=1}^{n}{\tfrac {1}{r^{\ell _{i}}}}\leq 1}$, to test if a code is uniquely decodable. Tabulating the values, we get:

Code	${\displaystyle K}$
1	1.75
2	1.5
3	1.0
4	0.9375

As expected, codes 1 and 2 have ${\displaystyle K>1}$, and thus, are not uniquely decodable, while codes 3 and 4 have ${\displaystyle K\leq 1}$, and hence, they are uniquely decodable.

Example 2: Uniformly Distributed Symbols

Let us consider the case when the symbols are uniformly distributed, i.e. ${\displaystyle P=\{0.25,0.25,0.25,0.25\}}$. We can then calculate the entropy of the source as:

${\displaystyle H\left(S\right)=0.25\log _{2}\left({\frac {1}{0.25}}\right)+0.25\log _{2}\left({\frac {1}{0.25}}\right)+0.25\log _{2}\left({\frac {1}{0.25}}\right)+0.25\log _{2}\left({\frac {1}{0.25}}\right)=2\,\mathrm {bits} }$

(2)

In this case, the source is incompressible. Thus, we can just use a fixed length code ${\displaystyle 00,01,10,11}$.

Example 3: Prefix Codes

In prefix codes or prefix-free codes, no codeword is a proper prefix of another. One way to test this is to use trees. Fig. 1 shows a binary tree with 4 levels. This three can represent codewords with lengths of 1 to 4 bits.

Example 4: Huffman Coding

Activity: Compression-Decompression