Difference between revisions of "Aufgaben:Exercise 3.11: Viterbi Path Finding"
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*This exercise belongs to the chapter [[Channel_Coding/Decoding_of_Convolutional_Codes| "Decoding of Convolutional Codes"]]. | *This exercise belongs to the chapter [[Channel_Coding/Decoding_of_Convolutional_Codes| "Decoding of Convolutional Codes"]]. | ||
− | *Reference is made in particular to the section [[Channel_Coding/Decoding_of_Convolutional_Codes#Evaluating_the_trellis_in_the_error-free_case_.E2.80. | + | *Reference is made in particular to the section [[Channel_Coding/Decoding_of_Convolutional_Codes#Evaluating_the_trellis_in_the_error-free_case_.E2.80.93_Path_search|"Evaluating the trellis in the error-free case – Path finding"]]. |
Revision as of 15:40, 19 November 2022
One result of $\text{Exercise 3.10}$ was adjacent trellis evaluation in terms of metrics ${\it \Lambda}_i(S_{\mu})$.
- At all decoding steps $i$ the $($in general$)$ $2^m = 4$ metrics were determined, selecting for each node the larger of two comparison values.
- The branch with the lower value was discarded. One can recognize discarded branches in the graph by dotted lines.
Otherwise, the same conditions apply as for $\text{Exercise 3.10}$. For example, also in the adjacent graph, a red arrow indicates the information bit $u_i = 0$ and a blue arrow stands for $u_i = 1$.
In the present exercise we consider the second and important part of the Viterbi algorithm, namely the search for the "surviving paths" ${\it \Phi}_i(S_{\mu})$. These are at time $i$ in state $S_{\mu}$ with $\mu \in \{1,\ 2,\ 3,\ 4 \}$. The search is best organized in the backward direction $($i.e., from bottom to top in the graph$)$.
At the end time $($in the example $i = 7)$ there is only one surviving path ${\it \Phi}_7(S_0)$ due to termination. From this it is possible to extract:
- the sequence $\underline{z}$ selected by the decoder $($short: "decoder sequence"$)$ ⇒ highest possible probability ${\rm Pr}(\underline{z} = \underline{x})$,
- the associated information sequence $\underline{v}$ with the greatest possible probability ${\rm Pr}(\underline{v} = \underline{u})$.
A decision at an earlier time, for example at $i = 5$, does not always satisfy the maximum likelihood criterion. Here there are four surviving paths ${\it \Phi}_5(S_0), \hspace{0.05cm}\text{ ...} \hspace{0.1cm} , \ {\it \Phi}_5(S_3)$, which at time $i = 5$ are in states $S_0, \hspace{0.05cm}\text{ ...} \hspace{0.1cm} , \ S_3$.
- One of these four paths is certainly part of the maximum likelihood path, which is the best possible path for $i → ∞$ $($at termination significantly earlier, here at $i = 7)$.
- But if a constraint decision is to be made already at time $i = 5$, one usually chooses the path ${\it \Phi}_5(S_{\mu})$ with the largest metric at that time ${\it \Lambda}_5(S_{\mu})$.
Hints:
- This exercise belongs to the chapter "Decoding of Convolutional Codes".
- Reference is made in particular to the section "Evaluating the trellis in the error-free case – Path finding".
Questions
Solution
- Unambiguously find the surviving path by searching backwards, i.e., from node ${\it \Lambda}_7(S_0)$ to node ${\it \Lambda}_0(S_0)$.
- Using the code sequences $(00, \, 01, \, 10$ or $11)$ given at the transitions, we obtain in the forward direction the result according to Proposition 2 ⇒ ${\it \Phi}_7(S_0)$:
- $$\underline{z} = \big (00\hspace{0.05cm}, 11\hspace{0.05cm}, 10\hspace{0.05cm}, 00\hspace{0.05cm}, 01\hspace{0.05cm}, 01\hspace{0.05cm}, 11\hspace{0.03cm} \big ) \hspace{0.05cm}.$$
- Do not reach the final node ${\it \Lambda}_7(S_0)$ along the other paths.
(2) By comparing the code sequence $\underline{z}$ selected in subtask (1) with the received sequence
- $$\underline{y} = \big (01\hspace{0.05cm}, 11\hspace{0.05cm}, 00\hspace{0.05cm}, 01\hspace{0.05cm}, 01\hspace{0.05cm}, 01\hspace{0.05cm}, 11\hspace{0.03cm} \big )$$
one detects three bit errors at positions 2, 5, and 8.
- If a code sequence $\underline{x} ≠ \underline{z}$ was sent, there can of course be more.
- Because of the final value ${\it \Lambda}_7(S_0) = 8$ or ${\it \Gamma}_7(S_0) = 3$ – see "Exercise 3.10" – but one can assume that a correct decision ⇒ $\underline{z} = \underline{x}$ has been made.
(3) Correct is proposed solution 1:
- From the colors of the surviving path – red represents $u_i = 0$ and blue represents $u_i = 1$ – one can see the correctness of solution proposal 1: red – blue – red – blue – blue – red – red.
- It should be noted that the actual information sequence $\underline{u}$ is only of length $L = 5$.
- Only by termination one arrives at the total length $L' = L + m = 7$.
(4) At time $i = 6$ there are still two surviving paths. A decision could be forcibly made based on the larger metric. However, because of ${\it \Lambda}_6(S_0) = {\it \Lambda}_6(S_2) = 6$ this is not possible in our example ⇒ No.
(5) The graph shows that all proposed solutions are correct. The paths are labeled ${\it \Phi}_5(S_0)$, ... , ${\it \Phi}_5(S_3)$.
(6) The constraint decision at time $i = 5$ would select the path with the largest metric ${\it \Lambda}_5(S_{\mu})$, i.e., the path ${\it \Phi}_5(S_2)$ corresponding to proposition 3.
(7) Based on our solution to subtask (1), the path ${\it \Phi}_5(S_3)$ according to proposition 4 would have been the better choice.
- This is part of the path ${\it \Phi}_7(S_0)$.
- At the time $i = 5$, however, there is still nothing in favor of this choice.
- The (ultimately correct) path is only highlighted by the two termination bits.