Difference between revisions of "Aufgaben:Exercise 2.5: Ternary Signal Transmission"
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* You can numerically determine the error probability values according to our applet [[Applets:Komplementäre_Gaußsche_Fehlerfunktionen|"Complementary Gaussian Error Functions"]]. | * You can numerically determine the error probability values according to our applet [[Applets:Komplementäre_Gaußsche_Fehlerfunktionen|"Complementary Gaussian Error Functions"]]. | ||
| − | * To check | + | * To check your results, use our (German language) SWF applet [[Applets:Fehlerwahrscheinlichkeit|"Symbol error probability of digital communications systems"]]. |
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===Questions=== | ===Questions=== | ||
<quiz display=simple> | <quiz display=simple> | ||
| − | {What symbol error probability results with the (normalized) noise rms value $\sigma_d/s_0 = 0.25$ for equally probable symbols? | + | {What symbol error probability results with the (normalized) noise rms value $\sigma_d/s_0 = 0.25$ for equally probable symbols? |
|type="{}"} | |type="{}"} | ||
$p_0 = 1/3, \ \sigma_d = 0.25 \text{:} \hspace{0.4cm} p_{\rm S} \ = \ ${ 3 3% } $\ \%$ | $p_0 = 1/3, \ \sigma_d = 0.25 \text{:} \hspace{0.4cm} p_{\rm S} \ = \ ${ 3 3% } $\ \%$ | ||
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$p_0 = 1/2, \ \sigma_d = 0.5 \text{:} \hspace{0.4cm} E_{\rm +, \ opt} \ = \ ${ 0.673 3% } | $p_0 = 1/2, \ \sigma_d = 0.5 \text{:} \hspace{0.4cm} E_{\rm +, \ opt} \ = \ ${ 0.673 3% } | ||
| − | {What is the probability | + | {What is the symbol error probability for optimal thresholds? |
|type="{}"} | |type="{}"} | ||
${\rm optimal \ thresholds} \text{:} \hspace{0.4cm} p_{\rm S} \ = \ ${ 21.7 3% } $\ \%$ | ${\rm optimal \ thresholds} \text{:} \hspace{0.4cm} p_{\rm S} \ = \ ${ 21.7 3% } $\ \%$ | ||
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===Solution=== | ===Solution=== | ||
{{ML-Kopf}} | {{ML-Kopf}} | ||
| − | '''(1)''' According to the given equation, with $M = 3$ and $\sigma_d/s_0 = 0.25$: | + | '''(1)''' According to the given equation, with $M = 3$ and $\sigma_d/s_0 = 0.25$: |
:$$p_{\rm S} = | :$$p_{\rm S} = | ||
\frac{ 2 \cdot (M-1)}{M} \cdot {\rm Q} \left( {\frac{s_0}{(M-1) \cdot | \frac{ 2 \cdot (M-1)}{M} \cdot {\rm Q} \left( {\frac{s_0}{(M-1) \cdot | ||
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| − | '''(2)''' When the noise rms value is doubled, the error probability | + | '''(2)''' When the noise rms value is doubled, the error probability increases significantly: |
:$$p_{\rm S} = {4}/{ 3}\cdot {\rm Q}(1)= {4}/{ 3}\cdot 0.1587 \hspace{0.15cm}\underline {\approx 21.2 \,\%} | :$$p_{\rm S} = {4}/{ 3}\cdot {\rm Q}(1)= {4}/{ 3}\cdot 0.1587 \hspace{0.15cm}\underline {\approx 21.2 \,\%} | ||
\hspace{0.05cm}.$$ | \hspace{0.05cm}.$$ | ||
| − | '''(3)''' The two outer symbols are each | + | '''(3)''' The two outer symbols are each falsified with probability $p = {\rm Q}(s_0/(2 \cdot \sigma_d)) = 0.1587$. |
| − | *The | + | *The falsification probability of the symbol $0$ is twice as large (it is limited by two thresholds). |
| − | * Considering the individual symbol probabilities, we obtain: | + | * Considering the individual symbol probabilities, we obtain: |
:$$p_{\rm S} = {1}/{ 4}\cdot p + {1}/{ 2}\cdot 2p +{1}/{ 4}\cdot p = 1.5 \cdot p = 1.5 \cdot 0.1587 | :$$p_{\rm S} = {1}/{ 4}\cdot p + {1}/{ 2}\cdot 2p +{1}/{ 4}\cdot p = 1.5 \cdot p = 1.5 \cdot 0.1587 | ||
\hspace{0.15cm}\underline {\approx | \hspace{0.15cm}\underline {\approx | ||
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| − | '''(4)''' Since the symbol $0$ occurs more frequently and can also be | + | '''(4)''' Since the symbol $0$ occurs more frequently and can also be falsified in both directions, the thresholds should be shifted outward. |
| − | *The optimal decision threshold $E_{\rm +, \ opt}$ is obtained from the intersection of the two Gaussian functions shown in the graph. It must hold: | + | *The optimal decision threshold $E_{\rm +, \ opt}$ is obtained from the intersection of the two Gaussian functions shown in the graph. It must hold: |
| − | [[File:P_ID1328__Dig_A_2_5e.png|right|frame|Optimal thresholds for '''(4)''']] | + | [[File:P_ID1328__Dig_A_2_5e.png|right|frame|Optimal thresholds for subtask '''(4)''']] |
:$$\frac{ 1/2}{ \sqrt{2\pi} \cdot \sigma_d} \cdot {\rm exp} \left[ - \frac{ E_{\rm +}^2}{2 \cdot \sigma_d^2}\right] | :$$\frac{ 1/2}{ \sqrt{2\pi} \cdot \sigma_d} \cdot {\rm exp} \left[ - \frac{ E_{\rm +}^2}{2 \cdot \sigma_d^2}\right] | ||
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| − | '''(5)''' Using the approximate result from '''(4)''', we obtain: | + | '''(5)''' Using the approximate result from subtask '''(4)''', we obtain: |
:$$p_{\rm S} \ = \ | :$$p_{\rm S} \ = \ | ||
{ 1}/{4} \cdot {\rm Q} \left( {\frac{s_0/3}{ | { 1}/{4} \cdot {\rm Q} \left( {\frac{s_0/3}{ | ||
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\sigma_d}}\right) +{ 1}/{4} \cdot {\rm Q} \left( {\frac{s_0/3}{ | \sigma_d}}\right) +{ 1}/{4} \cdot {\rm Q} \left( {\frac{s_0/3}{ | ||
\sigma_d}}\right)$$ | \sigma_d}}\right)$$ | ||
| + | [[File:P_ID1329__Dig_A_2_5g.png|right|frame|Optimal thresholds for subtask '''(6)''']] | ||
| + | |||
| + | |||
:$$\Rightarrow \hspace{0.3cm}p_{\rm S} \ = \ = { 1}/{2} \cdot {\rm Q} \left( 2/3 \right)+ {\rm Q} \left( 4/3 | :$$\Rightarrow \hspace{0.3cm}p_{\rm S} \ = \ = { 1}/{2} \cdot {\rm Q} \left( 2/3 \right)+ {\rm Q} \left( 4/3 | ||
\right)= | \right)= | ||
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| − | + | '''(6)''' After a similar calculation as in subtask '''(4)''' we get | |
| − | '''(6)''' After a similar calculation as in | ||
*$E_+ = 1 \, –0.0673 \ \underline{= 0.327} \approx 1/3$. | *$E_+ = 1 \, –0.0673 \ \underline{= 0.327} \approx 1/3$. | ||
*$E_{–} = \, –E_+$ is still valid. | *$E_{–} = \, –E_+$ is still valid. | ||
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| − | '''(7)''' Similar to the | + | '''(7)''' Similar to the solution for subtask '''(5)''', we now obtain: |
:$$p_{\rm S} \ = \ 0.4 \cdot {\rm Q} \left( 4/3 \right)+ 2 \cdot 0.2 \cdot{\rm Q} \left( 2/3 | :$$p_{\rm S} \ = \ 0.4 \cdot {\rm Q} \left( 4/3 \right)+ 2 \cdot 0.2 \cdot{\rm Q} \left( 2/3 | ||
\right)+0.4 \cdot {\rm Q} \left( 4/3 \right)$$ | \right)+0.4 \cdot {\rm Q} \left( 4/3 \right)$$ | ||
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\hspace{0.05cm}.$$ | \hspace{0.05cm}.$$ | ||
| − | Discussion of the result: | + | $\text{Discussion of the result:}$ |
| − | *Accordingly, there is a smaller symbol error probability ( | + | *Accordingly, there is a smaller symbol error probability $(17.4 \ \%$ versus $21.2 \ \%)$ than with equal probability amplitude coefficients. |
| − | *However, redundancy-free coding is no longer present, even if the amplitude coefficients are statistically independent of each other. | + | |
| − | *While for equally probable ternary symbols the entropy is $H = {\rm log}_2(3) = 1.585 \ {\rm bit/ternary \ symbol}$ | + | *However, redundancy-free coding is no longer present, even if the amplitude coefficients are statistically independent of each other. |
| − | :$$H \ = \ 0.2 \cdot {\rm log_2} (5) + 2 \cdot 0.4 \cdot {\rm log_2} (2.5)= 0.2 \cdot 2.322 + 0.8 \cdot 1.322 \hspace{0.15cm}\underline {\approx 1.522\,\, {\rm | + | |
| + | *While for equally probable ternary symbols | ||
| + | :*the entropy is $H = {\rm log}_2(3) = 1.585 \ {\rm bit/ternary \ symbol}$ | ||
| + | :*from which the equivalent bit rate can be calculated according to $R_{\rm B} = H/T$, | ||
| + | :*here applies with probabilities $p_0 = 0.2$ and $p_{–} = p_+ = 0.4$: | ||
| + | ::$$H \ = \ 0.2 \cdot {\rm log_2} (5) + 2 \cdot 0.4 \cdot {\rm log_2} (2.5)= 0.2 \cdot 2.322 + 0.8 \cdot 1.322 \hspace{0.15cm}\underline {\approx 1.522\,\, {\rm | ||
bit/ternary \ symbol}} | bit/ternary \ symbol}} | ||
\hspace{0.05cm}.$$ | \hspace{0.05cm}.$$ | ||
| − | *Thus, the equivalent bit rate is $4 \ \%$ smaller than the maximum possible for $M = 3$. | + | *Thus, the equivalent bit rate here is $\approx 4 \ \%$ smaller than the maximum possible equivalent bit rate for $M = 3$. |
{{ML-Fuß}} | {{ML-Fuß}} | ||
Latest revision as of 16:19, 3 June 2022
Probability density function $\rm (PDF)$ of a noisy ternary signal
A ternary transmission system $(M = 3)$ with the possible amplitude values $-s_0$, $0$ and $+s_0$ is considered.
- During transmission, additive Gaussian noise with rms value $\sigma_d$ is added to the signal.
- The recovery of the three-level digital signal at the receiver is done with the help of two decision thresholds at $E_{–}$ and $E_{+}$.
- First, the occurrence probabilities of the three input symbols are assumed to be equally probable:
- $$p_{\rm -} = {\rm Pr}(-s_0) = {1}/{ 3}, \hspace{0.15cm} p_{\rm 0} = {\rm Pr}(0) = {1}/{ 3}, \hspace{0.15cm} p_{\rm +} = {\rm Pr}(+s_0) ={1}/{ 3}\hspace{0.05cm}.$$
- For the time being, the decision thresholds are centered at $E_{–} = \, –s_0/2$ and $E_{+} = +s_0/2$.
- From subtask (3) on, the symbol probabilities are $p_{–} = p_+ = 1/4$ and $p_0 = 1/2$, as shown in the diagram.
- For this constellation, the symbol error probability $p_{\rm S}$ is to be minimized by varying the decision thresholds $E_{–}$ and $E_+$.
Notes:
- The exercise refers to the chapter "Redundancy-Free Coding".
- For the symbol error probability $p_{\rm S}$ of a $M$–level transmission system
- with equally probable input symbols
- and threshold values exactly in the middle between two adjacent amplitude levels holds:
- $$p_{\rm S} = \frac{ 2 \cdot (M-1)}{M} \cdot {\rm Q} \left( {\frac{s_0}{(M-1) \cdot \sigma_d}}\right) \hspace{0.05cm}.$$
- You can numerically determine the error probability values according to our applet "Complementary Gaussian Error Functions".
- To check your results, use our (German language) SWF applet "Symbol error probability of digital communications systems".
Questions
Solution
(1) According to the given equation, with $M = 3$ and $\sigma_d/s_0 = 0.25$:
- $$p_{\rm S} = \frac{ 2 \cdot (M-1)}{M} \cdot {\rm Q} \left( {\frac{s_0}{(M-1) \cdot \sigma_d}}\right)= {4}/{ 3}\cdot {\rm Q}(2) ={4}/{ 3}\cdot 0.0228\hspace{0.15cm}\underline {\approx 3 \,\%} \hspace{0.05cm}.$$
(2) When the noise rms value is doubled, the error probability increases significantly:
- $$p_{\rm S} = {4}/{ 3}\cdot {\rm Q}(1)= {4}/{ 3}\cdot 0.1587 \hspace{0.15cm}\underline {\approx 21.2 \,\%} \hspace{0.05cm}.$$
(3) The two outer symbols are each falsified with probability $p = {\rm Q}(s_0/(2 \cdot \sigma_d)) = 0.1587$.
- The falsification probability of the symbol $0$ is twice as large (it is limited by two thresholds).
- Considering the individual symbol probabilities, we obtain:
- $$p_{\rm S} = {1}/{ 4}\cdot p + {1}/{ 2}\cdot 2p +{1}/{ 4}\cdot p = 1.5 \cdot p = 1.5 \cdot 0.1587 \hspace{0.15cm}\underline {\approx 23.8 \,\%} \hspace{0.05cm}.$$
(4) Since the symbol $0$ occurs more frequently and can also be falsified in both directions, the thresholds should be shifted outward.
- The optimal decision threshold $E_{\rm +, \ opt}$ is obtained from the intersection of the two Gaussian functions shown in the graph. It must hold:
Optimal thresholds for subtask (4)
- $$\frac{ 1/2}{ \sqrt{2\pi} \cdot \sigma_d} \cdot {\rm exp} \left[ - \frac{ E_{\rm +}^2}{2 \cdot \sigma_d^2}\right] = \frac{ 1/4}{ \sqrt{2\pi} \cdot \sigma_d} \cdot {\rm exp} \left[ - \frac{ (s_0 -E_{\rm +})^2}{2 \cdot \sigma_d^2}\right]$$
- $$\Rightarrow \hspace{0.3cm} {\rm exp} \left[ \frac{ (s_0 -E_{\rm +})^2 - E_{\rm +}^2}{2 \cdot \sigma_d^2}\right]= {1}/{ 2} \Rightarrow \hspace{0.3cm} {\rm exp} \left[ \frac{ 1 -2 \cdot E_{\rm +}/s_0}{2 \cdot \sigma_d^2/s_0^2}\right]= {1}/{ 2}$$
- $$\Rightarrow \hspace{0.3cm}\frac{ E_{\rm +}}{s_0}= \frac{1} { 2}+ \frac{\sigma_d^2} {s_0^2} \cdot {\rm ln}(2)\hspace{0.15cm}\underline {=0.673}\hspace{0.15cm}\approx {2}/ {3} \hspace{0.05cm}.$$
(5) Using the approximate result from subtask (4), we obtain:
- $$p_{\rm S} \ = \ { 1}/{4} \cdot {\rm Q} \left( {\frac{s_0/3}{ \sigma_d}}\right)+ 2 \cdot { 1}/{2} \cdot {\rm Q} \left( {\frac{2s_0/3}{ \sigma_d}}\right) +{ 1}/{4} \cdot {\rm Q} \left( {\frac{s_0/3}{ \sigma_d}}\right)$$
Optimal thresholds for subtask (6)
- $$\Rightarrow \hspace{0.3cm}p_{\rm S} \ = \ = { 1}/{2} \cdot {\rm Q} \left( 2/3 \right)+ {\rm Q} \left( 4/3 \right)= { 1}/{2} \cdot 0.251 + 0.092 \hspace{0.15cm}\underline {\approx 21.7 \,\%} \hspace{0.05cm}.$$
(6) After a similar calculation as in subtask (4) we get
- $E_+ = 1 \, –0.0673 \ \underline{= 0.327} \approx 1/3$.
- $E_{–} = \, –E_+$ is still valid.
(7) Similar to the solution for subtask (5), we now obtain:
- $$p_{\rm S} \ = \ 0.4 \cdot {\rm Q} \left( 4/3 \right)+ 2 \cdot 0.2 \cdot{\rm Q} \left( 2/3 \right)+0.4 \cdot {\rm Q} \left( 4/3 \right)$$
- $$\Rightarrow \hspace{0.3cm}p_{\rm S} \ = \ 0.4 \cdot (0.092 + 0.251 + 0.092) \hspace{0.15cm}\underline {\approx 17.4 \,\%} \hspace{0.05cm}.$$
$\text{Discussion of the result:}$
- Accordingly, there is a smaller symbol error probability $(17.4 \ \%$ versus $21.2 \ \%)$ than with equal probability amplitude coefficients.
- However, redundancy-free coding is no longer present, even if the amplitude coefficients are statistically independent of each other.
- While for equally probable ternary symbols
- the entropy is $H = {\rm log}_2(3) = 1.585 \ {\rm bit/ternary \ symbol}$
- from which the equivalent bit rate can be calculated according to $R_{\rm B} = H/T$,
- here applies with probabilities $p_0 = 0.2$ and $p_{–} = p_+ = 0.4$:
- $$H \ = \ 0.2 \cdot {\rm log_2} (5) + 2 \cdot 0.4 \cdot {\rm log_2} (2.5)= 0.2 \cdot 2.322 + 0.8 \cdot 1.322 \hspace{0.15cm}\underline {\approx 1.522\,\, {\rm bit/ternary \ symbol}} \hspace{0.05cm}.$$
- Thus, the equivalent bit rate here is $\approx 4 \ \%$ smaller than the maximum possible equivalent bit rate for $M = 3$.
