Difference between revisions of "Aufgaben:Exercise 3.10: Maximum Likelihood Tree Diagram"

Revision as of 16:09, 28 June 2022

Signals and tree diagram

As in "Exercise 3.9" we consider the joint decision of three binary symbols (bits) by means of the correlation receiver.

The possible transmitted signals $s_0(t), \ \text{...} \ , \ s_7(t)$ are bipolar.
In the graphic the functions $s_0(t)$, $s_1(t)$, $s_2(t)$ and $s_3(t)$ are shown.
The blue curves are valid for rectangular NRZ transmission pulses.

Below is drawn the so-called tree diagram for this constellation under the condition that the signal $s_3(t)$ was transmitted. Shown here in the range from $0$ to $3T$ are the functions

$$i_i(t) = \int_{0}^{t} s_3(\tau) \cdot s_i(\tau) \,{\rm d} \tau \hspace{0.3cm}( i = 0, \ \text{...} \ , 7)\hspace{0.05cm}.$$

The correlation receiver compares the final values $I_i = i_i(3T)$ with each other and searches for the largest possible value $I_j$.
The corresponding signal $s_j(t)$ is then the one most likely to have been sent according to the maximum likelihood criterion.

Note that the correlation receiver generally makes the decision based on the corrected quantities $W_i = I_i \ - E_i/2$. But since for bipolar rectangles all transmitted signals $(i = 0, \ \text{...} \ , \ 7)$ have exactly the same energy

$$E_i = \int_{0}^{3T} s_i^2(t) \,{\rm d} t$$

the integrals $I_i$ provide exactly the same maximum likelihood information as the corrected quantities $W_i$.

The red signal waveforms $s_i(t)$ are obtained from the blue ones by convolution with the impulse response $h_{\rm G}(t)$ of a Gaussian low-pass filter with cutoff frequency $f_{\rm G} \cdot T = 0.35$.

Each individual rectangular pulse is broadened.
The red signal waveforms lead to intersymbol interference in case of threshold decision.

Note:

The exercise belongs to the chapter "Optimal Receiver Strategies".

Questions

$I_0/E_{\rm B} \ = \ $

$I_2/E_{\rm B} \ = \ $

$I_4/E_{\rm B} \ = \ $

$I_6/E_{\rm B} \ = \ $

	The tree diagram can be further described by straight line segments.
	If $I_3$ is the maximum $I_i$ value, the receiver decides correctly.
	$I_0 = I_6$ is valid independent of the strength of the noise.

	The tree diagram can be further described by straight line segments.
	The signal energies $E_i(i = 0, \ \text{...} \ , 7$) are different.
	Both the decision variables $I_i$ and $W_i$ are suitable.

	Without intersymbol interference (blue), $t_1 = 0$ and $t_2 = 3T$ are best possible.
	With intersymbol interference (red), $t_1 = 0$ and $t_2 = 3T$ are best possible.

Solution

(1) The left graph shows the tree diagram (without noise) with all final values. Highlighted in green is the curve $i_0(t)/E_{\rm B}$ with the final result $I_0/E_{\rm B} = \ –1$, which first rises linearly to $+1$ – the first bit of $s_0(t)$ and $s_3(t)$ in each case coincide – and then falls off over two bit durations.

Tree diagram of the correlation receiver

The correct results are thus:

$$I_0/E_{\rm B}\hspace{0.15cm}\underline { = -1},$$

$$I_2/E_{\rm B} \hspace{0.15cm}\underline {= +1}, $$

$$I_4/E_{\rm B} \hspace{0.15cm}\underline {= -3}, $$

$$I_6/E_{\rm B}\hspace{0.15cm}\underline { = -1} \hspace{0.05cm}.$$

(2) Only the second solution is correct:

In the presence of (noise) disturbances, the functions $i_i(t)$ no longer increase or decrease linearly, but have a curve as shown in the right graph.
As long as $I_3 > I_{\it i≠3}$, the correlation receiver decides correctly.
In the presence of noise, $I_0 ≠ I_6$ always holds, in contrast to the noise-free tree diagram.

(3) Only the second statement is true:

Since now the possible transmitted signals $s_i(t)$ can no longer be composed of isolated horizontal sections, also the tree diagram without noise does not consist of straight line segments.
Since the energies $E_i$ are different – this can be seen, for example, by comparing the (red) signals $s_0(t)$ and $s_2(t)$ – it is essential to use the corrected quantities $W_i$ for the decision.
The use of the pure correlation values $I_i$ can already lead to wrong decisions without noise disturbances.

(4) Answer 1 is correct:

In the case without intersymbol interference (blue rectangular signals), all signals are limited to the range $0 \ ... \ 3T$.
Outside this range the received signal $r(t)$ is pure noise.
Therefore in this case also the integration over the range $0 \ \text{...} \ 3T$.
In contrast, when intersymbol interference (red signals) is taken into account, the integrands $s_3(t) \cdot s_i(t)$ also differ outside this range.
Therefore, if $t_1 = \ –T$ and $t_2 = +4T$ are chosen, the error probability of the correlation receiver is further reduced compared to the integration range $0 \ \text{...} \ 3T$ is further reduced.

@@ Line 67: / Line 67: @@
 {{ML-Kopf}}
 '''(1)'''&nbsp; The left graph shows the tree diagram (without noise) with all final values. Highlighted in green is the curve $i_0(t)/E_{\rm B}$ with the final result $I_0/E_{\rm B} = \ &ndash;1$, which first rises linearly to $+1$ &ndash; the first bit of $s_0(t)$ and $s_3(t)$ in each case coincide &ndash; and then falls off over two bit durations.
-[[File:P_ID1466__Dig_A_3_10.png|right|frame|Tree diagram of the correlation receiver]]
+[[File:EN_Dig_A_3_10_ML.png|right|frame|Tree diagram of the correlation receiver]]
 The correct results are thus:
 :$$I_0/E_{\rm B}\hspace{0.15cm}\underline { = -1},$$