Difference between revisions of "Aufgaben:Exercise 4.17: Non-Coherent On-Off Keying"

Latest revision as of 16:13, 29 August 2022

Rayleigh and Rice PDF

The figure shows the two density functions resulting from a non-coherent demodulation of "On–Off–Keying" $\rm (OOK)$. It is assumed that the two OOK signal space points are located

at $\boldsymbol{s}_0 = C$ $($message $m_0)$ and

at $\boldsymbol{s}_1 = 0$ $($message $m_1)$.

The symbol error probability of this system is described by the following equation:

$$p_{\rm S} \hspace{-0.1cm} \ = \ \hspace{-0.1cm} {\rm Pr}({\cal{E}}) = {1}/{ 2} \cdot \int_{0}^{G} p_{y\hspace{0.05cm}|\hspace{0.05cm}m} (\eta\hspace{0.05cm} | \hspace{0.05cm}m_0) \,{\rm d} \eta +{1}/{ 2} \cdot \int_{G}^{\infty} p_{y\hspace{0.05cm}|\hspace{0.05cm}m} (\eta\hspace{0.05cm} |\hspace{0.05cm} m_1) \,{\rm d} \eta \hspace{0.05cm}.$$

With the standard deviation $\sigma_n = 1$, which is assumed in the following,

the resulting Rayleigh distribution for $m = m_1$ (blue curve) is:

$$p_{y\hspace{0.05cm}|\hspace{0.05cm}m} (\eta\hspace{0.05cm} \hspace{0.05cm}| m_1) = \eta \cdot {\rm e }^{-\eta^2/2} \hspace{0.05cm}.$$

The (red) Rice distribution can be approximated in the present case $($because of $C\gg \sigma_n)$ by a Gaussian curve:

$$p_{y\hspace{0.05cm}|\hspace{0.05cm}m} (\eta\hspace{0.05cm} |\hspace{0.05cm} m_0) = \frac{1}{\sqrt{2\pi}} \cdot {\rm e }^{-(\eta-C)^2/2} \hspace{0.05cm}.$$

The optimal decision boundary $G_{\rm opt}$ is obtained from the intersection of the red and blue curves.

From the two sketches it can be seen that $G_{\rm opt}$ depends on $C$.

For the upper graph $C = 4$, for the lower graph $C = 6$.

All quantities are normalized and $\sigma_n = 1$ is always assumed.

Notes:

The exercise belongs to the topic of the chapter "Carrier Frequency Systems with Non-Coherent Demodulation".

For the complementary Gaussian error integral, you can use the following approximations:

$${\rm Q }(1.5) \approx 0.0668\hspace{0.05cm}, \hspace{0.5cm}{\rm Q }(2.5) \approx 0.0062\hspace{0.05cm}, \hspace{0.5cm} {\rm Q }(2.65) \approx 0.0040 \hspace{0.05cm}.$$

You can check your results with theHTML5/JavaScript applet "Coherent and Non-coherent On-Off Keying".

Questions

	$E_{\rm S} = C$,
	$E_{\rm S} = C^2$,
	$E_{\rm S} = C^2\hspace{-0.1cm}/2$.

	$G = C/2$,
	$G \, –1/C \cdot {\rm ln} \, (G) = C/2 + 1/(2C) \cdot {\rm ln} \, (2\pi)$,
	$G = 1/C \cdot {\rm ln} \, (G)$.

$G_{\rm opt} \ = \ $

$p_{\rm S} \ = \ $

$\ \% $

$G_{\rm opt} \ = \ $

$p_{\rm S} \ = \ $

$\ \% $

Solution

(1) Solution 3 is correct:

The energy is equal to the value $\boldsymbol{s}_0 = C$ in the signal space constellation squared, divided by $2$.

The factor $1/2$ takes into account that the message $m_1$ does not contribute any energy $(\boldsymbol{s}_1 = 0)$.

(2) Solution 2 is correct here:

The optimal decision boundary $G$ lies at the intersection of the two curves shown.

The factor $1/2$ considers the equally probable messages $m_0$ and $m_1$. Thus, the following determination equation is obtained:

$${G}/{2} \cdot {\rm exp } \left [ - {G^2 }/{2 }\right ] = \frac{1}{2 \cdot \sqrt{2\pi}} \cdot {\rm exp } \left [ - \frac{G^2 - 2 C \cdot G + C^2}{2 }\right ]$$

$$\Rightarrow \hspace{0.3cm} \sqrt{2\pi} \cdot G = {\rm exp } \left [ C \cdot G - C^2/2 \right ] \hspace{0.3cm}\Rightarrow \hspace{0.3cm} C \cdot G - {\rm ln }\hspace{0.15cm} (\sqrt{2\pi} \cdot G) - C^2/2 = 0$$

$$\Rightarrow \hspace{0.3cm} G - {1}/{C} \cdot {\rm ln }\hspace{0.15cm} ( G) = C/2 + {1}/({2C}) \cdot {\rm ln }\hspace{0.15cm} (\sqrt{2\pi}) = C/2 + {1}/({2C}) \cdot {\rm ln }\hspace{0.15cm} ({2\pi})\hspace{0.05cm}.$$

(3) With $C = 4$, the governing equation given in subtask (2) is

$$f(G) \hspace{-0.1cm} \ = \ \hspace{-0.1cm} G - {1}/{C} \cdot {\rm ln }\hspace{0.15cm} ( G) - C/2 - {1}/({2C}) \cdot {\rm ln }\hspace{0.15cm} ({2\pi})= G - 0.25 \cdot {\rm ln }\hspace{0.15cm} ( G) - 2 - {\rm ln }\hspace{0.15cm} ({2\pi})/8 \approx G - 0.25 \cdot {\rm ln }\hspace{0.15cm} ( G) - 2.23 = 0 \hspace{0.05cm}.$$

This equation can only be solved numerically:

$$G = 2.0\text{:}\hspace{0.15cm}f(G) \hspace{-0.1cm} \ = \ \hspace{-0.1cm} -0.403 \hspace{0.05cm}, \hspace{0.2cm}G = 3.0\text{:}\hspace{0.15cm}f(G) = 0.495 \hspace{0.05cm}, \hspace{0.2cm}G = 2.5\text{:}\hspace{0.15cm}f(G) = 0.041\hspace{0.05cm},$$

$$ G = 2.4\text{:}\hspace{0.15cm}f(G) \hspace{-0.1cm} \ = \ \hspace{-0.1cm} -0.049 \hspace{0.05cm}, \hspace{0.2cm}G = 2.46\text{:}\hspace{0.15cm}f(G) \approx 0 \hspace{0.05cm}.$$

Thus, the optimal decision threshold is $G_{\rm opt} \underline {= 2.46 \approx 2.5}$.

(4) The error probability is composed of two parts:

$$p_{\rm S} = {\rm Pr}({\cal{E}}) = {1}/{ 2} \cdot {\rm Pr}({\cal{E}}\hspace{0.05cm}| \hspace{0.05cm} m = m_1)+{1}/{ 2}\cdot {\rm Pr}({\cal{E}}\hspace{0.05cm}| \hspace{0.05cm} m = m_0)\hspace{0.05cm}.$$

The first part $($falsification from $m_1$ to $m_0)$ results from the crossing of the limit $G$ by the Rayleigh distribution:

$${\rm Pr}({\cal{E}} \hspace{0.05cm}| \hspace{0.05cm} m = m_1) = \int_{G}^{\infty} p_{y\hspace{0.05cm}| \hspace{0.05cm}m} (\eta \hspace{0.05cm}| \hspace{0.05cm} m_1) \,{\rm d} \eta = {\rm e }^{-G^2/2}= {\rm e }^{-3.125}\approx 0.044 \hspace{0.05cm}.$$

The second part $($falsification from $m_0$ to $m_1)$ results from the Rice distribution, which is approximated here by the Gaussian distribution:

$${\rm Pr}({\cal{E}}| m = m_0) = \int_{0}^{G} p_{y\hspace{0.05cm}| \hspace{0.05cm}m} (\eta \hspace{0.05cm}| \hspace{0.05cm} m_0) \,{\rm d} \eta = \frac{1}{\sqrt{2\pi}} \cdot \int_{0}^{G} {\rm e }^{-(\eta-C)^2/2} \,{\rm d} \eta \hspace{0.05cm}.$$

This part can be given by the complementary Gaussian error integral ${\rm Q}(x)$:

$${\rm Pr}({\cal{E}}\hspace{0.05cm}| \hspace{0.05cm} m = m_0) = {\rm Pr}(y < G-C) = {\rm Pr}(y > C-G) = {\rm Q }(\frac{C-G}{\sigma_n})= {\rm Q }(\frac{4-2.5}{1})= {\rm Q }(1.5) \approx 0.0688 \hspace{0.05cm}. $$

This gives a total of:

$$p_{\rm S} = {\rm Pr}({\cal{E}}) = {1}/{ 2} \cdot 0.0440 +{1}/{ 2} \cdot 0.0668 \approx \underline{5.54\, \%}\hspace{0.05cm}.$$

Note:

A simulation has shown that a slightly smaller error probability results if the actual Rice distribution is used instead of the Gaussian approximation. Then with $G = 2.5$:

$$p_{\rm S} = {\rm Pr}({\cal{E}}) = {1}/{ 2} \cdot 0.0440 + {1}/{ 2} \cdot 0.0484 \approx \underline{4.62\, \%}\hspace{0.05cm}.$$

Thus, the Gaussian approximation provides an upper bound on the true error probability.

(5) With $C = 6$, the governing equation given in subtask (3) is

$$f(G)= G - {1}/{C} \cdot {\rm ln }\hspace{0.15cm} ( G) - C/2 - \frac{1}{2C} \cdot {\rm ln }\hspace{0.15cm} ({2\pi}) \approx G - {\rm ln }\hspace{0.15cm} ( G)/6 - 3.153 = 0 \hspace{0.05cm},$$

$$G = 3.0\hspace{-0.1cm}:\hspace{0.15cm}f(G) \hspace{-0.1cm} \ = \ \hspace{-0.1cm} -0.336 \hspace{0.05cm}, \hspace{0.2cm}G = 3.50\hspace{-0.1cm}:\hspace{0.15cm}f(G) = 0.138 \hspace{0.05cm},$$

$$ G = 3.3\hspace{-0.1cm}:\hspace{0.15cm}f(G) \hspace{-0.1cm} \ = \ \hspace{-0.1cm} -0.052 \hspace{0.05cm}, \hspace{0.2cm}G = 3.35\hspace{-0.1cm}:\hspace{0.15cm}f(G) \approx 0 \hspace{0.3cm} \Rightarrow \hspace{0.3cm} \underline{G_{\rm opt} \approx 3.35}\hspace{0.05cm}.$$

(6) Analogous to subtask (4), we obtain with $G = 3.5$:

$$p_{\rm S} \hspace{-0.1cm} \ = \ \hspace{-0.1cm} {\rm Pr}({\cal{E}}) = {1}/{ 2} \cdot {\rm e }^{-G^2/2} +{1}/{ 2} \cdot {\rm Q }(C-G)= {1}/{ 2} \cdot {\rm e }^{-6.125} + {1}/{ 2} \cdot {\rm Q }(2.5)= {1}/{ 2} \cdot 2.2 \cdot 10^{-3} + {1}/{ 2} \cdot 6.2 \cdot 10^{-3} \underline{= 0.42 \,\%} \hspace{0.05cm}.$$

For $C = 6$, the optimal decision boundary $(G_{\rm opt} = 3.35)$ results in an error probability that is about a factor of $10$ smaller than with $C = 4$:

$$p_{\rm S} = {1}/{ 2} \cdot {\rm e }^{-5.61} + {1}/{ 2} \cdot {\rm Q }(2.65)= {1}/{ 2} \cdot 3.6 \cdot 10^{-3} +{1}/{ 2} \cdot 4 \cdot 10^{-3}= {0.38 \,\%} \hspace{0.05cm}.$$

The actual error probability using the Rice distribution (no Gaussian approximation) gives a slightly smaller value: $0.33\%$.

@@ Line 77: / Line 77: @@
 ===Solution===
 {{ML-Kopf}}
-'''(1)'''&nbsp; <u>Solution 3</u> is correct:
+'''(1)'''&nbsp; <u>Solution 3</u>&nbsp; is correct:
-*The energy is equal to the value $\boldsymbol{s}_0 = C$ in the signal space constellation squared, divided by $2$.
+*The energy is equal to the value&nbsp; $\boldsymbol{s}_0 = C$&nbsp; in the signal space constellation squared,&nbsp; divided by&nbsp; $2$.
-*The factor $1/2$ takes into account that the message $m_1$ does not contribute any energy ($\boldsymbol{s}_1 = 0$).
+*The factor $1/2$ takes into account that the message&nbsp; $m_1$&nbsp; does not contribute any energy&nbsp; $(\boldsymbol{s}_1 = 0)$.
-'''(2)'''&nbsp;  <u>Solution 2</u> is correct here:
+'''(2)'''&nbsp;  <u>Solution 2</u>&nbsp; is correct here:
-*The optimal decision boundary $G$ lies at the intersection of the two curves shown.
+*The optimal decision boundary&nbsp; $G$&nbsp; lies at the intersection of the two curves shown.
-*The factor $1/2$ considers the equally probable messages $m_0$ and $m_1$. Thus, the following determination equation is obtained:
+*The factor&nbsp; $1/2$&nbsp; considers the equally probable messages&nbsp; $m_0$&nbsp; and&nbsp; $m_1$.&nbsp; Thus,&nbsp; the following determination equation is obtained:
 :$${G}/{2} \cdot {\rm exp } \left [ - {G^2 }/{2 }\right ] = \frac{1}{2 \cdot \sqrt{2\pi}} \cdot
   {\rm exp } \left [ - \frac{G^2 - 2 C \cdot G + C^2}{2 }\right ]$$
@@ Line 94: / Line 96: @@
-'''(3)'''&nbsp; With $C = 4$, the governing equation given in (2) is
+'''(3)'''&nbsp; With&nbsp; $C = 4$,&nbsp; the governing equation given in subtask&nbsp; '''(2)'''&nbsp; is
 :$$f(G) \hspace{-0.1cm} \ = \ \hspace{-0.1cm}  G - {1}/{C} \cdot {\rm ln }\hspace{0.15cm} ( G) - C/2 - {1}/({2C}) \cdot {\rm ln }\hspace{0.15cm} ({2\pi})=  G - 0.25 \cdot {\rm ln }\hspace{0.15cm} ( G) - 2 -  {\rm ln }\hspace{0.15cm} ({2\pi})/8
   \approx G - 0.25 \cdot {\rm ln }\hspace{0.15cm} ( G) - 2.23 = 0
@@ Line 105: / Line 107: @@
    \hspace{0.05cm}.$$
-*Thus, the optimal decider boundary is $G_{\rm opt} \underline {= 2.46 \approx 2.5}$.
+*Thus,&nbsp; the optimal decision threshold is&nbsp; $G_{\rm opt} \underline {= 2.46 \approx 2.5}$.
@@ Line 112: / Line 114: @@
 :$$p_{\rm S} = {\rm Pr}({\cal{E}}) =  {1}/{ 2} \cdot {\rm Pr}({\cal{E}}\hspace{0.05cm}| \hspace{0.05cm} m = m_1)+{1}/{ 2}\cdot {\rm Pr}({\cal{E}}\hspace{0.05cm}| \hspace{0.05cm} m = m_0)\hspace{0.05cm}.$$
-*The first part (falsification from $m_1$ nach $m_0$) results from the crossing of the limit $G$ by the Rayleigh distribution
+*The first part&nbsp; $($falsification from&nbsp; $m_1$&nbsp; to&nbsp; $m_0)$&nbsp; results from the crossing of the limit&nbsp; $G$&nbsp; by the Rayleigh distribution:
 :$${\rm Pr}({\cal{E}} \hspace{0.05cm}| \hspace{0.05cm} m = m_1) =   \int_{G}^{\infty} p_{y\hspace{0.05cm}| \hspace{0.05cm}m} (\eta \hspace{0.05cm}| \hspace{0.05cm} m_1) \,{\rm d} \eta = {\rm e }^{-G^2/2}= {\rm e }^{-3.125}\approx 0.044
   \hspace{0.05cm}.$$
-*The second part (falsification from $m_0$ to $m_1$) results from the Rice distribution, which is approximated here by the Gaussian distribution:
+*The second part&nbsp; $($falsification from&nbsp; $m_0$&nbsp; to&nbsp; $m_1)$&nbsp; results from the Rice distribution,&nbsp; which is approximated here by the Gaussian distribution:
 :$${\rm Pr}({\cal{E}}| m = m_0) =   \int_{0}^{G} p_{y\hspace{0.05cm}| \hspace{0.05cm}m} (\eta \hspace{0.05cm}| \hspace{0.05cm} m_0) \,{\rm d} \eta =
     \frac{1}{\sqrt{2\pi}} \cdot \int_{0}^{G} {\rm e }^{-(\eta-C)^2/2} \,{\rm d} \eta
   \hspace{0.05cm}.$$
-*This part can be given by the complementary Gaussian error integral ${\rm Q}(x)$:
+*This part can be given by the complementary Gaussian error integral&nbsp; ${\rm Q}(x)$:
 :$${\rm Pr}({\cal{E}}\hspace{0.05cm}| \hspace{0.05cm} m = m_0) =  {\rm Pr}(y < G-C) = {\rm Pr}(y > C-G) = {\rm Q }(\frac{C-G}{\sigma_n})= {\rm Q }(\frac{4-2.5}{1})= {\rm Q }(1.5) \approx 0.0688
   \hspace{0.05cm}.  $$
@@ Line 128: / Line 130: @@
 :$$p_{\rm S} = {\rm Pr}({\cal{E}}) =  {1}/{ 2} \cdot 0.0440 +{1}/{ 2} \cdot 0.0668 \approx \underline{5.54\, \%}\hspace{0.05cm}.$$
-''Note'': &nbsp; A system simulation has shown that a slightly smaller error probability results if the actual Rice distribution is used instead of the Gaussian approximation. Then with $G = 2.5$:
+<u>Note:</u> &nbsp;
+A simulation has shown that a slightly smaller error probability results if the actual Rice distribution is used instead of the Gaussian approximation.&nbsp; Then with&nbsp; $G = 2.5$:
 :$$p_{\rm S} = {\rm Pr}({\cal{E}}) =  {1}/{ 2} \cdot 0.0440 + {1}/{ 2} \cdot 0.0484 \approx \underline{4.62\, \%}\hspace{0.05cm}.$$
-Thus, the Gaussian approximation provides an upper bound on the true error probability.
+Thus,&nbsp; the Gaussian approximation provides an upper bound on the true error probability.
-'''(5)'''&nbsp; With&nbsp; $C = 6$,&nbsp; the governing equation given in '''(3)''' is
+'''(5)'''&nbsp; With&nbsp; $C = 6$,&nbsp; the governing equation given in subtask&nbsp; '''(3)'''&nbsp; is
 :$$f(G)=  G - {1}/{C} \cdot {\rm ln }\hspace{0.15cm} ( G) - C/2 - \frac{1}{2C} \cdot {\rm ln }\hspace{0.15cm} ({2\pi}) \approx G -  {\rm ln }\hspace{0.15cm} ( G)/6 - 3.153 = 0
    \hspace{0.05cm},$$
@@ Line 145: / Line 149: @@
-'''(6)'''&nbsp; Analogous to subtask '''(4)''', we obtain with $G = 3.5$:
+'''(6)'''&nbsp; Analogous to subtask&nbsp; '''(4)''',&nbsp; we obtain with&nbsp; $G = 3.5$:
 :$$p_{\rm S} \hspace{-0.1cm} \ = \ \hspace{-0.1cm} {\rm Pr}({\cal{E}}) =  {1}/{ 2} \cdot {\rm e }^{-G^2/2} +{1}/{ 2} \cdot {\rm Q }(C-G)=  {1}/{ 2} \cdot {\rm e }^{-6.125} + {1}/{ 2} \cdot {\rm Q }(2.5)=
   {1}/{ 2} \cdot 2.2 \cdot 10^{-3} + {1}/{ 2} \cdot 6.2 \cdot 10^{-3} \underline{= 0.42 \,\%}
   \hspace{0.05cm}.$$
-*For&nbsp; $C = 6$,&nbsp; the optimal decision boundary ($G_{\rm opt} = 3.35$) results in an error probability that is about a factor of $10$ smaller than with $C = 4$:
+*For&nbsp; $C = 6$,&nbsp; the optimal decision boundary&nbsp; $(G_{\rm opt} = 3.35)$&nbsp; results in an error probability that is about a factor of&nbsp; $10$&nbsp; smaller than with&nbsp; $C = 4$:
 :$$p_{\rm S} = {1}/{ 2} \cdot {\rm e }^{-5.61} + {1}/{ 2} \cdot {\rm Q }(2.65)=
 {1}/{ 2} \cdot 3.6 \cdot 10^{-3} +{1}/{ 2} \cdot 4 \cdot 10^{-3}= {0.38 \,\%}